JP2024067607A - Solar cell unit and method for installing the solar cell unit - Google Patents

Abstract

[Problem] To provide a solar cell unit that prevents leakage current and improves power generation efficiency. [Solution] A solar cell unit (1) solves the above problem by comprising a solar cell module (3) formed by bonding and solidifying a solar cell (14), a first tempered glass (12), and a second tempered glass (11) having a ratio of an area that transmits sunlight to an area of the solar cell (14) of 1 or more with a sealant (13), a first connection terminal that connects a first electrode extending from the solar cell (14) to a first current line that inputs a first current output from a first solar cell unit (N-1), and a second connection terminal that connects a second electrode extending from the solar cell (14) to a second current line that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1), and a terminal connection protection member (15) that protects them in an insulating state. [Selected Figure] Figure 2

Description

The present invention relates to a solar cell unit and a method for installing a solar cell unit.

In recent years, interest in renewable energy has increased, and expectations are growing for photovoltaic power generation systems that employ a large number of solar cell modules. Traditionally, solar cell modules have often been installed on roofs or solar cell module stands, but there has been an increase in the installation of solar cell systems on roads. For example, the following technologies are available for installing solar cell modules on roads.

As a first technique, a solar cell unit that is strong enough to be installed on a road and has easy part replacement is disclosed (see, for example, Patent Document 1). In the first technique, the solar cell unit includes a solar cell module, a bottom block, a pair of module fixing blocks, tempered glass, a pair of tempered glass fixing blocks, etc. The bottom block has a plurality of wiring grooves in which conductive bars are housed, recessed at positions corresponding to the positive and negative electrodes exposed on the underside of the solar cell module. The tempered glass covers the upper surface of the solar cell module, is transparent to sunlight, and is formed so that the width of the ground side in the X direction is greater than the width of the top side and includes the width of the upper surface of the solar cell module. The solar cell unit can be disassembled by sequentially disassembling the tempered glass and solar cell module from the top side, or by sliding the solar cell module along the Y direction from the front side.

As a second technology, a technology for installing solar cells on roads is disclosed (for example, Patent Document 2). In the second technology, a flexible solar cell module is disclosed that includes solar cells formed on a flexible substrate and is installed to cover at least a portion of the road surface, which may be flat or curved, in accordance with the shape of the road surface.

A third technology has been disclosed in which solar cells are combined with road or sidewalk blocks to generate electricity using only sunlight or heat (for example, Patent Document 3). In the third technology, the solar cell 1 is enclosed in a case that encases the solar cell and is made of a light-transmitting yet durable material with excellent heat resistance, such as bulletproof glass or bulletproof plastic.

JP 2020-039195 A JP 2013-038228 A Japanese Patent Application Laid-Open No. 09-018041

In Patent Document 1, the aim is to create a solar cell unit that is strong enough to be installed on roads and has easy part replacement, with a three-layer structure consisting of a bottom block, a solar cell module and a pair of fixing blocks on top of that, and tempered glass and a pair of fixing blocks on top of that. These are finely divided to allow for part replacement. The wiring structure is also exposed at the bottom of the solar cell module.

However, in Patent Document 1, because the structure has replaceable parts, the solar cell module and wiring structure are not sealed, which means there is a possibility of moisture entering from the natural environment (rain), posing a reliability risk such as electrical leakage.

In addition, Patent Document 1 employs a structure in which the upper tempered glass of a three-layer structure is fixed from the left and right, which means that the area through which sunlight passes cannot be maximized relative to the installation area, and there is a risk of reduced power generation efficiency.

Therefore, the present invention provides a solar cell unit that prevents leakage current and improves power generation efficiency.

According to one aspect of the present invention, a solar cell unit (1) that is installed alone or in a row on the ground surface, including a road, or in a recess in the ground surface comprises a solar cell module (3) formed by bonding and solidifying a solar cell (14) capable of generating electricity by receiving sunlight, a first tempered glass (12) that supports the solar cell (14) from the back surface of the solar cell (14), and a second tempered glass (11) that protects the solar cell (14) from the top surface of the solar cell (14) and has a ratio of the area that transmits sunlight to the area of the solar cell (14) of 1 or more, with a sealant (13), and the solar cell module (3) is installed on the surface of the first tempered glass (12), and the The solar cell (14) includes a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) that is provided in the front stage of the solar cell unit (N), and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) that is provided in the rear stage of the solar cell unit (N), and a terminal connection protection member (15) that protects them in an insulating state.

The second reinforced glass (11) is characterized by having an area equal to or greater than the area of the solar cell (14).

The terminal connection protection member (15) is characterized in that it outputs the first current input from the first solar cell unit (N-1) via the first connection terminal (31) to the second solar cell unit (N+1) via the second connection terminal (32), and outputs the second current to the second solar cell unit (N+1) via the second connection terminal (32).

The solar cell unit (1) further includes a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1), a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1), and a housing portion (2) in which the terminal connection protection member (15) is installed in a first recess (19) provided at the bottom of the top opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided at the bottom, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided on the side, and the solar cell module (3) is installed at the bottom.

When the solar cell module (3) is viewed from the first tempered glass (12) side or the second tempered glass (11) side, a specified sheet (41) is installed in the sealing material (13) in an area where the solar cell (14) is not present.

The second reinforced glass (11) is characterized in that it has a plurality of protrusions on its surface.

According to one aspect of the present invention, there is provided a solar cell unit (1) that is installed alone or in a row on the ground surface, including a road, or in a recess in the ground surface, and the solar cell module (13) is formed by bonding and solidifying a solar cell (14) capable of receiving sunlight and generating electricity, a first tempered glass (12) that supports the solar cell (14) from the back surface of the solar cell (14), and a second tempered glass (11) that protects the solar cell (14) from the top surface of the solar cell (11) and has a ratio of the area that transmits sunlight to the area of the solar cell (14) of 1 or more with a sealant (13), and the first tempered glass (12) is provided on the solar cell (14) so that the ratio of the area that transmits sunlight to the area of the solar cell (14) is 1 or more. A terminal that is installed on the surface of the solar cell (12) and protects in an insulated state: a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the previous stage of the solar cell unit (N); and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N). a connection protection member (15), a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1), a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1), the terminal connection protection member (15) being installed in a first recess (19) provided in a bottom portion within an upper opening, the first cable portion (21) and the second cable portion (23) being housed in one or more second recesses (18) provided in the bottom portion, The installation method of the solar cell unit (1) includes a housing part (2) having a side surface provided with a plurality of holes (4) for passing the second cable part (23) and a bottom surface on which the solar cell module (3) is installed, and is characterized in that the solar cell unit (N) is installed on the ground surface or in a recess in the ground, the first cable part is pulled out from a first hole of the plurality of holes, and connected to the second cable part of the first solar cell unit (N-1) that has already been installed on the ground surface or in a recess in the ground surface, and the connected first cable part or the connected second cable part is stored in the housing.

According to one aspect of the present invention, it is possible to prevent leakage current and improve power generation efficiency.

1 is a perspective view of a solar cell unit according to an embodiment of the present invention, viewed from above. 2 is a cross-sectional view taken along line AA of FIG. 1. 5A to 5C are diagrams for explaining a method of connecting solar cell units to each other in one embodiment of the present invention. FIG. 2 is an electrical configuration diagram of the solar cell unit in one embodiment of the present invention. FIG. 2 is a diagram illustrating a connection between solar cell units in one embodiment of the present invention. 2 is a cross-sectional view taken along line AA of a solar cell unit in one embodiment (another example) of the present invention. FIG. FIG. 11 is a diagram for explaining application of a black sheet 41 to a solar cell unit 1 in one embodiment (another example) of the present invention.

Figure 1 is a perspective view of a solar cell unit according to one embodiment of the present invention, viewed from above. Solar cell units 1 are installed singly or in multiple rows on the ground, including roads, or in recesses in the ground. Solar cell unit 1 is composed of a housing 2 and a solar cell module 3.

The housing 2 is an aluminum casting produced by casting an aluminum alloy. The solar cell module 3 is composed of multiple solar cells, and is installed on the top surface of the housing 2. The four side surfaces of the housing 2 are provided with holes (wiring holes) 4 for passing a connection cable, which will be described later. In FIG. 1, the connection cable is stored inside the housing 2. The dashed line A-A indicates the cut surface, and the cross-sectional view is shown in FIG. 2.

Figure 2 is a cross-sectional view taken along the line A-A in Figure 1. The solar cell module 3 is formed by bonding and solidifying a reinforced glass (bottom plate) 12, solar cell cells 14 arranged and wired on the bottom plate, and reinforced glass (top plate) 11 on the top plate with a sealant 13. The sealant 13 may be, for example, polyolefin elastomer (POE).

The tempered glass (top plate) 11 protects the solar cell (14) from the upper surface of the solar cell (11). The tempered glass (top plate) 11 covers the entire surface of the solar cell module 3 contained within the frame of the housing 2. In other words, the ratio of the area of the tempered glass (top plate) 11 that transmits sunlight to the area of the solar cell (14) is 1 or more. This makes it possible to make the most of the area of the tempered glass 11 that transmits sunlight relative to the installation area of the solar cell 14, thereby improving power generation efficiency.

The tempered glass (bottom plate) 12 supports the solar cell (14) from the back side of the solar cell (14). The tempered glass (bottom plate) 12 may be colored, but the tempered glass (top plate) 11 is preferably transparent because sunlight must be allowed to fall on the solar cell 14 to increase power generation efficiency.

The top surface of the housing 2 is provided with a module receiving convex surface 17 that can fully receive the reinforced glass (bottom plate) 12 of the solar cell module 3. The reinforced glass (bottom plate) 12 of the solar cell module 3 is fixed to the module receiving convex surface 17 with adhesive 16. A terminal connection box 15 is installed in a recess 19 in the center of the top surface of the housing 2.

The terminal connection box 15 is a box that houses an electrical system for electrically connecting multiple solar cell units 1 in series. The terminal connection box 15 may be made of an insulating material to prevent leakage of electricity from the electrical system. In addition, the electrical system inside the terminal connection box 15 may be treated to prevent corrosion.

As shown in FIG. 3, a connection cable (-) 21 and a connection cable (+) 23 extend from the terminal connection box 15. The terminal connection box 15 has the function of transmitting the power generated by the solar cell unit (own unit) N (N is an integer greater than or equal to 2) to the next (following stage) adjacent unit N+1, and transmitting the power transmitted from the previous (previous stage) adjacent unit N-1 to the next adjacent unit N+1.

As described above, the inside of the solar cell module 3 is sealed with a sealant 13. Electrodes connected to the solar cell 14 extend from the surface of the tempered glass (bottom plate) 12, and the electrodes are connected to connection terminals in a terminal connection box 15. At this time, the connection portion between the electrode and the connection terminal is covered with the terminal connection box 15, and the terminal connection box 15 is adhered to the surface of the tempered glass (bottom plate) 12 with, for example, a silicone polymer. The connection portion between the electrode and the connection terminal is soldered and then covered and hardened with an insulating potting resin. The insulating potting resin may be, for example, liquid silicone rubber, etc.

In addition, in FIG. 2, recesses 18 are provided on the left and right sides of recess 19. The space formed by recess 18 and tempered glass (bottom plate) 12 becomes a space (cable storage space) for storing a connection cable, which will be described later.

The solar cell module 3 is formed by bonding and solidifying tempered glass (bottom plate) 12, solar cell cells 14 arranged and wired on top of that, and tempered glass (top plate) 11 on top of that with a sealant 13, which prevents moisture from entering due to changes in the natural environment such as rain, eliminating the possibility of electrical leakage. Therefore, in terms of resistance to changes in the natural environment, the module can achieve the same reliability as solar cell modules normally installed on the ground or roof.

In addition, by covering the entire top plate with light-transmitting transparent glass (reinforced glass (top plate) 11), the power generation performance of the solar cells 14 can be maximized. Also, by incorporating the reinforced glass 11, 12 into the module, it is possible to obtain a strength that can withstand installation on roads.

Furthermore, the housing 2, which is cast from an aluminum alloy, is rigid and resistant to twisting and warping. By fixing the solar cell module 3 with adhesive 16 to the module receiving convex surface 17, which can fully receive the reinforced glass (bottom plate) 12 of the solar cell module 3, the solar cell unit 1 as a whole is rigid and resistant to twisting and warping, and can absorb a load applied from above without deforming the solar cell module 3.

Figure 3 is a diagram for explaining a method for connecting solar cell units together in one embodiment of the present invention. A connection cable (-) 21 and a connection cable (+) 23 are stored in the housing 2, and the connection cable (-) 21 and the connection cable (+) 23 can be extended from any two of the four wiring holes 4.

Here, for each of the connection cable (-) 21 and the connection cable (+) 23, the end connected to the terminal connection box 15 is referred to as the base end, and the other end is referred to as the tip end. The connection cable (-) 21 has a female connector (-) 22 at its tip. The connection cable (+) 23 has a male connector (+) 24 at its tip.

When laying the solar cell units 1 on a road, multiple solar cell units 1 are electrically connected to each other and arranged in series. As a connection method for this purpose, the connection cable (-) 21 and the connection cable (+) 23 have a connector structure, and after connecting the connection cable 21 (-) and the connection cable 23 (+) between adjacent solar cell units 1, the connection cables 21, 23 can be stored in the cable storage space of the recess 18 in the housing 2. This allows the solar cell units 1 to be laid without any gaps.

The solar cell unit 1 is the same size as a typical pavement block, so by replacing it with an existing pavement block, a solar cell road can be constructed with a short construction period.

In addition, when a solar cell unit 1 breaks down, it can be repaired individually by removing that solar cell unit 1. When removing any one solar cell unit 1 from the multiple solar cell units 1 arranged in parallel, it can be pulled out by the length of the connection cables 21, 23. Therefore, it is preferable that the length of the connection cables 21, 23 is set to a length appropriate for facilitating maintenance and replacement of the solar cell units 1.

In addition, a storage battery is installed near the road where the solar cell unit is installed, and the generated electricity can be charged into the storage battery and used.

Figure 4 is an electrical diagram of a solar cell unit in one embodiment of the present invention. The terminal connection box 15 is electrically connected to a solar cell circuit 35. The solar cell circuit 35 represents the electrical connection relationship of the solar cell cells 14 that make up the solar cell module 3. In the case of Figure 4, the circuit is made up of four solar cell cells 14 connected in series, and two of them are connected in parallel.

In FIG. 4, the solar cell unit 1 includes a terminal connection box 15, a connection cable 21 having a connector (-) 22, a connection cable 23 having a connector (+) 24, a conductor 30, connection terminals 31 and 32, a conductor 33, and a bypass diode 34.

The conductor 30 is electrically connected to the base end of the connection cable 21. The connection terminal 31 is connected to the conductor 30 and is a terminal that is connected to the negative terminal of the solar cell circuit 35. The conductor 33 is electrically connected to the base end of the connection cable 23. The connection terminal 32 is connected to the conductor 33 and is a terminal that is connected to the positive terminal of the solar cell circuit 35.

The bypass diode 34 is connected in parallel with the solar cell circuit 35. When the solar cell circuit 35 is operating normally, no current flows through the bypass diode 34. However, when the solar cell circuit 35 fails, the power supplied from the adjacent solar cell unit is output to the next solar cell unit by bypassing the solar cell circuit 35.

Figure 5 is a diagram explaining the connections between solar cell units in one embodiment of the present invention. In Figure 5, three adjacent solar cell units 1 are referred to as solar cell unit N-1, solar cell unit N, and solar cell unit N+1. The reference numerals indicating each component of solar cell unit N-1 are given the suffix N-1. The reference numerals indicating each component of solar cell unit N are given the suffix N. The reference numerals indicating each component of solar cell unit N+1 are given the suffix N+1.

The connector (-) _22N of the solar cell unit N is connected to the connector (+) 24N-1 of the solar cell unit N _-1 . The connector (+) _24N of the solar cell unit N is connected to the connector (-) 22N _{+1 of the solar cell unit N+1} .

Here, attention is focused on solar cell unit N. When solar cell unit N is operating normally, the current output from solar cell unit N-1 is output to solar cell unit N+1 via the route of connector (-) _22N , connection terminal _31N , solar cell circuit _35N , connection terminal _32N , and connector (+) _24N . At this time, the current generated by solar cell circuit _35N is also output to solar cell unit N+1 via the route of connection terminal _32N and connector (+) _24N .

If the solar cell circuit _35N of the solar cell unit N fails, the current output from the solar cell unit N-1 is output to the solar cell unit N+1 via the connector (-) _22N , the connection terminal _31N , the bypass diode _34N , the connection terminal _32N , and the connector (+) _24N .

Figure 6 is a cross-sectional view of the solar cell unit taken along the line A-A in one embodiment of the present invention (another example). On a pavement where people walk, the glare from the surface of the solar cell unit 1 and the glare of people can be unpleasant. Therefore, as another example, we will explain how to suppress the reflection from the surface of the solar cell unit 1 and the glare of people.

As shown in FIG. 6, a black sheet 41 is inserted between the reinforced glass (top plate) 11 of the solar cell module 3 and the solar cell 14 to hide the metal wiring (not shown), and is then solidified with a sealant 13.

Figure 7 is a diagram for explaining the application of a black sheet 41 to a solar cell unit 1 in one embodiment (another example) of the present invention. Figure 7(A) is a top view of the solar cell unit 1 before the black sheet 41 is applied. Figure 7(B) is a top view of the solar cell unit 1 after the black sheet 41 has been applied.

In FIG. 7(A), transparent tempered glass (bottom plate) 12 is placed on the top surface (module receiving convex surface 17) of the housing 2, on which the solar cell module 3 is placed and covered with transparent tempered glass (top plate) 11. Therefore, in the gap between the inside of the frame of the housing 2 and the solar cell 14 of the solar cell module 3, the metal wiring 51 placed in the layer of the sealing material 13 and the color of the module receiving convex surface 17 are visible.

In FIG. 7(B), the metal wiring 51 is hidden by the black sheet 41 provided between the tempered glass (top panel) 11 and the solar cell 14. The module receiving convex surface 17 is also hidden and cannot be seen. As a result, the surface of the solar cell unit 1 is completely black, eliminating any sense of discomfort and making it user-friendly.

As another example, anti-slip convex portions can be provided by adhering glass particles to the topmost tempered glass (top plate) 11. In this case, the glass material (glass particles) is adhered to the convex portions in a size that does not block sunlight (for example, 1 mm convex portions spaced at equal intervals of 3.5 mm).

According to this embodiment, the solar cell 14 is sealed with the sealing material 13, and the electrodes extending from the solar cell 14 and the electrical connection parts such as the connection terminals 31, 32 that are their connection points are also protected in an insulated state by the terminal connection box 15, so that leakage current can be prevented. In addition, the area of the tempered glass (top plate) 11 that transmits sunlight can be maximized relative to the installation area of the solar cell 14, so power generation efficiency can be improved.

In addition, after connecting the connection cables 21, 23 between adjacent solar cell units 1, the connection cables 21, 23 can be stored in the cable storage space inside the housing 2, thereby making efficient use of the installation space for the solar cell units.

In addition, by placing a black sheet on the top surface of the solar cell unit 1 except for the solar cell cells 14, it is possible to prevent reflections and glare on the surface of the second tempered glass. In addition, glass particles may be adhered to the topmost tempered glass (top plate) 11 to improve the anti-slip effect.

From the above, the solar cell unit (1) in this embodiment has the following features:
A solar cell unit (1) that is installed singly or in a row on a ground surface including a road or in a recess in the ground surface,
a solar cell module (3) formed by bonding and solidifying, with a sealing material (13), a solar cell (14) capable of generating electricity by receiving sunlight, a first tempered glass (12) supporting the solar cell (14) from a back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from an upper surface of the solar cell (14) and having a ratio of an area through which sunlight passes to an area of the solar cell (14) of 1 or more;
a terminal connection protection member (15) that is installed on a surface of the first strengthened glass (12) and protects, in an insulating state, a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the previous stage of the solar cell unit (N) and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N);
Equipped with.

This configuration prevents leakage current and improves power generation efficiency. In other words, the solar cell (14) is sealed with the sealing material (13), and the electrodes extending from the solar cell (14) and their connection points, the first connection terminal (31) and the second connection terminal (32), are also protected in an insulated state by the terminal connection protection member (15), preventing leakage current.

The second reinforced glass (11) has an area equal to or greater than the area of the solar cell (14).

This configuration makes it possible to maximize the area of the second tempered glass (11) that transmits sunlight relative to the installation area of the solar cell (14), thereby improving power generation efficiency.

The terminal connection protection member (15) is
The first current input from the first solar cell unit (N-1) via the first connection terminal (31) is output to the second solar cell unit (N+1) via the second connection terminal (32), and the second current is output to the second solar cell unit (N+1) via the second connection terminal (32).

By configuring it in this way, it is possible to transmit current from the first solar cell unit (N-1) to the second solar cell unit (N+1), and it is also possible to transmit current generated by the solar cell (14) to the second solar cell unit (N+1).

The solar cell unit (1) further comprises:
a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1);
a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1);
a housing section (2) in which the terminal connection protection member (15) is installed in a first recess (19) provided in a bottom portion within an upper surface opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom portion, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided in a side surface, and the solar cell module (3) is installed in the bottom portion;
Equipped with.

By configuring it in this way, the first solar cell unit (N-1), the solar cell unit (N), the second solar cell unit (N+1), etc. can be connected in series, and the connected cable section can be stored inside the housing.

When the solar cell module (3) is viewed from the first tempered glass (12) side or the second tempered glass (11) side, a specified sheet (41) is placed in the sealing material (13) in an area where there are no solar cell cells (14).

This configuration helps prevent glare and reflection on the surface of the second tempered glass.

The surface of the second reinforced glass (11) has multiple protrusions.

This configuration improves the anti-slip effect.

The installation method of the solar cell unit (1) in this embodiment is as follows:
A solar cell unit (1) that is installed singly or in a row on a ground surface including a road or in a recess in the ground surface,
a solar cell module (13) formed by bonding and solidifying, with a sealing material (13), a solar cell (14) capable of generating electricity by receiving sunlight, a first tempered glass (12) supporting the solar cell (14) from a back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from an upper surface of the solar cell (11) and having a ratio of an area through which sunlight passes to an area of the solar cell (14) of 1 or more;
a terminal connection protection member (15) that is installed on a surface of the first strengthened glass (12) and protects, in an insulating state, a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the previous stage of the solar cell unit (N) and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N);
a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1);
a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1);
a housing section (2) in which the terminal connection protection member (15) is installed in a first recess (19) provided in a bottom portion within an upper surface opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom portion, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided on a side surface, and the solar cell module (3) is installed on the bottom portion;
A method for installing the solar cell unit (1), comprising:
The solar cell unit (N) is installed on the ground surface or in a recessed portion of the ground surface;
The first cable portion is pulled out from a first hole among the plurality of holes and connected to a second cable portion of the first solar cell unit (N-1) that has already been installed on the ground surface or in a recessed portion of the ground surface;
The connected first cable portion or the connected second cable portion is housed within the housing.

By configuring it in this way, the first solar cell unit (N-1), the solar cell unit (N), the second solar cell unit (N+1), etc. can be connected in series and installed on a road or the like, and the connected cable section can be stored inside the housing.

Although this aspect has been described above based on the embodiment and modified examples, the embodiment of the above-mentioned aspect is intended to facilitate understanding of this aspect and does not limit this aspect. This aspect may be modified or improved without departing from the spirit and scope of the claims, and equivalents are included in this aspect. Furthermore, if a technical feature is not described as essential in this specification, it may be deleted as appropriate.

1 Solar cell unit 2 Housing 3 Solar cell module 4 Wiring hole 11 Reinforced glass (top plate)
12 Tempered glass (bottom plate)
REFERENCE SIGNS LIST 13 Sealant 14 Solar cell 15 Terminal connection box 16 Adhesive 17 Module receiving convex surface 18 Concave 19 Concave 21, 23 Connection cable 22, 24 Connector 30 Conductor 31, 32 Connection terminal 33 Conductor 34 Bypass diode 35 Solar cell circuit 41 Black sheet 51 Metal wiring

According to one aspect of the present invention, a solar cell unit (1) that is installed alone or in a plurality of rows on the ground surface including a road or in a recess in the ground surface comprises a solar cell module (3) formed by bonding and solidifying, with a sealant (13), a solar cell (14) capable of receiving sunlight and generating electricity, a first tempered glass (12) supporting the solar cell (14) from the back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from the top surface of the solar cell (14) and having a ratio of an area that transmits sunlight to an area of the solar cell (14) of 1 or more, and the first tempered glass (12) supporting the solar cell (14) from the back surface of the solar cell (14). A first connection terminal (31) is provided on the surface of the reinforced glass (12) and connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the previous stage of the solar cell unit (N), and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N). a terminal connection protection member (15) that electrically insulates and protects the first solar cell unit (N-1) from the outside; a first cable portion (21) that extends from the first current line (30) and draws in the first current input from the first solar cell unit (N-1); a second cable portion (23) that extends from the second current line (33) and outputs the first current and the second current to the second solar cell unit (N+1); the terminal connection protection member (15) is installed in a first recess (19) provided in a bottom portion within an upper opening, and the first cable portion (21) is installed in one or more second recesses (18) provided in the bottom portion. and the second cable portion (23) are housed therein, a plurality of holes (4) are provided on the side surface for passing the first cable portion (21) and the second cable portion (23), and the solar cell module (3) is installed on the bottom surface, wherein the first connection terminal (31) and the second connection terminal (32) are each covered with an insulating resin and then covered with the terminal connection protection member (15), the housing portion (2) is made of an aluminum casting cast from an aluminum alloy, and the solar cell module (3) is fixed to the bottom surface with an adhesive (16) .

The plurality of holes (4) are four holes, each of which is provided on each side of the housing portion (2), and the first cable portion (21) and the second cable portion (23) are extended from any two of the four holes .

According to one aspect of the present invention, there is provided a solar cell unit (1) that is installed alone or in a plurality of rows on the ground surface including a road or in a recess in the ground surface, the solar cell module (13) being formed by bonding and solidifying a solar cell (14) capable of receiving sunlight and generating electricity, a first tempered glass (12) supporting the solar cell (14) from a back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from an upper surface of the solar cell (11) and having a ratio of an area that transmits sunlight to an area of the solar cell (14) of 1 or more with a sealant (13), and a first connection terminal that is installed on a surface of the first tempered glass (12) and connects a first electrode that is one of electrodes extending from the solar cell (14) to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in a stage preceding the solar cell unit (N). a second connection terminal (32) connecting a second electrode, which is the other electrode extending from the solar cell (14), and a second current line (33) for outputting a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the rear stage of the solar cell unit (N); a terminal connection protection member (15) for protecting the above-mentioned components in an electrically insulated state from the outside ; a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1); a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1); a housing part (2) in which a first cable part (21) and a second cable part (23) are stored, a side surface of which is provided with a plurality of holes (4) for passing the first cable part (21) and the second cable part (23), and the solar cell module (3) is installed at the bottom thereof; a first cable part (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1); a second cable part (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1); and a housing portion (2) having a plurality of holes (4) on a side surface thereof and having the solar cell module (3) installed on the bottom surface thereof , the first connection terminal (31) and the second connection terminal (32) are each covered with an insulating resin and then covered with the terminal connection protection member (15), the housing portion (2) is made of an aluminum casting cast from an aluminum alloy, and the solar cell module (3) is fixed to the bottom surface with an adhesive (16). A method for installing the solar cell unit (1) includes installing the solar cell unit (N) on the ground surface or in a recessed portion on the ground, pulling out the first cable portion from a first hole of the plurality of holes and connecting it to the second cable portion of the first solar cell unit (N-1) that has already been installed on the ground surface or in the recessed portion on the ground, and storing the connected first cable portion or the connected second cable portion in the housing .

According to one aspect of the present invention, a solar cell unit (1) that is installed alone or in a plurality of rows on the ground surface including a road or in a recess in the ground surface includes a solar cell module (3) formed by bonding and solidifying a solar cell (14) capable of receiving sunlight and generating electricity, a first tempered glass (12) that supports the solar cell (14) from the back surface of the solar cell (14), and a second tempered glass (11) that protects the solar cell (14) from the top surface of the solar cell (14) and has a ratio of an area that transmits sunlight to an area of the solar cell (14) of 1 or more with a sealant (13), and a solar cell module (3) that is installed on a surface of the first tempered glass (12) and generates electricity from the solar cell (14). a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the preceding stage of the solar cell unit (N), and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N); a first cable portion (21) that draws in the first current input from the unit (N-1); a second cable portion (23) that extends from the second current line (33) and outputs the first current and the second current to the second solar cell unit (N+1); the terminal connection protection member (15) is installed in a first recess (19) provided in a bottom portion within an upper opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom portion, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided on a side surface, and the solar cell module (3) is installed on the bottom portion. the first connection terminal (31) and the second connection terminal (32) are each covered with an insulating resin and then covered with the terminal connection protection member (15); the housing portion (2) is made of an aluminum casting cast from an aluminum alloy; the solar cell module (3) is fixed with an adhesive (16) to a module receiving convex surface (17) provided at the bottom of the top opening ; the multiple holes (4) are four holes, each provided on one side of the housing portion (2), and the first cable portion (21) and the second cable portion (23) are extended from any two of the four holes.

According to one aspect of the present invention, there is provided a solar cell unit (1) which is installed singly or in a plurality of rows on a ground surface including a road or in a recess in the ground surface, the solar cell module (13) being formed by bonding and solidifying a solar cell (14) capable of receiving sunlight and generating electricity, a first tempered glass (12) supporting the solar cell (14) from a back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from an upper surface of the solar cell (11) and having a ratio of an area transmitting the sunlight to an area of the solar cell (14) of 1 or more with a sealant (13), and a first electrode which is one of electrodes extending from the solar cell (14) and is installed on a surface of the first tempered glass (12), and a first electrode which is one of electrodes extending from the solar cell (14), and a first tempered glass (12) provided in front of the solar cell unit (N). a terminal connection protection member (15) that protects in an electrically insulated state from the outside a first connection terminal (31) that connects a first current line (30) that inputs a first current output from a solar cell unit (N-1), a second connection terminal (32) that connects a second electrode that is the other electrode extending from the solar cell (14) and a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) that is provided in the rear stage of the solar cell unit (N), a terminal connection protection member (15) that protects the above-mentioned terminals in an electrically insulated state from the outside, a first cable portion (21) that extends from the first current line (30) and draws in the first current input from the first solar cell unit (N-1), and a second cable portion (21) that extends from the second current line (33) and transmits the first current and the second current to the second solar cell unit (N+1). the solar cell module (3) is provided at the bottom of the top opening, the terminal connection protection member (15) is installed in a first recess (19) provided in the bottom of the top opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided on a side surface, and a housing portion (2) in which the solar cell module (3) is installed at the bottom, the first connection terminal (31) and the second connection terminal (32) are each covered with an insulating resin and then covered with the terminal connection protection member (15), the housing portion (2) is made of an aluminum casting cast from an aluminum alloy , and the module provided at the bottom of the top opening is provided at the bottom of the top opening, the terminal connection protection member (15) is installed in a first recess (19) provided in the bottom of the top opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided on a side surface , and the solar cell module (3) is installed at the bottom, The solar cell module (3) is fixed to a convex cable receiving surface (17) of the solar cell unit (1) with an adhesive (16) , the plurality of holes (4) are four holes, each of which is provided on each side of the housing portion (2), and the first cable portion (21) and the second cable portion (23) are extended from any two of the four holes, characterized in that the solar cell unit (N) is installed on the ground surface or in a recessed portion of the ground, the first cable portion is pulled out from a first hole of the four holes and connected to the second cable portion of the first solar cell unit (N-1) that has already been installed on the ground surface or in a recessed portion of the ground, and the connected first cable portion or the connected second cable portion is stored in the housing.

Claims (7)

A solar cell unit (1) that is installed singly or in a row on a ground surface including a road or in a recess in the ground surface,
a solar cell module (3) formed by bonding and solidifying, with a sealant (13), a solar cell (14) capable of generating electricity upon receiving sunlight, a first tempered glass (12) supporting the solar cell (14) from a back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from an upper surface of the solar cell (14) and having a ratio of an area through which sunlight passes to an area of the solar cell (14) of 1 or more;
a terminal connection protection member (15) that is installed on a surface of the first strengthened glass (12) and protects in an insulating state: a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the previous stage of the solar cell unit (N); and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N);
A solar cell unit (1) comprising: The solar cell unit (1) according to claim 1, wherein the second tempered glass (11) has an area equal to or greater than an area of the solar cell (14). The terminal connection protection member (15) is
The solar cell unit (1) according to claim 1, characterized in that the first current input from the first solar cell unit (N-1) via the first connection terminal (31) is output to the second solar cell unit (N+1) via the second connection terminal (32), and the second current is output to the second solar cell unit (N+1) via the second connection terminal (32). The solar cell unit (1) further comprises:
a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1);
a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1);
a housing section (2) in which the terminal connection protection member (15) is installed in a first recess (19) provided in a bottom portion within an upper surface opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom portion, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided in a side surface, and the solar cell module (3) is installed in the bottom portion;
2. The solar cell unit (1) according to claim 1, characterized in that it comprises: 2. The solar cell unit (1) according to claim 1, characterized in that, when the solar cell module (3) is viewed from the first tempered glass (12) side or the second tempered glass (11) side, a predetermined sheet (41) is installed in an area of the sealing material (13) where there are no solar cells (14). The solar cell unit according to any one of claims 1 to 5, characterized in that a plurality of protrusions are provided on a surface of the second strengthened glass (11). A solar cell unit (1) that is installed singly or in a row on a ground surface including a road or in a recess in the ground surface,
a solar cell module (13) formed by bonding and solidifying, with a sealing material (13), a solar cell (14) capable of generating electricity by receiving sunlight, a first tempered glass (12) supporting the solar cell (14) from a back surface of the solar cell (14), and a second tempered glass (11) protecting the solar cell (14) from an upper surface of the solar cell (11) and having a ratio of an area through which sunlight passes to an area of the solar cell (14) of 1 or more;
a terminal connection protection member (15) that is installed on a surface of the first strengthened glass (12) and protects in an insulating state: a first connection terminal (31) that connects a first electrode, which is one of the electrodes extending from the solar cell (14), to a first current line (30) that inputs a first current output from a first solar cell unit (N-1) provided in the previous stage of the solar cell unit (N); and a second connection terminal (32) that connects a second electrode, which is the other electrode extending from the solar cell (14), to a second current line (33) that outputs a second current generated by the solar cell module (3) to a second solar cell unit (N+1) provided in the subsequent stage of the solar cell unit (N);
a first cable portion (21) extending from the first current line (30) and drawing in the first current input from the first solar cell unit (N-1);
a second cable portion (23) extending from the second current line (33) and outputting the first current and the second current to the second solar cell unit (N+1);
a housing section (2) in which the terminal connection protection member (15) is installed in a first recess (19) provided in a bottom portion within an upper surface opening, the first cable portion (21) and the second cable portion (23) are stored in one or more second recesses (18) provided in the bottom portion, a plurality of holes (4) for passing the first cable portion (21) and the second cable portion (23) are provided on a side surface, and the solar cell module (3) is installed on the bottom portion;
A method for installing the solar cell unit (1), comprising:
The solar cell unit (N) is installed on the ground surface or in a recessed portion of the ground surface;
The first cable portion is pulled out from a first hole among the plurality of holes and connected to a second cable portion of the first solar cell unit (N-1) that has already been installed on the ground surface or in a recessed portion of the ground surface;
A method for installing a solar cell unit, comprising: storing the connected first cable part or the connected second cable part in the housing.