JP5565802B2 - Light transmissive solar cell module - Google Patents

Description

  The present invention relates to a light transmissive solar cell module including a see-through line that is a light transmissive portion that transmits light from the front surface to the back surface of a power generation unit.

  Conventionally, a light transmissive solar cell module having a daylighting function that transmits part of incident light from the front surface side to the back surface side in addition to the power generation function has been proposed (see, for example, Patent Documents 1 and 2).

  14 is a plan view seen from the back side showing an example of the external configuration of a conventional light-transmissive solar cell module 100, and FIG. 15 is an enlarged view of a portion E shown in FIG.

  For example, the light transmission type solar cell module 100 is formed in a vertically long shape having a width of about 600 mm and a length of about 1000 mm. Although not shown, the light transmission type solar cell module 100 is formed on a light-transmitting insulating substrate formed in a vertically long rectangular shape. In addition, a transparent front electrode layer, a photoelectric conversion layer, and a back electrode layer are sequentially laminated to form a power generation unit 100A including a plurality of solar cells 102, 102,. In this example, the power generation unit 100A is separated into a plurality of power generation regions 100A1 to 100A9 in the vertical direction by a separation line (separation groove) 110 (in this example, separated into nine power generation regions). That is, the separation line 110 is formed so as to penetrate from the back electrode layer to the translucent insulating substrate, and in order to prevent a discharge risk between adjacent power generation regions, it is necessary to ensure a creepage distance. It is formed sufficiently wide.

  Further, each of the power generation regions 100A1 to 100A9 has a configuration in which, for example, seven solar cells 102, 102,... Formed in the lateral direction are connected in series. Therefore, in each power generation region 100A1 to 100A9, in order to connect seven solar cells 102 in series, six scribe lines (hereinafter also referred to as third scribe lines in this specification) for separating the back electrode layer. .) 105 is formed at predetermined intervals in the horizontal direction. The third scribe line 105 is formed so that the back electrode layer and the photoelectric conversion layer are removed to reach the front electrode layer.

  Further, in each of the power generation regions 100A1 to 100A9, as shown in an enlarged view in FIG. 15, a see-through line 108 for daylight reaching the front electrode layer by removing the back electrode layer and the photoelectric conversion layer is predetermined in the vertical direction. A predetermined number of lines are formed in the lateral direction perpendicular to the third scribe line 105 with the interval of. The formation interval and the number of the see-through lines 108 are determined by what percentage the transmittance of the light transmission type solar cell module 100 is set.

  Here, the separation line 110 is formed to have a line width of, for example, 0.38 mm, and the see-through line 108 is formed to, for example, 0.1 mm because the creepage distance needs to be secured as described above. The line 105 is formed to 0.08 mm, for example.

  The conventional light transmissive solar cell module 100 configured in this manner is configured to connect the power generation regions 100A1 to 100A9 in series, in parallel, or in series-parallel to extract output.

  As described above, the conventional light transmission type solar cell module 100 removes the back electrode layer and the photoelectric conversion layer in the same manner as the see-through line 108 as well as the see-through line 108 as a light transmitting line. In addition, there are three types of lines, the third scribe line 105 reaching the front electrode layer, and the separation line 110 reaching the translucent insulating substrate by removing the back electrode layer, the photoelectric conversion layer, and the front electrode layer. become.

JP 2002-43594 A JP 2002-299666 A

  By the way, the conventional light transmission type solar cell module having a structure in which the see-through line 108, the third scribe line 105, and the separation line 110 are arranged in parallel and regularly with respect to each side of the solar cell module 100 in this manner. When 100 is arranged on a window glass, a roof, a show window, etc., interference fringes may occur due to interference with screen doors, blinds, lace curtains, display monitors, design drawings, and other structures. That is, interference fringes may occur due to interference between the light transmission pattern of the light transmission type solar cell module and the pattern or pattern of the structure itself arranged before and after the light transmission type solar cell module. And when an interference fringe generate | occur | produced, the design value of the thing arrange | positioned before and behind a light transmissive solar cell module may fall significantly. Further, in daily life, there are problems that the interference fringes are always visible, which may cause a great stress and may cause an optical illusion.

  In order to solve such a problem, it is conceivable to make the light transmission pattern of the light transmission type solar cell module a pattern that does not generate interference fringes as much as possible with the structures arranged before and after the light transmission pattern.

  By the way, devising so as to suppress the occurrence of such interference fringes has been conventionally performed in the field of liquid crystal display devices. For example, the liquid crystal display device disclosed in Japanese Patent Application Laid-Open No. 58-2821 has a configuration in which a large number of holes or protrusions are arranged on the surface of a liquid crystal driving electrode of a liquid crystal display cell. Specifically, a concavo-convex pattern is formed on the surface of the liquid crystal drive electrode so as to prevent interference fringes. It has also been proposed that when the uneven pattern is a circular hole, the size and interval of the circles are formed randomly. Such a concavo-convex pattern is formed by a method in which a number of arbitrary concavo-convex patterns are formed by a photolithography technique in a process of forming a switching element or the like on a silicon substrate.

  As described above, in the field of liquid crystal display devices, there are contrivances to eliminate interference fringes, but in the field of light transmissive solar cell modules, there are no contrivances to eliminate interference fringes with structures to be arranged. It was. This is because the liquid crystal display device is originally intended to display an image, that is, to show to a person, whereas the light transmission type solar cell module is used for power generation, and originally used as an object to be viewed. This is due to not being done.

  Further, in order to eliminate the interference fringes of the light transmission type solar cell module, even if the configuration of the liquid crystal display device disclosed in Japanese Patent Application Laid-Open No. 58-2821 is applied, the liquid crystal display device having a completely different structure is originally provided. Is not applicable to a light transmissive solar cell module, and at present, no light transmissive solar cell module devised to eliminate interference fringes with structures arranged in the front and rear is proposed. .

  The present invention was devised in view of such circumstances, and its purpose is to provide a light transmissive solar cell module having a light transmissive portion that transmits light from the front surface to the back surface of the power generation portion. An object of the present invention is to provide a light transmissive solar cell module devised so as not to interfere as much as possible with patterns and designs of structures arranged before and after that.

  In order to solve the above problems, the light transmissive solar cell module of the present invention is a light transmissive solar cell module having a light transmissive portion that transmits light from the front surface to the back surface of the power generation portion, and the light transmissive portion includes: It is characterized by being formed in a pattern that is not parallel to each side of the module body. More specifically, the light transmission part is formed in an irregular pattern.

  According to the present invention, when the light transmissive solar cell module is arranged on a window glass or the like by forming the light transmissive portion in an irregular pattern, for example, a regular fine mesh is formed in a lattice shape. Even when arranged before and after a screen door, the mesh pattern and the light transmission pattern of the light transmission part partially intersect but do not completely overlap, so the occurrence of interference fringes is greatly reduced or disappeared It can be suppressed to the extent. In daily life, the occurrence of interference fringes is greatly reduced or disappeared, so that daily stress due to the appearance of interference fringes can be reduced. Furthermore, it is possible to avoid the occurrence of danger due to the optical illusion.

  In the light transmissive solar cell module of the present invention, the power generation unit is formed by a plurality of solar cells in which a front electrode layer, a photoelectric conversion layer, and a back electrode layer are sequentially stacked on a translucent insulating substrate. The light transmission portion is configured by removing the back electrode layer and the photoelectric conversion layer.

  Specifically, the portion from which the back electrode layer and the photoelectric conversion layer are removed is a scribe line for connecting a plurality of solar cells in series or a see-through line that transmits light. That is, since these scribe lines and see-through lines are formed so that the back electrode layer and the photoelectric conversion layer are removed and reach the front electrode layer, incident light from the surface side of the translucent insulating substrate is transmitted through It passes through the conductive insulating substrate and the surface electrode layer, and passes through the scribe line and the see-through line to be transmitted to the back electrode layer side. That is, when viewed from the back electrode layer side, the scribe lines and see-through lines appear as straight lines. Therefore, in the present invention, by forming the scribe line and the see-through line in an irregular pattern that is not a straight line, for example, a light transmissive solar cell before and after a screen door or the like in which a fine mesh is regularly formed in a lattice shape. Even when the module is arranged, the mesh pattern and the light transmission pattern of the light transmission part partially intersect but do not completely overlap, so the generation of interference fringes is greatly reduced or suppressed to an invisible level. be able to.

  Specifically, in the present invention, the light transmission part includes a see-through part for transmitting light, the see-through part is formed by a plurality of holes, and the sizes of the holes are the same. The arrangement pattern is irregularly formed.

  In the present invention, the light transmission portion includes a see-through portion for transmitting light, the see-through portion is formed by a plurality of holes, and the size of the holes is irregularly formed. It is said.

  In the present invention, the light transmission part includes a see-through part for transmitting light, the see-through part is formed by a plurality of holes, and the sizes of the holes are irregularly formed, and The arrangement pattern is also irregularly formed.

  Here, the shape of the hole may be various shapes such as a circle, an ellipse, a square, a rectangle, a triangle, and a pentagon or more polygon.

  When the light-transmissive solar cell module configured in this way is placed on a window glass, roof, show window, etc., interference fringes with screen doors, blinds, lace curtains, display monitors, design images, and other structures Although it may occur, the light transmission pattern of the light transmission type solar cell module is irregularly formed, thereby reducing or obscuring the interference with the pattern or design of the structure arranged before and after the light transmission pattern. It can be suppressed to the extent. Thereby, the design value of the thing arrange | positioned before and behind a light transmissive solar cell module is not reduced significantly.

  In the present invention, the light transmission part includes a see-through line for transmitting light, and the see-through line is formed in a non-linear irregular curve pattern.

  According to the present invention, for example, even when this light transmission type solar cell module is arranged before and after a screen door in which a fine mesh is regularly formed in a lattice shape, a mesh pattern and a non-linear irregular curve The see-through line of a pattern (for example, a gently curved pattern with a continuous irregular waveform) does not overlap completely even though it partially intersects, so that the occurrence of interference fringes is greatly reduced, or It can be suppressed to such an extent that it cannot be seen.

  In the present invention, the light transmission part includes a see-through line for transmitting light, and the see-through line is formed to be inclined with respect to each side of the module body.

  According to the present invention, the see-through line is linear. However, since this see-through line is formed to be inclined with respect to each side of the module main body (specifically, the translucent insulating substrate), for example, a regular fine mesh is formed in a lattice shape. Even when this light transmissive solar cell module is placed before and after a screen door, the mesh pattern and the light transmissive pattern of the light transmissive part intersect at a slight angle, but do not overlap completely. Occurrence can be greatly reduced or suppressed to the extent that it can no longer be seen. In the case where there is a linear pattern in the structure arranged in front and back, not limited to the above screen door, the pattern is often provided vertically or horizontally with respect to each side of the structure. This is because it can provide a sense of security and stability by providing it vertically or horizontally. Therefore, the generation of interference fringes can be greatly reduced or suppressed to an invisible level only by forming the see-through line so as to be inclined with respect to each side of the module body as in the present invention.

  In the present invention, the light transmission part includes a scribe line that separates the back electrode layer in order to connect the plurality of solar cells in series, and the scribe line has a non-linear irregular curve pattern. It has a formed configuration.

  According to the present invention, for example, even when this light transmission type solar cell module is arranged before and after a screen door in which a fine mesh is regularly formed in a lattice shape, a mesh pattern and a non-linear irregular curve A scribe line of a pattern (for example, a gently curved pattern in which irregular waveforms continue) does not completely overlap although it partially intersects, or greatly reduces the occurrence of interference fringes, or It can be suppressed to such an extent that it cannot be seen.

  In the present invention, the light transmission part includes a separation line for separating the power generation region of the power generation part, and the separation line is formed in a non-linear irregular curve pattern.

  Since the separation line is formed so that the back electrode layer, the photoelectric conversion layer, and the surface electrode layer are removed to reach the translucent insulating substrate, the incident light from the front surface side of the translucent insulating substrate is translucent. It passes through the conductive insulating substrate and passes through the separation line to the back electrode layer side. That is, when viewed from the back electrode layer side, this separation line appears as a straight line. Therefore, in the present invention, the separation lines are formed in an irregular curve pattern that is not a straight line (for example, a gentle curve pattern in which irregular waveforms are continuous), for example, in a regular grid pattern. Even when a light-transmissive solar cell module is placed before and after a screen door or the like with a fine mesh, the mesh pattern and the light-transmitting pattern of the light-transmitting portion do not overlap completely although they partially intersect Therefore, the generation of interference fringes can be greatly reduced or suppressed to the point where it cannot be seen.

  In the present invention, the light transmission pattern of the light transmission part is an irregular shape such as a hole shape or an irregular arrangement pattern, but even in this case, each cell has the same power generation area except for the light transmission part. It is necessary to form so that it becomes. That is, it is necessary to make the amount of current flowing through each cell the same by making the power generation region of each cell the same area. This is because if the area of the power generation region of each cell is different, the current is limited by the cell with the smallest amount of flowing current, resulting in a total power generation loss.

  When a light-transmissive solar cell module is placed on a window glass, roof, show window, etc., there may be interference fringes with screen doors, blinds, lace curtains, display monitors, design drawings, and other structures. In the light transmission type solar cell module of the present invention, since the light transmission part is formed in an irregular pattern, the interference with the pattern or pattern of the structure arranged before and after the light transmission part is reduced or suppressed to an invisible level. be able to. Thereby, the design value of the thing arrange | positioned before and behind a light transmissive solar cell module is not reduced significantly. In daily life, the occurrence of interference fringes can be greatly reduced or disappeared, reducing the daily stress caused by the appearance of interference fringes and avoiding the danger of optical illusions. It becomes possible to do.

It is the top view seen from the back side (opposite side to a light-receiving surface) which shows the basic composition of a light transmission type solar cell module. It is an enlarged view of A part of the light transmission type solar cell module shown in FIG. It is the elements on larger scale which looked at the A section of the light transmission type solar cell module shown in Drawing 1 from the X direction. It is the elements on larger scale which looked at the A section of the light transmission type solar cell module shown in Drawing 1 from the Y direction. It is the top view which looked at the external appearance structure of the light transmission type solar cell module of the specific example 1 from the back surface side (opposite side to a light-receiving surface). It is an enlarged view of B part of the light transmission type solar cell module shown in FIG. It is a perspective view which shows typically the state which has arrange | positioned the light transmission type solar cell module of the specific example 1 behind the screen door. It is a perspective view which shows typically the state which has arrange | positioned the light transmission type solar cell module of the specific example 1 in front of the screen door. It is the top view which looked at the external appearance structure of the light transmission type solar cell module of the specific example 2 from the back surface side (opposite side to a light-receiving surface). It is an enlarged view of C part of the light transmission type solar cell module shown in FIG. It is the top view which looked at the external appearance structure of the light transmission type solar cell module of the specific example 3 from the back surface side (opposite side to a light-receiving surface). It is an enlarged view of D part of the light transmission type solar cell module shown in FIG. It is the top view which looked at the external appearance structure of the light transmission type solar cell module of the example 4 from the back surface side (opposite side to a light-receiving surface). It is the top view which looked at the external appearance structure of the light transmission type solar cell module of the example 5 from the back surface side (opposite side to a light-receiving surface). It is the top view seen from the back side which shows an example of the external appearance structure of the conventional light transmission type solar cell module. It is an enlarged view of E part shown in FIG.

  Embodiments of the present invention will be described below with reference to the drawings. In addition, the following embodiment is an example which actualized this invention, Comprising: The thing of the character which limits the technical scope of this invention is not.

<Description of basic configuration of light transmissive solar cell module>
FIG. 1 is a plan view seen from the back side (opposite to the light receiving surface) showing the basic configuration of the light transmissive solar cell module, and FIG. 2 is an enlarged view of portion A of the light transmissive solar cell module shown in FIG. FIG. 3 is a partially enlarged cross-sectional view of the A portion of the light transmissive solar cell module shown in FIG. 1 as viewed from the X direction. FIG. 4 shows the A portion of the light transmissive solar cell module shown in FIG. It is the partial expanded sectional view seen from.

  With reference to FIG. 1 thru | or FIG. 4, the basic composition of a light transmission type solar cell module is demonstrated first. However, the light transmissive solar cell module according to the present invention is characterized by a light transmissive portion that transmits light from the front surface to the back surface of the power generation portion, specifically, a see-through portion that is formed only to transmit light (see-through line). ), A scribe line (a third scribe line, which will be described later) for separating the back electrode layer to connect a plurality of solar cells in series, and a separation line for separating the power generation region of the power generation unit in an irregular pattern However, in this description of the basic configuration, in order to facilitate understanding of the configuration of the see-through line, the scribe line, and the separation line, the case where the see-through line, the scribe line, and the separation line are formed in a straight line will be described. . After that, a specific example of the irregular pattern of the light transmission part, which is a feature of the present invention, will be described.

  The light transmissive solar cell module 1 of the present invention is formed, for example, in a vertically long shape having a width of about 600 mm and a length of about 1000 mm. A transparent surface is formed on the light transmissive insulating substrate 11 formed in a vertically long rectangular shape. The electrode layer 12, the photoelectric conversion layer 13, and the back electrode layer 14 are sequentially stacked to form a power generation unit 11 </ b> A including a plurality of solar cells 21, 21,. In the embodiment, the power generation unit 11A is separated into a plurality of power generation regions 11A1 to 11A9 in the vertical direction (separated into nine power generation regions in this example) by a separation line (separation groove) 19 described later. That is, the separation line 19 is formed so as to reach the translucent insulating substrate 11 by removing the back electrode layer 14, the photoelectric conversion layer 13, and the front electrode layer 12, and it is necessary to ensure a creepage distance. It is formed sufficiently wide.

  Further, each of the power generation regions 11A1 to 11A9 has a configuration in which, for example, seven solar cells 21, 21,... Formed in the horizontal direction in FIG. Therefore, in each of the power generation regions 11A1 to 11A9, six third scribe lines 17 that separate the back electrode layer 14 have a predetermined interval in the vertical direction in order to connect the seven solar cells 21 in series. Is formed. That is, the third scribe line 17 is formed so as to reach the surface electrode layer 12 by removing the back electrode layer 14 and the photoelectric conversion layer 13.

  Further, in each of the power generation regions 11A1 to 11A9, as shown in a partially enlarged view in FIG. 2, a see-through line 18 for daylight reaching the front electrode layer 12 by removing the back electrode layer 14 and the photoelectric conversion layer 13 is provided. A predetermined number is formed in the horizontal direction orthogonal to the third scribe lines 17 with a predetermined interval in the vertical direction.

  Here, the separation line 19 is formed to have a line width of, for example, 0.38 mm, and the see-through line 18 is formed to, for example, 0.1 mm. The line 17 is formed to 0.08 mm, for example.

  The light transmissive solar cell module 1 configured in this manner is configured to connect the power generation regions 11A1 to 11A9 in series, in parallel, or in series-parallel to take out the output.

As the translucent insulating substrate 11, a glass substrate or the like can be used. The surface electrode layer 12 may for example ZnO, ITO, may be used, such as SnCl _2, a transparent conductive oxide having a light permeability (TCO). For example, the photoelectric conversion layer 13 may have a structure in which a p layer, an i layer, and an n layer made of a semiconductor thin film are sequentially stacked. As the semiconductor thin film, for example, an amorphous silicon thin film, a crystalline silicon thin film, or a combination thereof can be used.

  As the back electrode layer 14, for example, a layer having a layer made of a conductive oxide such as ZnO and a layer made of a metal such as silver or a silver alloy can be used. As a more general back electrode layer, a laminate of ZnO / Ag can be exemplified.

  Next, a manufacturing method (manufacturing method) of the light transmissive solar cell module 1 having the above configuration will be described.

First, for example, SnO ₂ (tin oxide) is formed as the surface electrode layer 12 on the translucent insulating substrate 11 such as a glass substrate by a thermal CVD method or the like (this is referred to as step 1).

  Next, the surface electrode layer 12 is patterned using a fundamental wave (wavelength: 1064 nm) of a YAG laser. That is, laser light is incident from the surface side of the translucent insulating substrate 11 (the lower surface side in FIGS. 3 and 4), whereby the surface electrode layer 12 is separated into strips by laser scribe, and the separation line (first scribe line). Line) 15 is formed (this is referred to as step 2).

  Next, the photoelectric conversion layer 13 is formed by ultrasonic cleaning with pure water. As the photoelectric conversion layer 13, for example, an upper (light-receiving surface side) cell made of an a-Si: Hp layer, an a-Si: Hi layer, a lower cell made of a μc-Si: Hp layer, and a μc-Si: Hn layer is used. A film is formed (this is referred to as step 3).

Next, the photoelectric conversion layer 13 is patterned with a laser using, for example, a second harmonic (wavelength: 532 nm) of a YAG laser or a YVO ₄ laser. That is, by making laser light enter from the surface side of the translucent insulating substrate 11, the photoelectric conversion layer 13 is separated into strips by laser scribing, and the front electrode layer 12 and the back electrode layer 14 are electrically connected. For this purpose, a contact line (second scribe line) 16 is formed (this is referred to as step 4).

Next, a film of ZnO (zinc oxide) / Ag is formed as the back electrode layer 14 by magnetron sputtering or the like (this is referred to as step 5). The thickness of ZnO can be about 50 nm. Note that a highly light-transmitting film such as ITO or SnO ₂ may be used instead of ZnO. The film thickness of silver can be about 125 nm. Note that the transparent conductive film such as ZnO described above may be omitted in the back electrode layer 14, but it is desirable to obtain high conversion efficiency.

Next, the photoelectric conversion layer 13 and the back electrode layer 14 are patterned using a second harmonic (wavelength: 532 nm) of a YAG laser or a YVO ₄ laser, for example. That is, by making laser light incident from the front surface side of the translucent insulating substrate 11, the photoelectric conversion layer 13 and the back electrode layer 14 are separated into strips by laser scribing, and a separation line (third) that reaches the front electrode layer 12. A scribe line 17 is formed (this is referred to as step 6). At this time, it is preferable to select a processing condition that suppresses damage to the front electrode layer 12 to a minimum and suppresses generation of burrs of the silver electrode after processing the back electrode layer 14.

Next, in order to form the separation line 19 that separates the power generation unit 11A into the six power generation regions 11A1 to 11A6, for example, using a second harmonic (wavelength: 532 nm) of a YAG laser or a YVO ₄ laser, a surface electrode layer 12. The photoelectric conversion layer 13 and the back electrode layer 14 are patterned with a laser. That is, by making laser light enter from the surface side of the translucent insulating substrate 11, the surface electrode layer 12, the photoelectric conversion layer 13, and the back electrode layer 14 at the boundary portion of each power generation region are removed in a groove shape by laser scribing. Then, a separation line 19 having a predetermined width reaching the translucent insulating substrate 11 is formed (this is referred to as step 7).

Finally, in order to form a see-through line that transmits incident light from the surface (light receiving surface) of the translucent insulating substrate 11 to the back electrode layer 14 side, for example, a second harmonic (wavelength: 532 nm) of a YAG laser, The YVO ₄ laser is used to pattern the photoelectric conversion layer 13 and the back electrode layer 14 with a laser. That is, by making laser light incident from the front surface side of the translucent insulating substrate 11, the photoelectric conversion layer 13 and the back electrode layer 14 are separated into strips by laser scribing, and a separation line (see-through line) reaching the front electrode layer 12. ) 18 is formed (this is referred to as step 8).

  In this way, the light transmissive solar cell module 1 having the configuration shown in FIGS. 1 to 4 is manufactured.

  In the light transmissive solar cell module 1 having such a configuration, the back electrode layer 14 and the photoelectric conversion layer as well as the see-through line 18 as well as the see-through line 18 are used as a light transmitting line (light transmitting portion). 13 is formed by removing the back electrode layer 14, the photoelectric conversion layer 13, and the surface electrode layer 12 in order to separate the third scribe line 17 formed by removing 13 and the power generation unit 11A into a plurality of power generation regions 11A1 to 11A6. There are three types of separated lines 19.

  And when such a light transmission type solar cell module 1 is arrange | positioned at a window glass, a roof, a show window, etc., the 3rd scribe line 17 and the see-through line 18 of the light transmission type solar cell module 1 formed in linear form, Furthermore, there is a possibility that the separation line 19 interferes with a design such as a screen door, a blind, a lace curtain, a display monitor, a design image, and other structures to generate interference fringes.

Therefore, in the present invention, the above-described third scribe line 17 and see-through line 18 that are light transmission portions, and further, the separation line 19 are formed in an irregular pattern, so that the design of the structure to be arranged in the front and rear, etc. Generation of interference fringes is reduced.
Hereinafter, a specific example of the formation pattern of the light transmission part will be described.

<Specific example 1>
5 is a plan view of the external configuration of the light transmissive solar cell module 1A of Example 1 as viewed from the back side (the side opposite to the light receiving surface), and FIG. 6 is the light transmissive solar cell module 1A shown in FIG. It is an enlarged view of B part.

  In the light transmissive solar cell module 1A of Example 1, the see-through line 18 described in the basic configuration is a see-through portion 18a formed by a plurality of holes. In the specific example 1, the size of each hole of the see-through portion 18 a is formed to be the same size, and the arrangement pattern is irregularly formed so as to be different for each solar battery cell 21. Further, the third scribe line 17a is not a straight line but a gently curved line in which irregular waveforms continue. Further, the separation line 19a is not a straight line but a gently curved line in which irregular waveforms continue.

  In the specific example 1, the shape of the hole of the see-through portion 18a is circular. It can be shaped. Moreover, you may combine these shapes.

  However, the see-through portion 18a needs to be formed so that the power generation regions of the divided solar cells 21 have the same area. In this sense, the same applies to the third scribe line 17a and the separation line 19a. That is, it is necessary to make the amount of current flowing through each solar battery cell 21 the same by setting the power generation region of each solar battery cell 21 to the same area. This is because if the areas of the power generation regions of the solar cells 21 are different, current is limited by the solar cells 21 with the smallest amount of flowing current, resulting in an overall power generation loss. This also applies to the following specific examples.

  As shown in FIG. 7A, the light transmission type solar cell module 1A formed in this way is arranged behind a screen door 90 having a fine mesh regularly arranged in a lattice shape, and FIG. 7B. As shown, for example, when arranged in front of a screen door or the like 90 in which a fine mesh is regularly formed in a lattice shape, the pattern of the mesh and the light transmission pattern of the light transmission part of the light transmission type solar cell module 1A are: Although some of the intersections do not overlap completely, the occurrence of interference fringes can be greatly reduced or suppressed to the point where they cannot be seen. In daily life, the occurrence of interference fringes is greatly reduced or disappeared, so that daily stress due to the appearance of interference fringes can be reduced. Furthermore, it is possible to avoid the occurrence of danger due to the optical illusion.

<Specific example 2>
8 is a plan view of the external configuration of the light transmissive solar cell module 1B of Example 2 as viewed from the back side (the side opposite to the light receiving surface), and FIG. 9 is the light transmissive solar cell module 1B shown in FIG. It is an enlarged view of C part.

  In the light transmissive solar cell module 1B of the specific example 2, the see-through line 18 described in the basic configuration is a see-through portion 18b formed by a plurality of holes. In the specific example 2, the size of each hole of the see-through portion 18b is an irregular size mixed in size. However, in the specific example 2, the size and arrangement pattern of the holes of the see-through portion 18 b are substantially the same in each solar cell 21. Further, the third scribe line 17b is not a straight line but a gently curved line in which irregular waveforms continue. Further, the separation line 19b is not a straight line but a gently curved line in which irregular waveforms continue.

  In the specific example 2, the shape of the hole of the see-through portion 18b is an ellipse. However, the shape is not limited to the ellipse. It is possible to have a shape of Moreover, you may combine these shapes.

  For example, when the light transmission type solar cell module 1B formed in this way is arranged before and after a screen door or the like in which a fine mesh is regularly formed in a lattice shape, the illustration is omitted, but FIG. As in the case shown in FIG. 7B, the mesh pattern and the light transmission pattern of the light transmission part of the light transmission type solar cell module 1B intersect partly but do not completely overlap. It can be reduced or suppressed to an extent where it cannot be seen. In daily life, the occurrence of interference fringes is greatly reduced or disappeared, so that daily stress due to the appearance of interference fringes can be reduced. Furthermore, it is possible to avoid the occurrence of danger due to the optical illusion.

<Specific example 3>
10 is a plan view of the external configuration of the light transmissive solar cell module 1C of Example 3 as viewed from the back side (the side opposite to the light receiving surface), and FIG. 11 is the light transmissive solar cell module 1C shown in FIG. It is an enlarged view of D part.

  In the light transmissive solar cell module 1C of Example 3, the see-through line 18 described in the basic configuration is a see-through portion 18c formed by a plurality of holes. Moreover, in the specific example 3, the number and size of each hole of the see-through portion 18 c are irregularly formed for each solar battery cell 21, and the arrangement pattern is irregularly formed for each solar battery cell 21. It has been configured. That is, the specific example 3 has a configuration in which the specific example 1 and the specific example 2 are combined. Further, the third scribe line 17c is not a straight line but a gently curved line in which irregular waveforms continue. Further, the separation line 19c is not a straight line but a gently curved line in which irregular waveforms continue.

  In the specific example 3, the shape of the hole of the see-through portion 18c is an ellipse. However, the shape is not limited to an ellipse. It is possible to have a shape of Moreover, you may combine these shapes.

  For example, when the light transmission type solar cell module 1C formed in this way is arranged before and after a screen door or the like in which a fine mesh is regularly formed in a lattice shape, the illustration is omitted, but FIG. As in the case shown in FIG. 7B, the mesh pattern and the light transmission pattern of the light transmission part of the light transmission type solar cell module 1B intersect partly but do not completely overlap. It can be reduced or suppressed to an extent where it cannot be seen. In daily life, the occurrence of interference fringes is greatly reduced or disappeared, so that daily stress due to the appearance of interference fringes can be reduced. Furthermore, it is possible to avoid the occurrence of danger due to the optical illusion.

<Specific Example 4>
FIG. 12 is a plan view of the external configuration of the light transmissive solar cell module 1D of Example 4 as viewed from the back surface side (the side opposite to the light receiving surface).

  In the specific example 4, as in the above basic configuration, the see-through line 18d, the third scribe line 17d, and the separation line 19d are formed in a straight line. However, in the specific example 4, the see-through line 18d, the third scribe line 17d, and the separation line 19d are formed to be inclined with respect to each side of the module main body (specifically, the translucent insulating substrate 11) (that is, , Formed at an angle other than 0 degrees and 90 degrees). In Specific Example 4, the see-through line 18d is formed in a lattice shape that intersects the horizontal direction and the vertical direction, but may be formed only in the horizontal direction or only in the vertical direction. Further, in the fourth specific example, the see-through line 18d, the third scribe line 17d, and the separation line 19d are formed to be inclined in this way, so that each of the light-transmitting solar cell modules 1D on the light-transmitting insulating substrate 11 is formed. A triangular dummy region 11a in which the solar cells 21 are not formed is formed on the side.

  According to the specific example 4, the see-through line 18d, the third scribe line 17d, and the separation line 19d are linear. However, the see-through line 18d, the third scribe line 17d, and the separation line 19d are formed to be inclined with respect to each side of the light-transmissive solar cell module 1D (specifically, the light-transmissive insulating substrate 11). Therefore, for example, even when this light-transmissive solar cell module is arranged before and after a screen door or the like in which a fine mesh is regularly formed in a lattice shape, the mesh pattern, the see-through line 18d, the third scribe line 17d And the patterns of the separation line 19d intersect at a slight angle and do not completely overlap, so that the generation of interference fringes can be greatly reduced or suppressed to an invisible level. In daily life, the occurrence of interference fringes is greatly reduced or disappeared, so that daily stress due to the appearance of interference fringes can be reduced. Furthermore, it is possible to avoid the occurrence of danger due to the optical illusion.

<Specific Example 5>
FIG. 13 is a plan view of the external configuration of the light transmissive solar cell module 1E of Example 5 as viewed from the back side (the side opposite to the light receiving surface).

  Specific example 5 is a configuration closest to the light transmission type solar cell module 1 having the basic configuration shown in FIG. 1, and each of the see-through line 18e, the third scribe line 17e, and the separation line 19e is a non-linear irregularity. The structure is formed in a simple line. Specifically, as shown in FIG. 13, each line 18e, 17e, 19e is a gently curved line in which irregular waveforms continue. In the specific example 5, the see-through line 18e is formed in a lattice shape intersecting the horizontal direction and the vertical direction, but may be formed only in the horizontal direction or only in the vertical direction.

  For example, when the light transmission type solar cell module 1E formed in this way is arranged before and after a screen door or the like in which a fine mesh is regularly formed in a lattice shape, the illustration is omitted, but FIG. As in the case shown in FIG. 7B, the mesh pattern and the light transmission pattern of the light transmission part of the light transmission type solar cell module 1E intersect partly but do not completely overlap. It can be reduced or suppressed to an extent where it cannot be seen. In daily life, the occurrence of interference fringes is greatly reduced or disappeared, so that daily stress due to the appearance of interference fringes can be reduced. Furthermore, it is possible to avoid the occurrence of danger due to the optical illusion.

  In each of the above specific examples, the see-through portion, the see-through line, the third scribe line, and the separation line are formed in an arbitrary shape. However, as described in the basic configuration, the see-through portion, the see-through line, The three scribe lines and the separation line are formed by laser processing. Therefore, since it is easy to repeatedly irradiate a laser along a random curve once determined, it is possible to form a see-through portion, a see-through line, a third scribe line, and a separation line as in the above specific examples. Easy. In addition, for the see-through portions 18a to 18c having a hole shape, it is best to make the entire surface of the power generation portion 11A irregular (random). For example, 10 pieces corresponding to one solar battery cell 21 Even if a basic see-through hole pattern of the same area is prepared in advance and applied to all the solar cells 21 in an arbitrary combination, the see-through portions 18a to 18c are apparently incapable of the entire power generation unit 11A. It can appear to be formed in a regular pattern. By using such a combination of basic see-through hole patterns, it is possible to manufacture an actual light-transmissive solar cell module relatively easily.

  In the above embodiment, the see-through line 18 is formed so as to reach the front electrode layer 12 by removing the back electrode layer 14 and the photoelectric conversion layer 13. However, the back electrode layer 14, the photoelectric conversion layer 13, and the front surface are formed. The electrode layer 12 may be removed and formed so as to reach the translucent insulating substrate 11.

  Furthermore, in the said embodiment, the light transmissive solar cell module 1 of the structure which isolate | separated the electric power generation part 11A into nine electric power generation area | regions 11A1-11A9 with the separation line 19 is mentioned as an example, and it demonstrates as a light transmissive solar cell module. However, some small light transmission solar cell modules do not have this separation line. The present invention can also be applied to a light transmission type solar cell module having no separation line.

1, 1A to 1E Light transmission type solar cell module 11A Power generation unit 11A1 to 11A9 Power generation region 11 Translucent insulating substrate (module body)
11a Dummy region 12 Transparent surface electrode layer 13 Photoelectric conversion layer 14 Back electrode layer 15 Separation line (first scribe line)
16 Contact line (second scribe line)
17, 17a-17e Third scribe line 18, 18a-18e See-through line 19, 19a-19e Separation line 21 Solar cell 90 Screen door, etc.

Claims (7)

A light transmissive solar cell module having a see-through line through which light passes from the front surface to the back surface of the power generation unit,
The see-through line is formed in a pattern that is not parallel to each side of the module body,
The power generation unit is formed by a plurality of solar cells in which a front electrode layer, a photoelectric conversion layer, and a back electrode layer are sequentially stacked on a light-transmitting insulating substrate,
The see-through line is formed by removing the back electrode layer and the photoelectric conversion layer, and is formed in the plurality of solar cells to transmit light without cell separation ,
The see-through line is formed in a direction crossing a scribe line that separates the power generation unit into the plurality of solar cells, and is spaced from the end of the plurality of solar cells in the direction of the scribe line. Are formed to line up,
The see-through line is formed so as to be inclined with respect to each side of the module body. A light transmissive solar cell module having a see-through line through which light passes from the front surface to the back surface of the power generation unit,
The see-through line is formed in a pattern that is not parallel to each side of the module body,
The power generation unit is formed by a plurality of solar cells in which a front electrode layer, a photoelectric conversion layer, and a back electrode layer are sequentially stacked on a light-transmitting insulating substrate,
The see-through line is formed by removing the back electrode layer and the photoelectric conversion layer, and is formed in the plurality of solar cells to transmit light without cell separation ,
The see-through line is formed in a direction crossing a scribe line that separates the power generation unit into the plurality of solar cells, and is spaced from the end of the plurality of solar cells in the direction of the scribe line. Are formed to line up,
The light transmission type solar cell module, wherein the scribe line and the see-through line are formed in a non-linear irregular curve pattern. A light transmissive solar cell module having a see-through portion through which light passes from the front surface to the back surface of the power generation unit,
The see-through part is formed in a pattern that is not parallel to each side of the module body,
The power generation unit is formed by a plurality of solar cells in which a front electrode layer, a photoelectric conversion layer, and a back electrode layer are sequentially stacked on a light-transmitting insulating substrate,
The plurality of solar cells separate the power generation unit into a plurality of power generation regions by a separation line formed by removing the photoelectric conversion layer and the surface electrode layer, and the back electrode layer and the photoelectric conversion layer Is obtained by separating each power generation region into a plurality of the solar cells by a scribe line formed by removing,
The see-through part is formed by removing the back electrode layer and the photoelectric conversion layer, and is formed in the plurality of solar cells to transmit light without cell separation ,
The light transmission type solar cell module, wherein the separation line is formed in a non-linear irregular curve pattern, and the see-through portion is formed in a plurality of hole shapes . The light transmissive solar cell module according to claim 3 ,
The see-through portion is a light transmissive solar cell module, wherein the holes have the same size, and the arrangement pattern is irregularly formed. The light transmissive solar cell module according to claim 3 ,
The see-through portion is a light transmissive solar cell module, wherein the size of the holes is irregular. The light transmissive solar cell module according to claim 3 ,
The see-through portion is a light transmissive solar cell module characterized in that the size of the holes is irregularly formed and the arrangement pattern thereof is irregularly formed. The light transmissive solar cell module according to any one of claims 1 to 6 ,
Each of the cells is formed such that a power generation region excluding the light transmission portion has the same area.

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