JP6397703B2 - Solar cell module and wall surface forming member - Google Patents

Description

  The present invention relates to a solar cell module having light-receiving surfaces on both sides. The present invention also relates to a wall surface forming member such as a window using the solar cell module.

In recent years, solar cell modules have attracted attention as energy sources with low environmental impact.
This solar cell module is a photoelectric conversion device capable of converting light energy into electric energy.
The solar cell module includes a transparent electrode layer, a back electrode layer, and a photoelectric conversion layer including a semiconductor junction or the like sandwiched between the two electrode layers. In this solar cell module, carriers (electrons and holes) generated by irradiating the photoelectric conversion layer with light can be collected by the electrode layer and taken out to an external circuit.
In addition, this solar cell module uses a glossy metal as the back electrode layer, so that the light that has passed through the photoelectric conversion layer is also reflected by the back electrode layer and collected by the photoelectric conversion layer. The amount of power generation is improved.

Conventional solar cell modules are installed in a posture that is parallel or slightly inclined with respect to the ground in order to ensure a sufficient incident area for sunlight. Therefore, in the migrating environment, the installation position of the solar cell module has been limited to a flat ground or a roof.
However, since the area of a roof in a general building is limited, there is a problem that if a solar cell is attached to the entire surface of the roof, it cannot be added. Therefore, with the widespread use of solar cell modules, a search for a new solar cell module installation location has been made.

Therefore, in Patent Document 1, attention is paid to a window as an installation location of the solar cell module, and a solar cell (solar cell module) that can be used as a window has been proposed.
The solar cell of Patent Document 1 has a structure in which sunlight can be taken into an indoor space even at a power generation site by using a transparent electrode as a back electrode layer.

JP 2001-320068 A JP-A-2005-311292

By the way, according to the solar cell of patent document 1, since light can be taken out from an electric power generation part, when it uses for the window of a building, light can be taken in indoor space.
However, in the solar cell of Patent Document 1, since a part of the light is used for photoelectric conversion in the photoelectric conversion layer, the amount of light taken in is smaller than that of a normal window, and the amount of light collected is not sufficient for some users. You may feel that. Moreover, in order to approximate the amount of light collected from a normal window, it is preferable that sunlight can be collected inside the building as much as possible.

  Then, in view of the above-mentioned problem, it aims at providing the solar cell module and wall surface formation member which can obtain high lighting property, suppressing the rapid fall of an electric power generation area compared with the past.

The invention described in claim 1 for solving the above-described problems includes a first light-transmissive insulating substrate, a second light-transmissive insulating substrate, the first light-transmissive insulating substrate, and a second light-transmissive insulating substrate. In a solar cell module including a photoelectric conversion element sandwiched between substrates, the photoelectric conversion element is laminated in the order of a first transparent electrode layer, a photoelectric conversion layer, and a second transparent electrode layer from the first light-transmissive insulating substrate side. The photoelectric conversion layer is capable of converting light energy into electric energy when irradiated with light, and transmits a part of the light. When the light-transmitting insulating substrate is viewed in plan, it has an opening from which at least the photoelectric conversion layer has been removed, and when light is irradiated from the first light-transmitting insulating substrate side, it passes through the inside of the opening. And an optical path to the second light-transmissive insulating substrate. An element separation groove for dividing the element into a plurality of small pieces, an electrode connection groove from which the photoelectric conversion layer is partially removed, and a first electrode separation groove from which the first transparent electrode layer is partially removed, The electrode connection groove forms at least a part of the opening. In the photoelectric conversion element, a part of the second transparent electrode layer of one small piece enters the electrode connection groove, and the other small piece. The one small piece and the other small piece are electrically connected in series by being in contact with the first transparent electrode layer, and when the light is irradiated from the first light-transmissive insulating substrate side, An optical path that passes through the interior and reaches the second light-transmissive insulating substrate is provided, the second transparent electrode layer is formed of a transparent conductive oxide, and the groove width of the electrode connection groove is The width of the first electrode separation groove is 90 μm or more and 120 μm or less. It is a solar cell module to be.
That is, the present invention provides a solar light comprising a first light-transmissive insulating substrate, a second light-transmissive insulating substrate, and a photoelectric conversion element sandwiched between the first light-transmissive insulating substrate and the second light-transmissive insulating substrate. In the battery module, the photoelectric conversion element is laminated in order of a first transparent electrode layer, a photoelectric conversion layer, and a second transparent electrode layer from the first light-transmissive insulating substrate side, Light energy can be converted into electrical energy when irradiated with light, and a part of the light is transmitted. The photoelectric conversion element is a plan view of the first light-transmissive insulating substrate. , Having an opening from which at least the photoelectric conversion layer is removed, and passing through the inside of the opening when irradiated with light from the first light-transmitting insulating substrate side, the second light-transmitting insulating substrate that provides an optical path to the.

  Here, “translucency” refers to a function of transmitting at least part of light, and specifically refers to a light transmittance of 30% to 100%. That is, even if it is a board | substrate with which the glare-proof process was performed, if 30% or more of light is permeate | transmitted, it corresponds to the translucency of this specification.

According to the configuration of the present invention, all of the first light-transmissive insulating substrate, the first transparent electrode layer, the photoelectric conversion layer, the second transparent electrode layer, and the second light-transmissive insulating substrate transmit light. Even if light is incident from the first light-transmitting insulating substrate side or light is incident from the second light-transmitting insulating substrate side, the light can be collected and generated by the photoelectric conversion layer. Therefore, compared with the conventional solar cell module that can receive light only on one side, the light receiving area increases, and the amount of light taken into the photoelectric conversion layer increases. Therefore, even a thin-film solar cell, which is generally considered to have a lower power generation efficiency than a crystalline silicon solar cell, can extract more electricity.
According to the configuration of the present invention, any of the first light-transmissive insulating substrate, the first transparent electrode layer, the photoelectric conversion layer, the second transparent electrode layer, and the second light-transmissive insulating substrate transmits light. Therefore, it is possible to take daylight even in the power generation part. Therefore, according to the solar cell module of the present invention, it is possible to maintain daylighting while securing a power generation area, and therefore, it can be installed in places other than the roof such as windows, veranda railings, and balcony railings.
Furthermore, according to the structure of this invention, it has the opening part from which the photoelectric converting layer was removed, and when it irradiates light from the 1st translucent insulating board | substrate side in addition to the optical path which passes along an electric power generation part. Since it has an optical path that passes through the inside of the opening and reaches the second light-transmissive insulating substrate, it is possible to compensate for the shortage of light quantity due to the consumption of light in the photoelectric conversion layer. It can be close to the amount of light collected in the window.
In the second aspect of the present invention, irregularities are formed on the outer principal surface of the first translucent insulating substrate with reference to the photoelectric conversion element, and the outer principal surface has an arithmetic average roughness. 0.25 μm or more and 1.25 μm or less, 60 ° specular gloss according to JIS Z 8741 is 8% or less, and the photoelectric conversion layer has two photoelectric conversion units having different spectral sensitivities, The two photoelectric conversion units are a crystalline photoelectric conversion unit including a crystalline silicon layer and an amorphous photoelectric conversion unit including an amorphous silicon layer, and the amorphous photoelectric conversion unit includes the crystalline photoelectric conversion unit. 2. The solar cell module according to claim 1, wherein the solar cell module is located on the second light-transmissive insulating substrate side with respect to the unit.

Here, according to the structure of said invention, the amount of light collection can be increased by providing an opening.
However, since the photoelectric conversion layer does not exist in the opening, there is a problem in that the opening cannot generate power and the power generation area that can be generated is reduced.

Incidentally, among solar cell modules, there is a solar cell module in which a plurality of photoelectric conversion elements are stacked on a so-called integrated type substrate (for example, Patent Document 2).
In this integrated solar cell module, a photoelectric conversion element is divided into a plurality of small pieces by a plurality of grooves. This groove is inevitably formed in order to partition the photoelectric conversion element, and is a portion that does not generate power originally.
Therefore, the present inventor has paid attention to this groove and tried to suppress a substantial decrease in the power generation area by forming an opening in the groove.

That is, the invention described in claim 3 has an element isolation groove for dividing the photoelectric conversion element into a plurality of small pieces, and the element isolation groove forms at least a part of the opening, The plurality of small pieces are electrically connected in series or in parallel, respectively, and pass through the element isolation trench when irradiated with light from the first light-transmissive insulating substrate side, and the second light-transmissive a solar cell module according to claim 1 or 2, characterized in that it comprises an optical path to the light insulating substrate.

  According to the configuration of the present invention, since the opening is formed by the element isolation groove, a substantial reduction in the power generation area can be suppressed. That is, according to the structure of this invention, it becomes a solar cell module excellent in the lighting function, maintaining the electric power generation efficiency comparable as the conventional solar cell module.

By the way, in the solar cell module described in Patent Document 2, adjacent pieces of photoelectric conversion elements are connected in series, and voltage is sequentially added to each piece.
Specifically, a connection groove for connecting the electrode layers to each other is formed in the photoelectric conversion layer of the photoelectric conversion element, and the transparent electrode layer and the back electrode layer of a small piece of the adjacent photoelectric conversion element are connected via the connection groove. ing. That is, this connection groove is a groove necessary for electrically connecting small pieces of adjacent photoelectric conversion elements in series, and is a portion that does not generate electricity originally.
Therefore, the inventor paid attention to the connection groove and tried to suppress a substantial decrease in the power generation area by forming an opening in the connection groove.

That is, the invention according to claim 1 includes an element separation groove that divides the photoelectric conversion element into a plurality of small pieces, and an electrode connection groove from which the photoelectric conversion layer is partially removed. The photoelectric conversion element is configured to form at least a part of the opening, and a part of the second transparent electrode layer of one small piece enters the electrode connection groove and the first transparent electrode of the other small piece is formed in the photoelectric conversion element. By contacting the layer, the one small piece and the other small piece are electrically connected in series, and when light is irradiated from the first translucent insulating substrate side, the inside of the electrode connection groove passes, that provides an optical path to the second transparent insulating substrate.

Since the conventional solar cell module represented by patent document 2 uses the glossy metal for the back electrode layer as described above, the portion where the back electrode layer is formed does not transmit light. Absent. Therefore, even if the connection groove is formed, the connection groove is filled with a part of the back electrode layer, so that the light cannot be taken from the connection groove.
On the other hand, according to the configuration of the present invention, since the back electrode layer is the first transparent electrode layer or the second transparent electrode layer and is transparent, the electrode connection groove can be used as a part of the opening.
That is, according to the configuration of the present invention, since at least a part of the opening is formed by the electrode connection groove, it is possible to prevent a significant reduction in the power generation area due to formation of the opening.
Further, according to the configuration of the present invention, the photoelectric conversion element is partitioned into a plurality of small pieces by the element isolation groove, and one small piece and the other small piece among the plurality of small pieces are electrically connected via the electrode connection groove. They are connected in series. Therefore, since the current generated in one piece is transmitted to the other pieces and flows, the voltage can be sequentially added in each piece. Therefore, the power generation amount in the entire solar cell module can be improved.

  The invention according to claim 4 is characterized in that when the first light-transmissive insulating substrate is viewed in plan, the opening area of the opening is 20% or less of the area of the first light-transmissive insulating substrate. The solar cell module according to claim 1.

  According to the configuration of the present invention, since it is possible to perform daylighting even at the power generation site, the daylighting function can be sufficiently exhibited even with a low aperture ratio.

  Invention of Claim 5 has a film-form sealing member, and the said sealing member is what seals a photoelectric conversion element, and has elasticity, The said sealing member is 5. The solar cell module according to claim 1, wherein most of the solar cell module is disposed between the photoelectric conversion element and the second light-transmissive insulating substrate.

According to the configuration of the present invention, since the photoelectric conversion element is sealed by the film-shaped sealing member, the increase in thickness due to the sealing member is small, and accordingly, the first light-transmissive insulating substrate and the second light-transmitting substrate. The thickness of the light insulating substrate can be increased. Therefore, for example, even when the solar cell module is provided on a window or the like and exposed to a strong wind such as a typhoon, the solar cell module can be provided with sufficient rigidity to withstand. it can. In contrast, since the increase in thickness by the sealing member is small, the thickness of the solar cell module can be reduced.
Furthermore, according to the structure of this invention, since the sealing member has elasticity, it is a case where it uses for a window etc., for example, Comprising: A 1st translucent insulated substrate and a 2nd translucent insulated substrate are used. Even when pinched with a fixing bracket, the pressing force received by the first translucent insulating substrate and the second translucent insulating substrate from the fixing bracket can be relieved by the sealing member, preventing damage to the photoelectric conversion element. can do.

  By the way, when the solar cell module is used for a handrail such as a window or a veranda, one side of the solar cell module is arranged on another building or road side. As a result, the substrate that forms the surface of the solar cell module acts as a mirror, reflecting sunlight, and there may be situations where neighboring residents and passersby point out that “dazzle” or “glare” may occur. .

Accordingly, in the invention according to claim 2 , the outer main surface of the first translucent insulating substrate is formed with irregularities on the basis of the photoelectric conversion element, and the arithmetic average roughness of the outer main surface. is at 0.25μm or 1.25μm or less, 60 degree specular gloss equivalent to JIS Z 8741 is Ru der than 8 percent.

  According to the structure of this invention, the unevenness | corrugation is formed in the outer surface of the 1st translucent insulated substrate, and the glare-proof process is performed. Therefore, for example, even when the solar cell module is used for a window or the like, sunlight is first generated by arranging the first light-transmissive insulating substrate on the outside of the building (on the other building or road side). It is possible to prevent the occurrence of “glare” and “glare” due to reflection on the light-transmitting insulating substrate.

  In the above invention, the first light-transmissive insulating substrate may be made of glass.

  According to this invention, it is easy to perform surface processing and it is easy to form unevenness.

By the way, in a building such as an office building, the inside of the building may be illuminated by an illumination device such as a fluorescent lamp regardless of day or night.
However, in the conventional solar cell module, since it was single-sided light reception, it generate | occur | produced only with sunlight and the light by an illuminating device was not utilized for electric power generation.

Accordingly, the invention described in claim 6 is a first light-transmitting insulating substrate, a second light-transmitting insulating substrate, and a photoelectric sandwiched between the first light-transmitting insulating substrate and the second light-transmitting insulating substrate. A wall surface forming member using a solar cell module including a conversion element, wherein the photoelectric conversion element is a first transparent electrode layer from the first light-transmissive insulating substrate side. , A photoelectric conversion layer, and a second transparent electrode layer are laminated in this order, and the photoelectric conversion layer can convert light energy into electrical energy when irradiated with light, and a part of the light. The photoelectric conversion element has an opening from which at least the photoelectric conversion layer is removed when the first light-transmitting insulating substrate is viewed in plan, and the solar cell module includes the first light-transmitting element. Of the opening when light is irradiated from the conductive insulating substrate side. The solar cell module includes an element isolation groove for dividing the photoelectric conversion element into a plurality of small pieces, and a portion of the photoelectric conversion layer. And the first electrode separation groove from which the first transparent electrode layer is partially removed, and the electrode connection groove forms at least a part of the opening. And the photoelectric conversion element is configured such that a part of the second transparent electrode layer of one small piece enters the electrode connection groove and contacts the first transparent electrode layer of the other small piece. The solar cell modules pass through the inside of the electrode connection groove when irradiated with light from the first light-transmissive insulating substrate side, and the second light-transmissive pieces are connected in series. An optical path to the light insulating substrate, and the solar cell module is It is arranged so as to divide the space inside and outside the building, the second translucent insulating substrate is arranged on the inner space side of the building, and the first translucent insulating substrate is arranged on the outer space side of the building, The second transparent electrode layer is formed of a transparent conductive oxide, and the groove width of the electrode connection groove is larger than the groove width of the first electrode separation groove, and is 90 μm or more and 120 μm or less. The conversion layer has two photoelectric conversion units having different spectral sensitivities, and among the two photoelectric conversion units, the photoelectric conversion unit whose absorption wavelength peak is close to 550 nm is located on the second translucent insulating substrate side. The two photoelectric conversion units are a crystalline photoelectric conversion unit including a crystalline silicon layer and an amorphous photoelectric conversion unit including an amorphous silicon layer, and the amorphous photoelectric conversion unit is For crystalline photoelectric conversion unit It is the wall forming member, characterized in that located in the second transparent insulating substrate side and.
The present invention is a wall surface forming member that uses the above solar cell module, and in the wall surface forming member that forms the outer wall surface of the building, the solar cell module is arranged so as to divide the space inside and outside the building. The second translucent insulating substrate is disposed on the inner space side of the building, the first translucent insulating substrate is disposed on the outer space side of the building, and the photoelectric conversion layer includes two photoelectric transistors having different spectral sensitivities. It has a conversion unit, wherein the two photoelectric conversion units, the photoelectric conversion unit near the peak of the absorption wavelength to 550nm is associated with a second transparent insulating that are located on the substrate side wall surface forming member.

A general lighting device such as a fluorescent lamp has a high emission spectrum intensity near 550 nm in order to approach natural light.
Therefore, according to the configuration of the present invention, the photoelectric conversion unit having an absorption wavelength having a peak close to 550 nm is arranged on the inner space side. Therefore, the light by the lighting device in the indoor space can be efficiently converted into electricity.

  According to the solar cell module and the wall surface forming member of the present invention, it is possible to obtain a daylighting function while suppressing a rapid decrease in the power generation area as compared with the conventional case.

It is a perspective view which represents typically the installation state of the solar cell module of 1st Embodiment of this invention. It is the conceptual diagram which extracted the solar cell module vicinity of FIG. It is a disassembled perspective view of the solar cell module of FIG. It is a top view of the principal part of the solar cell module of FIG. It is AA sectional drawing of the solar cell module of FIG. It is BB sectional drawing of the solar cell module of FIG. It is explanatory drawing showing the principal part of the solar cell module of FIG. 5, and has shown the flow of the current with the arrow. 5 and FIG. 6 are explanatory diagrams showing an optical path of sunlight, in which (a) corresponds to FIG. 5 and (b) corresponds to FIG. 5 and FIG. 6 are explanatory diagrams showing an optical path of sunlight, in which (a) corresponds to FIG. 5 and (b) corresponds to FIG. It is explanatory drawing showing the relationship between the radiation spectrum of a general fluorescent lamp, and the spectral sensitivity of each photoelectric conversion unit. It is a perspective view which represents typically the installation state of the solar cell module of other embodiment of this invention. It is sectional drawing of the solar cell module of other embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail.
In the following description, the vertical positional relationship of the solar cell module 1 will be described with reference to the posture of FIG. 2 unless otherwise specified.

The solar cell module 1 of 1st Embodiment is used suitably as a fitting window of buildings, such as an office building, as FIG. 1 shows.
As shown in FIG. 2, the solar cell module 1 is a wall surface forming member that is attached to a wall 50 of a building in a vertical posture and forms a part of the outer wall surface of the building.
That is, the solar cell module 1 stands up in the vertical direction (vertical direction) with respect to the floor surface during normal use, and is divided into an indoor space 51 inside the building and an external space 52 outside the building.

The solar cell module 1 is a thin film solar cell, and as shown in FIG. 3, a photoelectric conversion element 12 formed of a plurality of thin films on a first translucent insulating substrate 10 and a second translucent insulating substrate 11. Is sandwiched between.
As shown in FIG. 4, the solar cell module 1 is a module in which the photoelectric conversion element 12 is divided into a plurality of small pieces 47 and the plurality of small pieces 47 are connected in series and / or in parallel. is there.
When the solar cell module 1 is attached to the building wall 50 as shown in FIG. 2, the first light-transmissive insulating substrate 10 is directed from the external space 52 side (outside) toward the indoor space 51 side (inside). The photoelectric conversion element 12, the sealing member 13, and the second light-transmissive insulating substrate 11 are stacked in this order.

As shown in FIG. 3, the first light-transmissive insulating substrate 10 is a light-transmissive substrate having a planar shape and is an insulating substrate that does not contribute electrically to power generation.
Specifically, the 1st translucent insulated substrate 10 is a plate-shaped glass substrate, and the glare-proof process was performed to the main surface of at least one side.
The first translucent insulating substrate 10 of the present embodiment has irregularities 15 on the outer main surface, which is the surface on the outer space 52 side, when the solar cell module 1 is attached to a building, as can be seen from FIGS. Is formed.
The arithmetic average roughness of the outer principal surface of the first light-transmissive insulating substrate 10 is preferably 0.25 μm or more from the viewpoint of suppressing regular reflection light.
Moreover, it is preferable that it is 1.25 micrometers or less from a viewpoint of suppressing the scattered light of the light by the convex part which forms the unevenness | corrugation 15, and the recessed part.

When the solar cell module 1 is assembled, the first light-transmissive insulating substrate 10 preferably has a 60 ° specular glossiness of 8% or less according to JIS Z 8741.
If it is this range, the glare and glare by direct reflection can be suppressed.

  Although the average thickness of the 1st translucent insulated substrate 10 is suitably designed by the rigidity with the 2nd translucent insulated substrate 11, installation environment, etc., it is preferable that they are 1 mm or more and 1 cm or less. If it is this range, when using the solar cell module 1 as a window, sufficient intensity | strength can be given.

The first light-transmissive insulating substrate 10 has a polygonal shape or a circular shape when seen in a plan view. As shown in FIG. 4, the first light-transmissive insulating substrate 10 of the present embodiment has a quadrangular shape and includes two sets of two opposing sides.
That is, the first translucent insulating substrate 10 is formed by extending longitudinal sides 16 and 17 extending linearly in one direction (longitudinal direction) and a direction orthogonal to the longitudinal sides 16 and 17 (lateral direction). Are provided with lateral sides 18 and 19 extending linearly in parallel.

The photoelectric conversion element 12 is a semiconductor element that extracts light energy as electric energy. As can be seen from FIGS. 5 and 6, the photoelectric conversion layer 21 is sandwiched between two transparent electrode layers 20 and 22.
Specifically, the photoelectric conversion element 12 is laminated | stacked in order of the 1st transparent electrode layer 20, the photoelectric conversion layer 21, and the 2nd transparent electrode layer 22 from the 1st translucent insulated substrate 10 side.

The 1st transparent electrode layer 20 is a transparent conductive film, and is a layer which has translucency and electroconductivity.
The constituent material of the first transparent electrode layer 20 is not particularly limited as long as it has translucency and conductivity. For example, indium tin oxide (ITO), indium zinc oxide (IZO) , Tin oxide (SnO ₂ ), zinc oxide (ZnO) and other transparent conductive oxides.
In addition, the 1st transparent electrode layer 20 may add the doping agent to the above-mentioned transparent conductive oxide.

The photoelectric conversion layer 21 is a layer having a function of converting light energy into electric energy, and is a semiconductor layer having at least a PIN structure or a PN structure.
The photoelectric conversion layer 21 is formed from one or a plurality of photoelectric conversion units.

As shown in the enlarged view of FIG. 6, the photoelectric conversion layer 21 of the present embodiment includes a crystalline photoelectric conversion unit 25 formed mainly from a crystalline silicon layer and an amorphous layer formed mainly from an amorphous silicon layer. A tandem structure in which the system photoelectric conversion units 26 are connected by a connection layer 27 is employed. In the photoelectric conversion layer 21, both the photoelectric conversion units 25 and 26 are provided with a PIN junction.
“Crystal” as used herein refers to something other than amorphous. That is, the concept includes microcrystals and polycrystals.

  As shown in the enlarged view of FIG. 6, the crystalline photoelectric conversion unit 25 includes a p-type crystalline silicon based semiconductor layer 30, an i-type crystalline silicon based semiconductor layer 31, and an n-type crystalline silicon based from the first transparent electrode layer 20 side. The semiconductor layer 32 is formed by laminating in this order.

  The amorphous photoelectric conversion unit 26 includes a p-type amorphous silicon-based semiconductor layer 35, an i-type amorphous silicon-based semiconductor layer 36, and an n-type from the first transparent electrode layer 20 side (connection layer 27 side). The amorphous silicon based semiconductor layer 37 is formed by being laminated in this order.

  The connection layer 27 is a layer that connects the photoelectric conversion units 25 and 26.

The 2nd transparent electrode layer 22 is a transparent conductive film, and is a layer which has translucency and electroconductivity.
The constituent material of the second transparent electrode layer 22 is not particularly limited as long as it has translucency and conductivity. For example, indium tin oxide (ITO), indium zinc oxide (IZO) , Tin oxide (SnO ₂ ), zinc oxide (ZnO) and other transparent conductive oxides. In addition, the 2nd transparent electrode layer 22 may add the doping agent to the above-mentioned transparent conductive oxide.

As shown in FIGS. 5 and 6, the sealing member 13 is a member that seals the photoelectric conversion element 12 and is a member that relieves the pressing force from the second light-transmissive insulating substrate 11.
The sealing member 13 is an insulating film having translucency, gas sealing properties, and elasticity.
The material of the sealing member 13 is not particularly limited as long as it has the above function. For example, a material obtained by adding a crosslinking agent to a thermoplastic resin such as ethylene / vinyl acetate copolymer (EVA) can be used.
The sealing member 13 of the present embodiment employs EVA and has an adhesion function. That is, the sealing member 13 of this embodiment can adhere the photoelectric conversion element 12 and the second light-transmissive insulating substrate 11 to each other.

The average thickness of the sealing member 13 is appropriately designed depending on the thickness of the first light-transmissive insulating substrate 10 and the like, but is 0 from the viewpoint of sufficient sealing in the assembled state of the solar cell module 1, that is, in the bonded state. It is preferable that it is 2 mm or more.
The average thickness of the sealing member 13 is 0.3 mm or more from the viewpoint of sufficiently reducing the pressing force from the second light-transmissive insulating substrate 11 and preventing damage to the photoelectric conversion element 12 in the bonded state. Is more preferable.
The average thickness of the sealing member 13 is preferably 0.8 mm or less from the viewpoint of securing the daylighting property as a window in the bonded state.

The second translucent insulating substrate 11 is a translucent substrate having a planar shape and does not contribute electrically to power generation.
Specifically, the second light-transmitting insulating substrate 11 is a plate-like glass substrate, like the first light-transmitting insulating substrate 10, but unlike the first light-transmitting insulating substrate 10, it is protected on one side. Dazzle treatment is not applied.

  Although the average thickness of the 2nd translucent insulated substrate 11 is suitably designed by rigidity with the 1st translucent insulated substrate 10, installation environment, etc., it is preferable that they are 1 mm or more and 1 cm or less. Within this range, the solar cell module 1 can be sufficiently strong.

  Next, the structure of the solar cell module 1 will be described.

As shown in FIGS. 5 and 6, the solar cell module 1 is divided into a plurality of small pieces by dividing each layer into a plurality of pieces by a plurality of grooves having different depths.
Specifically, the solar cell module 1 has the first electrode separation groove 40 from which the first transparent electrode layer 20 has been partially removed and the photoelectric conversion layer 21 to be partially removed in the cross section in the lateral direction shown in FIG. And the first element isolation groove 42 (opening) from which the photoelectric conversion layer 21 and the second transparent electrode layer 22 are partially removed. Moreover, the solar cell module 1 has the 2nd element separation groove | channel 43 (opening part) which removed the photoelectric converting layer 21 and the 2nd transparent electrode layer 22 partially in the longitudinal direction cross section shown by FIG. . The solar cell module 1 is divided into a plurality of sections by these grooves, and the photoelectric conversion element 12 is divided into a plurality of small pieces 47.

Describing each groove in detail, the first electrode separation groove 40 is a groove for separating the first transparent electrode layer 20 laminated on the first light-transmissive insulating substrate 10 as shown in FIG.
The first electrode separation groove 40 is parallel to the vertical sides 16 and 17 of the first translucent insulating substrate 10 when the first translucent insulating substrate 10 is viewed in plan, and is linear in the vertical direction. It extends.
Further, when the solar cell module 1 is viewed in cross section as shown in FIG. 5, a part of the photoelectric conversion layer 21 has entered the first electrode separation groove 40, and the photoelectric conversion layer 21 directly has the first translucency. A first separation portion 45 is formed in contact with the insulating substrate 10. That is, the first separation unit 45 physically separates the first transparent electrode layer 20 adjacent in the lateral direction into a plurality of small pieces.
The groove width of the first electrode separation groove 40 is preferably 30 μm or more and 80 μm or less.
If it is such a range, the small piece of the adjacent 1st transparent electrode layer 20 can be electrically isolate | separated, and a short circuit can be prevented.

As shown in FIG. 5, the electrode connection groove 41 is a groove that separates only the photoelectric conversion layer 21 of the photoelectric conversion element 12 into a plurality of regions.
The electrode connection groove 41 is parallel to the first electrode separation groove 40 when the first light-transmissive insulating substrate 10 is viewed in plan, and continuously or intermittently extends linearly in the vertical direction.
Further, when the solar cell module 1 is viewed in cross section as shown in FIG. 5, a part of the second transparent electrode layer 22 enters the electrode connection groove 41, and the second transparent electrode layer 22 is directly connected to the second transparent electrode layer 22. The electrode connection part 46 is formed in contact with the 1 transparent electrode layer 20.
That is, as shown in FIG. 7, the electrode connecting portion 46 includes a second transparent electrode layer 22a of one small piece 47a and a first transparent electrode layer 20b of a small piece 47b laterally adjacent to the one small piece 47a. Are electrically connected.
Therefore, the current generated in the photoelectric conversion layer 21 of each small piece 47 is directed from the second transparent electrode layer 22b side to the first transparent electrode layer 20b side through the photoelectric conversion layer 21b as shown by the arrows in FIG. However, since the first transparent electrode layer 20b is electrically connected to the second transparent electrode layer 22a by the electrode connecting portion 46, the current generated in the small piece 47b is applied to the second transparent electrode layer 22b of the adjacent small piece 47a. Flowing. Thus, since the small pieces 47a and 47b adjacent in the horizontal direction are electrically connected in series, a current flows between the small pieces 47a and 47b adjacent in the horizontal direction, and the voltage is added.

Here, in general, the conductivity of the transparent conductive film is lower than that of metal. Therefore, in order to take out an electric current efficiently, the contact area of the 2nd transparent electrode layer 22 and the 1st transparent electrode layer 20 becomes a problem.
From this point of view, the groove width of the electrode connection groove 41 is preferably 60 μm or more.
If it is such a range, sufficient electrical connection between the 2nd transparent electrode layer 22 and the 1st transparent electrode layer 20 can be taken.
By increasing the groove width of the electrode connection groove 41, light transmittance can be ensured, but an effect equal to or greater than that can be obtained by increasing the groove width of the first element isolation groove. Therefore, the groove width of the electrode connection groove 41 is more preferably 90 μm or more that can ensure sufficient electrical conduction.
The groove width of the electrode connection groove 41 is preferably 120 μm or less.
If it is such a range, the reduction | decrease in an electric power generation area can be suppressed.

As shown in FIG. 5, the first element separation groove 42 is a groove that separates both the photoelectric conversion layer 21 and the second transparent electrode layer 22 into a plurality of regions, and the photoelectric conversion element 12 is divided into a plurality of small pieces 47. It is a groove to divide.
The first element isolation groove 42 is parallel to the first electrode isolation groove 40 when the first light-transmissive insulating substrate 10 is viewed in plan, and extends linearly in the vertical direction.
Further, when the solar cell module 1 is viewed in cross section, a part of the sealing member 13 enters the first element isolation groove 42.

The groove width of the first element isolation groove 42 is preferably 55 μm or more from the viewpoint of preventing a short circuit due to contact between the second transparent electrode layers 22 of the small pieces 47 adjacent in the lateral direction.
The groove width of the first element isolation groove 42 is preferably 95 μm or less from the viewpoint of securing a sufficient area of the small piece 47 and securing a power generation area.
From the viewpoint of extracting light through the inside of the first element isolation groove 42, the light transmittance can be increased by widening the groove width, but from the viewpoint of securing a power generation area, It is preferable that the groove width is narrow.
In the present embodiment, the groove width of the first element isolation groove 42 can be determined depending on which is prioritized in consideration of the relationship between the light transmission amount and the power generation area.

As shown in FIG. 6, the second element separation groove 43 is a groove that separates the photoelectric conversion layer 21 and the second transparent electrode layer 22 into a plurality of regions, and the photoelectric conversion element 12 together with the first element separation groove 42. The groove is divided into a plurality of small pieces 47.
The second element isolation groove 43 is parallel to the lateral sides 18 and 19 when the first light-transmissive insulating substrate 10 is viewed in plan, and extends linearly in the lateral direction. That is, the second element isolation groove 43 is orthogonal to all of the first electrode isolation groove 40, the electrode connection groove 41, and the first element isolation groove 42.

  Further, when the solar cell module 1 is viewed in cross section as shown in FIG. 6, a part of the sealing member 13 enters the second element isolation groove 43.

The groove width of the second element isolation groove 43 is preferably 90 μm or more from the viewpoint of suppressing the diffusion of hot spots formed in a shaded state in the power generation state.
The groove width of the second element isolation groove 43 is preferably 150 μm or less from the viewpoint of sufficiently securing the area of the small piece 47 and securing the power generation area.
The groove width of the second element isolation groove 43 can increase the light transmittance by widening the groove width from the viewpoint of extracting light via the inside, but from the viewpoint of securing the power generation area, It is preferable that the groove width is narrow.
In the present embodiment, the groove width of the second element isolation groove 43 can be determined depending on which is prioritized in consideration of the relationship between the light transmission amount and the power generation area.

Moreover, when the solar cell module 1 is a plan view of the first light-transmissive insulating substrate 10, the total opening area of the electrode connection groove 41, the first element separation groove 42, and the second element separation groove 43 is It is preferable that it is greater than 0 percent and less than or equal to 20 percent of the area of one translucent insulating substrate.
If it is this range, light transmittance can be ensured, suppressing the reduction | decrease in an electric power generation area.

  Then, the lighting function of the solar cell module 1 of this embodiment is demonstrated.

The solar cell module 1 of this embodiment is a solar cell mainly used as a window. Therefore, the solar cell module 1 is required to be able to take light into the indoor space 51.
Therefore, the solar cell module 1 uses a transparent conductive film as the electrode layers 20 and 22 of the photoelectric conversion element 12. Therefore, as indicated by the solid line arrow in FIG. 8, sunlight incident on the first light-transmissive insulating substrate 10 from the external space 52 passes through the photoelectric conversion element 12 and escapes from the second light-transmissive insulating substrate 11. .
Specifically, the sunlight that has entered from the first light-transmissive insulating substrate 10 passes through the first transparent electrode layer 20 and is consumed by the photoelectric conversion layer 21 for power generation, and the remaining sunlight is the second transparent electrode layer. 22 reaches the second light-transmissive insulating substrate 11 without being substantially reflected. Then, the sunlight passes through the second translucent insulating substrate 11 and reaches the indoor space 51.
Thus, since the solar cell module 1 can reach the indoor space 51 with the sunlight from the external space 52, it can exhibit the daylighting function as a window.

Further, as indicated by the broken line arrow in FIG. 8, the indoor light incident on the second light-transmissive insulating substrate 11 from the indoor space 51 is hardly reflected by the second transparent electrode layer 22 of the photoelectric conversion element 12. It passes through the photoelectric conversion element 12 and leaves the first light-transmissive insulating substrate 10.
Specifically, sunlight that enters from the second light-transmissive insulating substrate 11 passes through the second transparent electrode layer 22 and is consumed by the photoelectric conversion layer 21 for power generation, and the remaining sunlight is consumed by the first transparent electrode layer. 20, passes through the first light-transmissive insulating substrate 10 and reaches the external space 52.

  As described above, the solar cell module 1 can use both the sunlight from the external space 52 and the indoor light from the indoor space 51 for power generation, and the power generation amount is improved as compared with the conventional thin film solar cell module. Can be made.

Here, since the transparent conductive film is used as the electrode layers 20 and 22 of the photoelectric conversion element 12 as described above, sunlight from the external space 52 can be taken into the indoor space 51.
However, since the outer main surface of the first light-transmissive insulating substrate 10 is subjected to anti-glare treatment and consumed by the photoelectric conversion layer 21, the amount of light collected is inferior compared to a window made of ordinary glass, The amount of light collected may not reach a sufficient level. Further, when importance is attached to the function as a window, the more the amount of light collected, the better.

Therefore, in addition to the optical path that passes through the photoelectric conversion layer 21 indicated by the arrow in FIG. 8, the solar cell module 1 of the present embodiment also has an optical path that does not pass through the photoelectric conversion layer 21 as indicated by the arrow in FIG. 9. I have.
Specifically, the solar cell module 1 also includes an optical path that passes through the electrode connection grooves 41, the first element isolation grooves 42, and the second element isolation grooves 43.
Therefore, a part of sunlight from the external space 52 can be taken into the indoor space 51 without being consumed and attenuated by the photoelectric conversion layer 21, and the lack of lighting in the indoor space 51 can be compensated. it can.
As described above, since the solar cell module 1 can perform daylighting not only through the optical path passing through the photoelectric conversion layer 21 but also through the optical path that does not pass through the photoelectric conversion layer 21, it can exhibit a sufficient daylighting function as a window.

By the way, in the indoor space of a building such as a general house, since sunlight cannot be obtained at night, the indoor space is illuminated using an illumination device such as a fluorescent lamp. In addition, in indoor spaces of buildings such as office buildings, illumination devices such as fluorescent lamps are often used to illuminate indoor spaces regardless of day or night.
However, since the conventional solar cell module can receive light only on one side, it is used with the light receiving surface facing the sun. Therefore, the power generation time of the conventional solar cell module is limited to the daytime, and it has not been possible to generate power using light such as a fluorescent lamp in the indoor space at night.
On the other hand, in the solar cell module 1 of the present embodiment, since the electrode layers 20 and 22 of the photoelectric conversion element 12 are both formed of a transparent conductive film, it is possible to receive light from both sides of the solar cell module 1. . Therefore, it is possible to generate power using light from the lighting device in the indoor space 51 even at night.

Here, it is generally known that the emission spectrum of light emitted from sunlight or a fluorescent lamp has a peak top near 550 nm as shown in FIG.
Further, as shown in FIG. 10, a general solar cell using amorphous silicon absorbs mainly at a wavelength of 300 to 600 nm, and a solar cell using crystalline silicon uses amorphous silicon. It is known that it mainly absorbs at a wavelength near 600 to 1000 nm on the longer wavelength side than the solar cell.
Conventionally, a multi-junction solar cell module in which these solar cells are joined has been focused on increasing the power generation efficiency by collecting more sunlight.
Therefore, an amorphous photoelectric conversion unit using amorphous silicon having an absorption wavelength in the vicinity of 550 nm is provided on the light receiving side (first translucent insulating substrate 10 side) from the viewpoint of further enhancing light capture, A crystalline photoelectric conversion unit 25 using crystalline silicon is provided on the top.
On the other hand, the solar cell module 1 of the present embodiment is provided with the amorphous photoelectric conversion unit 26 on the indoor space 51 side in order to generate power with high efficiency even at night as described above, and on the external space 52 side. A crystal photoelectric conversion unit 25 is provided. That is, the amorphous photoelectric conversion unit 26 having a main absorption wavelength in the vicinity of 550 nm is provided on the indoor space side. Therefore, according to the solar cell module 1 of the present embodiment, it is possible to generate power with high efficiency even at night.

  As described above, with the solar cell module 1 of the present embodiment, it is possible to obtain a daylighting function while suppressing a rapid decrease in the power generation area.

  In the above-described embodiment, the daylighting function by making the electrode layers 20 and 22 of the photoelectric conversion element 12 transparent is compensated by increasing the groove width of the groove, but the present invention is not limited to this. It is not necessary to narrow the groove width and add the daylighting function through the groove.

  In the above-described embodiment, the second element isolation groove 43 is formed by removing the photoelectric conversion layer 21 and the second transparent electrode layer 22 and connecting the small pieces 47 adjacent in the vertical direction with the first transparent electrode layer 20. However, the present invention is not limited to this, and the first transparent electrode layer 20, the photoelectric conversion layer 21, and the second transparent electrode layer 22 may be formed separately. Good.

  In the embodiment described above, the amorphous photoelectric conversion unit 26 is provided on the indoor space 51 side, and the crystalline photoelectric conversion unit 25 is provided on the external space 52 side in order to efficiently generate power from the light from the indoor space 51. However, the present invention is not limited to this, and the crystalline photoelectric conversion unit 25 may be provided on the indoor space 51 side, and the amorphous photoelectric conversion unit 26 may be provided on the external space 52 side.

In the above-described embodiment, the crystalline photoelectric conversion unit 25 is formed by three layers of the p-type crystalline silicon based semiconductor layer 30, the i-type crystalline silicon based semiconductor layer 31, and the n-type crystalline silicon based semiconductor layer 32. The present invention is not limited to this, and other layers such as alloy layers may be interposed between the semiconductor layers 30, 31, and 32. Further, it may be formed of two layers, a p-type crystalline silicon based semiconductor layer 30 and an n-type crystalline silicon based semiconductor layer 32.
Similarly, in the above-described embodiment, the amorphous photoelectric conversion unit 26 includes the p-type amorphous silicon-based semiconductor layer 35, the i-type amorphous silicon-based semiconductor layer 36, and the n-type amorphous silicon-based semiconductor layer. However, the present invention is not limited to this, and other layers such as an alloy layer may be interposed between the semiconductor layers 35, 36, and 37. Further, it may be formed of two layers, a p-type amorphous silicon-based semiconductor layer 35 and an n-type amorphous silicon-based semiconductor layer 37.

  In the above-described embodiment, the photoelectric conversion element 12 is obtained by bonding the two photoelectric conversion units 25 and 26. However, the present invention is not limited to this, and only one photoelectric conversion unit is incorporated. Or three or more photoelectric conversion units may be incorporated.

  In the above-described embodiment, the electricity generated by the photoelectric conversion layer 21 is taken out by the first transparent electrode layer 20 and the second transparent electrode layer 22, but the present invention is not limited to this, and each transparent electrode layer Metal thin wires may be formed on the surfaces of 20, 22 and used as auxiliary electrodes.

  In the above-described embodiment, the solar cell module is used as the window, but the present invention is not limited to this. For example, the solar cell module may be used as a part of a handrail on a veranda or a balcony as shown in FIG.

  In the above-described embodiment, a sheet-like member is covered as a sealing member on the photoelectric conversion element 12 to improve sealing performance. However, the present invention is not limited to this, and as shown in FIG. The first translucent insulating substrate 10 and the second translucent insulating substrate 11 may be sealed by bonding with an adhesive 60.

  In the above-described embodiment, the first electrode separation groove 40, the electrode connection groove 41, and the first element separation groove 42 are parallel to the vertical sides 16 and 17, and the second element separation groove 43 is the horizontal sides 18 and 19. However, the present invention is not limited to this, and the first electrode separation groove 40, the electrode connection groove 41, and the first element separation groove 42 are parallel to the lateral sides 18 and 19. The second element isolation groove 43 may be parallel to the vertical sides 16 and 17. In short, the vertical and horizontal positional relationship of the solar cell module 1 may be reversed.

1 Solar cell module (wall forming member)
DESCRIPTION OF SYMBOLS 10 1st translucent insulated substrate 11 2nd translucent insulated substrate 12 Photoelectric conversion element 13 Sealing member 15 Concavity and convexity 20 1st transparent electrode layer 21 Photoelectric conversion layer 22 2nd transparent electrode layer 25 Crystalline photoelectric conversion unit (photoelectric Conversion unit)
26 Amorphous photoelectric conversion unit (photoelectric conversion unit)
41 Electrode connection groove (opening)
42 First element isolation groove (opening)
43 First element isolation groove (opening)
51 Indoor space (internal space)
52 External space

Claims (6)

In a solar cell module comprising a first light-transmissive insulating substrate, a second light-transmissive insulating substrate, and a photoelectric conversion element sandwiched between the first light-transmissive insulating substrate and the second light-transmissive insulating substrate,
The photoelectric conversion element is laminated in the order of the first transparent electrode layer, the photoelectric conversion layer, and the second transparent electrode layer from the first translucent insulating substrate side.
The photoelectric conversion layer is capable of converting light energy into electrical energy when irradiated with light, and transmits a part of the light,
The photoelectric conversion element has an opening from which at least the photoelectric conversion layer is removed when the first light-transmissive insulating substrate is viewed in plan view,
When irradiating light from the first translucent insulating substrate side, the optical path passes through the inside of the opening and reaches the second translucent insulating substrate ,
An element separation groove for dividing the photoelectric conversion element into a plurality of small pieces, an electrode connection groove from which the photoelectric conversion layer is partially removed, and a first electrode separation groove from which the first transparent electrode layer is partially removed. And
The electrode connection groove forms at least a part of the opening,
In the photoelectric conversion element, a part of the second transparent electrode layer of one piece enters the electrode connection groove and contacts the first transparent electrode layer of the other piece, whereby the one piece and the other piece. Are electrically connected in series,
When irradiating light from the first translucent insulating substrate side, the light path passes through the inside of the electrode connection groove and reaches the second translucent insulating substrate,
The second transparent electrode layer is made of a transparent conductive oxide,
The solar cell module, wherein a groove width of the electrode connection groove is 90 μm or more and 120 μm or less wider than a groove width of the first electrode separation groove. Concavities and convexities are formed on the outer principal surface of the first light-transmissive insulating substrate with respect to the photoelectric conversion element,
The outer main surface has an arithmetic average roughness of 0.25 μm or more and 1.25 μm or less, and a 60-degree specular gloss according to JIS Z 8741 is 8% or less,
The photoelectric conversion layer has two photoelectric conversion units having different spectral sensitivities,
The two photoelectric conversion units are a crystalline photoelectric conversion unit including a crystalline silicon layer and an amorphous photoelectric conversion unit including an amorphous silicon layer,
2. The solar cell module according to claim 1, wherein the amorphous photoelectric conversion unit is located on a second light-transmissive insulating substrate side with respect to the crystalline photoelectric conversion unit. Before SL isolation trench is to form at least part of said opening,
The plurality of small pieces are electrically connected in series or in parallel,
2. An optical path that passes through the inside of the element isolation groove when irradiated with light from the first translucent insulating substrate side and reaches the second translucent insulating substrate. 3. The solar cell module according to 1 or 2 .   The opening area of the opening is 20% or less of the area of the first translucent insulating substrate when the first translucent insulating substrate is viewed in plan. The solar cell module according to. Having a film-like sealing member,
The sealing member seals the photoelectric conversion element and has elasticity.
5. The solar cell module according to claim 1, wherein most of the sealing member is disposed between the photoelectric conversion element and the second light-transmissive insulating substrate. Wall surface using a solar cell module comprising a first light-transmissive insulating substrate, a second light-transmissive insulating substrate, and a photoelectric conversion element sandwiched between the first light-transmissive insulating substrate and the second light-transmissive insulating substrate A forming member,
In the wall forming member that forms the outer wall of the building,
The photoelectric conversion element is laminated in the order of the first transparent electrode layer, the photoelectric conversion layer, and the second transparent electrode layer from the first translucent insulating substrate side.
The photoelectric conversion layer is capable of converting light energy into electrical energy when irradiated with light, and transmits a part of the light,
The photoelectric conversion element has an opening from which at least the photoelectric conversion layer is removed when the first light-transmissive insulating substrate is viewed in plan view,
When the solar cell module is irradiated with light from the first light-transmissive insulating substrate side, the solar cell module includes an optical path that passes through the opening and reaches the second light-transmissive insulating substrate.
The solar cell module includes an element separation groove for dividing the photoelectric conversion element into a plurality of small pieces, an electrode connection groove from which the photoelectric conversion layer is partially removed, and a first transparent electrode layer from which the first transparent electrode layer is partially removed. 1 electrode separation groove,
The electrode connection groove forms at least a part of the opening,
In the photoelectric conversion element, a part of the second transparent electrode layer of one piece enters the electrode connection groove and contacts the first transparent electrode layer of the other piece, whereby the one piece and the other piece. Are electrically connected in series,
When the solar cell module is irradiated with light from the first light-transmissive insulating substrate side, the solar cell module has an optical path that passes through the inside of the electrode connection groove and reaches the second light-transmissive insulating substrate;
The solar cell module is arranged to divide the space inside and outside the building,
A second translucent insulating substrate is disposed on the inner space side of the building, and a first translucent insulating substrate is disposed on the outer space side of the building;
The second transparent electrode layer is made of a transparent conductive oxide,
The groove width of the electrode connection groove is wider than the groove width of the first electrode separation groove, and is 90 μm or more and 120 μm or less,
The photoelectric conversion layer has two photoelectric conversion units having different spectral sensitivities,
Among the two photoelectric conversion units, the photoelectric conversion unit whose absorption wavelength peak is close to 550 nm is located on the second translucent insulating substrate side ,
The two photoelectric conversion units are a crystalline photoelectric conversion unit including a crystalline silicon layer and an amorphous photoelectric conversion unit including an amorphous silicon layer,
The amorphous photoelectric conversion unit is located on the second light-transmissive insulating substrate side with respect to the crystalline photoelectric conversion unit .

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