KR20240030996A - Juntion box and solar power system including the same - Google Patents

Abstract

The junction box and the solar power generation system including the same according to the present invention are electrically connected to a first inverter and a first solar cell module to which direct current power generated from the first solar cell module is supplied, and are electrically connected to the first solar cell module. A first junction box provided with a first diode circuit for transferring the generated direct current power to the first inverter, a second inverter to which direct current power generated from a second solar cell module having different specifications from the first solar cell module is supplied, and a second junction box electrically connected to the second solar cell module and provided with a second diode circuit for transmitting direct current power generated by the second solar cell module to the second inverter. The first junction box includes, A first connecting conductor connecting the first solar cell module and the first diode circuit, a first passing conductor having an input terminal and an output terminal and not connected to the first diode circuit but connecting the input terminal and the output terminal are provided, and a second junction is provided. In the box, a second connecting conductor connecting the second solar cell module and the second diode circuit, and a second passing conductor having an input terminal and an output terminal and not connected to the second diode circuit, but connecting the input terminal and the output terminal to each other are provided, The first connection conductor is connected to the second through conductor, and the second connection conductor is connected to the first through conductor.

Description

Junction box and solar power generation system including the same {JUNTION BOX AND SOLAR POWER SYSTEM INCLUDING THE SAME}

The present invention relates to a junction box and a solar power generation system including the same. More specifically, the present invention relates to a solar power generation system that is compact by connecting a plurality of solar cell modules with different specifications to one junction box. This relates to a configurable junction box and a solar power generation system including the same.

Recently, as the depletion of existing energy resources such as oil or coal is predicted, many alternative energies are being developed.

Among them, solar power generation is a technology that directly converts infinite, pollution-free solar energy into electrical energy. When sunlight is irradiated on a solar cell composed of a semiconductor pn junction, the photovoltaic effect is generated. Electromotive force is generated and current flows to an externally connected load.

Meanwhile, such solar power generation has a solar cell module (10; Photo Voltaic; PV) in which solar cells are connected to obtain appropriate electromotive force.

Referring to Figure 1, a conventional solar cell module 10 includes a back-sheet (16), an encapsulant (14), solar cells (15), an encapsulant (14), and glass ( 12; Glass) can be formed by combining in that order. A junction box (18) is mounted on the back sheet (16). At this time, the solar cell module 10 is finished by combining the fixing frame 11.

The junction box 18 mounted on the back sheet 16 is connected to the solar cell module 10 to protect the solar cell module 10, and transmits direct current power produced by the solar cell module 10 to an external line or inverter. It is a device for delivering up to (20). The inverter 20 is a device for converting direct current power into alternating current power.

The junction box 18 may be composed of an enclosure with an internal space, a cable, and a connector, and a diode circuit 18a may be formed inside the enclosure.

The diode circuit 18a of the junction box 18 can form an alternative path for the power generated through the solar cell module to flow even if a shaded area is generated in the solar cell module 10 due to the external environment. It can be configured as in (a) of 2.

In the case of a general solar cell module 10, solar cell modules 10 of the same specification (type) are connected in series or parallel, and the solar cell module 10 is connected to the inverter 20 to convert light energy into direct current. Converts electricity into alternating current. At this time, there is no need to use the general solar cell module 10 separately from the inverter 20 and the circuit.

Referring to (b) of FIG. 2, the junction box 18 is electrically connected through a string 15a and a bus bar 19, which are the minimum series group connected in series with the solar cell 15. .

Referring to FIG. 3, in a general solar power generation system 1, one end of the junction box 18 connected to the solar cell 15 is connected to the positive terminal (+) of the inverter 20, and the junction box 18 The other end of is connected to the negative terminal (-) of the inverter (20). At this time, the conductor connected to the negative terminal of the inverter 20 is called a 'return conductor'.

In the case of this general solar power generation system 1, the arrangement of the solar cell module 10 including the junction box 18 is simple, and the junction box 18 connected to the solar cell module 10 is exposed, so the return conductor There is no major difficulty in installing it.

However, in the case of a solar power generation system including a building-integrated solar cell module (BIPV), the arrangement of the solar cell modules inevitably becomes complicated because the building-integrated solar cell modules form the windows, walls, and exterior materials of the building. Moreover, since the return conductor connecting the junction box and the negative terminal of the inverter is located between the exterior wall of the building and the solar cell module, the return conductor must be buried in the building in advance, which has the disadvantage of making the construction of the solar power generation system difficult and complicated. .

In addition, referring to FIG. 4, there is a construction standard for the current building-integrated solar power generation system that requires that only solar cell modules with the same simplified current value (Isc value), which is the current value when the voltage is 0, be connected to each other. Accordingly, since solar cell modules of different sizes or colors cannot be connected to each other, separate wiring is installed for each solar cell module with different specifications to connect each solar cell module and the corresponding inverter.

However, due to the characteristics of building-integrated solar cell modules that emphasize diversity of colors depending on the shape of the building or the size and design of the exterior wall materials, it is difficult to create a variety of designs due to difficulties in wiring connections. If various designs are required, not only does the construction cost increase, but the difficulty of construction also increases.

In addition, since the inverter 20 must be connected to the public electric distribution network and the distribution boards of buildings and houses, there is a problem in that wiring connections for each specification of the building-integrated solar cell module become more difficult and complicated.

Accordingly, a separate device is required to connect solar cell modules with different specifications through the same line, which has the disadvantage of significantly increasing construction costs.

Korean Patent Publication No. 10-1452448 (Name: Junction box for solar power generation system with arbitrary modification prevention structure, Publication date: 2010.01.29.)

The purpose of the present invention is to provide a junction box that can form a solar power generation system by connecting solar cell modules with different specifications through a single junction box, and a solar power generation system including the same.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The above object is, according to an embodiment of the present invention, a first inverter to which direct current power generated from the first solar cell module is supplied, is electrically connected to the first solar cell module, and supplies direct current power generated from the first solar cell module. A first junction box provided with a first diode circuit for transferring direct current power to the first inverter, a second inverter to which direct current power generated from a second solar cell module having different specifications from the first solar cell module is supplied, and a second inverter. 2 It is electrically connected to the solar cell module and includes a second junction box provided with a second diode circuit for transferring direct current power generated by the second solar cell module to the second inverter, and the first junction box includes a first A first connecting conductor connecting the solar cell module and the first diode circuit, a first passing conductor having an input terminal and an output terminal and not connected to the first diode circuit but connecting the input terminal and the output terminal are provided, and a second junction box is provided. , a second connecting conductor connecting the second solar cell module and the second diode circuit, and a second passing conductor having an input terminal and an output terminal and not connected to the second diode circuit but connecting the input terminal and the output terminal to each other, wherein the first passing conductor is provided. This can be achieved by a solar power generation system in which the connecting conductor is connected to a second passing conductor, and the second connecting conductor is connected to the first passing conductor.

When the second junction box is located on one side of the first junction box and the first inverter and the second inverter are located on the other side of the first junction box, the first connection wire of the first junction box is connected to the first inverter , the second connection conductor of the second junction box may be arranged to be connected to the second inverter via the first through conductor of the first junction box.

A 1-1 through conductor and a 1-2 through conductor are provided in the first junction box, and a 2-1 through conductor and a 1-2 through conductor connected to the 1-1 through conductor are provided in the second junction box. A 2-2 through conductor is provided to be connected, and one end of the second connection conductor of the second junction box is connected to the positive terminal of the second inverter via the second through conductor of the first junction box, and the second junction box is connected to the positive terminal of the second inverter. The other end of the second connection conductor may be connected to the negative terminal of the second inverter via the 2-2 through conductor and the 1-2 through conductor in that order.

When the first junction box is located on one side of the second junction box and the first inverter and the second inverter are located on the other side of the second junction box, the second connection wire of the second junction box is connected to the second inverter. , the first connection conductor of the first junction box may be connected to the first inverter via the second through conductor of the second junction box.

A 1-1 through conductor and a 1-2 through conductor are provided in the first junction box, and a 2-1 through conductor and a 1-2 through conductor connected to the 1-1 through conductor are provided in the second junction box. A 2-2 through conductor is provided to be connected, and one end of the first connection conductor of the first junction box is connected to the positive terminal of the first inverter via the second through conductor of the second junction box, and the first junction box is connected to the positive terminal of the first inverter. The other end of the first connecting conductor may be connected to the negative terminal of the first inverter via the 1-1 through conductor and the 2-1 through conductor in that order.

Meanwhile, the above object is, according to the present invention, in a junction box where a first solar cell module and a second solar cell module with specifications different from the first solar cell module are connected, an enclosure having an internal space, and an interior of the enclosure. provided, a diode circuit connected to the first inverter corresponding to the first solar cell module, a connection wire electrically connected to the diode circuit and the first solar cell module, provided inside the enclosure, and spaced apart from the connection wire. This can be achieved by a junction box for a solar power generation system, which has an input terminal and an output terminal and includes a passing conductor that is not connected to the diode circuit but the input terminal and the output terminal are connected to each other.

The through conductor connects the second solar cell module and the second inverter corresponding to the second solar cell module, and the second solar cell module may be connected to the second inverter via the through conductor.

One or more return conductors are provided in the enclosure, one end of the connection conductor may be connected to the positive terminal of the first inverter, and the other end of the connection conductor may be connected to the negative terminal of the first inverter via the return conductor.

At least one of the connecting conductors, passing conductors, and return conductors may be a waterproof connector.

A closing cap may be installed on at least one of the connecting conductors, passing conductors, and return conductors.

A junction box related to an embodiment of the present invention and a solar power generation system including the same are solar cell modules having different specifications in one junction box where other passing conductors used as connection conductors, passing conductors, and return conductors are provided. can be connected, allowing a solar power generation system to be implemented compactly. Accordingly, the convenience of construction and use of the solar power generation system can be greatly improved, and there is an advantage in that construction costs and maintenance/repair costs can be significantly reduced.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

Figure 1 is a diagram for explaining the structure of a general solar cell module.
FIG. 2 is a diagram showing a state in which the solar cell module and junction box shown in FIG. 1 are connected.
Figure 3 is a diagram showing the configuration of a conventional solar power generation system with a return conductor.
Figure 4 is a diagram showing the configuration of a conventional solar power generation system including solar cell modules with different specifications.
Figure 5 is a configuration diagram of a solar power generation system according to an embodiment of the present invention.
Figure 6 is a diagram showing a first junction box according to an embodiment of the present invention.
Figure 7 is a diagram showing a second junction box according to an embodiment of the present invention.
FIG. 8 is a diagram schematically showing a solar power generation system including the first and second junction boxes shown in FIGS. 6 and 7.
FIG. 9 is a diagram showing the shape of a connector and a finishing cap mounted on a plurality of conductors shown in FIGS. 6 and 7.
Figure 10 is a diagram showing a third junction box according to an embodiment of the present invention.
FIG. 11 is a diagram schematically showing a solar power generation system including the first, second, and third junction boxes shown in FIGS. 6, 7, and 10.

Hereinafter, the junction boxes 111, 121, and 131 and the solar power generation system 100 including the same according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

In addition, regardless of the drawing numbers, identical or corresponding components are given the same or similar reference numbers and duplicate descriptions thereof are omitted. For convenience of explanation, the size and shape of each component shown are exaggerated or reduced. It can be.

The solar power generation system 100 according to an embodiment of the present invention is electrically connected to the first inverter 119, which supplies direct current power generated by the first solar cell module 110, and the first solar cell module 110. A first junction box 111 connected and provided with a first diode circuit 113 for transferring direct current power generated from the first solar cell module 110 to the first inverter 119, a first solar cell module ( A second inverter 121 supplied with direct current power generated from the second solar cell module 120 having specifications different from those of 110), and electrically connected to the second solar cell module 120, the second solar cell module It may include a second junction box 121 provided with a second diode circuit 123 for transferring the direct current power generated in 120 to the second inverter 129.

The first solar cell module 110 and the second solar cell module 120 are modules with different specifications. In particular, the first solar cell module 110 and the second solar cell module 120 may have different simplified current values (Isc), which mean the current value when the voltage is 0.

In the following, for convenience of explanation, the direct current power generated by the first solar cell module 110 is referred to as first direct current power, and the direct current power generated by the second solar cell module 120 is referred to as second direct current power.

The first direct current power generated by the first solar cell module 110 may be supplied to the first inverter 119 through the first junction box 111.

Here, the first inverter 119 may be an inverter with specifications corresponding to the first solar cell module 110.

The second direct current power generated by the second solar cell module 120 may be supplied to the second inverter 129 through the second junction box 121.

Here, the second inverter 129 may be an inverter with specifications corresponding to the second solar cell module 120.

Meanwhile, the first solar cell module 110 and the second solar cell module 120 may be connected to the first junction box 111. Additionally, the first solar cell module 110 and the second solar cell module 120 may be connected to the second junction box 121.

Accordingly, the first direct current power generated by the first solar cell module 110 may be supplied to the first inverter 119 through the first junction box 111 and the second junction box 121. Additionally, the second direct current power generated by the second solar cell module 120 may be supplied to the second inverter 129 through the first junction box 111 and the second junction box 121.

The first junction box 111 may include a first enclosure 112, a first connecting conductor 114, and a first passing conductor 116 provided inside the first enclosure 112. The second junction box 121 may include a second enclosure 122, a second passing conductor 124, and a second connecting conductor 125 provided inside the second enclosure 122.

Additionally, a first diode circuit 113 may be provided in the first enclosure 112 of the first junction box 111. A second diode circuit 123 may be provided in the second enclosure 122 of the second junction box 121.

The first diode circuit 113 is for transmitting the first direct current power generated by the first solar cell module 110 to the first inverter 119, and forms the first junction together with the first solar cell module 110. It is connected to the first connection wire 114 of the box 111. The first passing conductor 116 of the first junction box 111 has an input terminal (116a) and an output terminal (116b), and in a state that is not connected to the first diode circuit 113, the input terminal (1116a) and the output terminal (116b) connected to each other

The second diode circuit 123 is for transmitting the second direct current power generated by the second solar cell module 120 to the second inverter 129, and is used together with the second solar cell module 120 to form a second junction. It is connected to the second connection wire 125 of the box 121. The second passing conductor 124 of the second junction box 121 has an input terminal (124a) and an output terminal (124b), and in a state that is not connected to the second diode circuit 123, the input terminal (124a) and the output terminal (124b) are connected to each other

Here, the first connection conductor 114 and the second connection conductor 125 each have input terminals 114a and 125a and output terminals 114b and 125b, like the first passage conductor 116 and the second passage conductor 124. It can be provided.

The input terminal 114a and the output terminal 114b of the first connection wire 114 connected to the first diode circuit 113 are not connected to each other. At this time, the first connecting conductor 114 is formed with a cut section 115 in which the input terminal 114a and the output terminal 114b are not connected to each other.

Additionally, the input terminal 125a and the output terminal 125b of the second connection wire 125 connected to the second diode circuit 123 are not connected to each other. At this time, the second connecting conductor 125 is formed with a cut section 126 in which the input terminal 125a and the output terminal 125b are not connected to each other.

Meanwhile, the first connection conductor 114 of the first junction box 111 is connected to the second through conductor 124 of the second junction box 121, and the second connection conductor of the second junction box 121 ( 125) may be connected to the first passing conductor 116 of the first junction box 111.

According to the arrangement of the first junction box 111, the second junction box 121, the first inverter 119, and the second inverter 129, the first connection wire 114, the second connection wire 125, and the second connection wire 114 are formed. 1 The connection between the first inverter 119 and the second inverter 129 and the first junction box 111 and the second junction box 121 can be changed through the through conductor 116 and the second through conductor 124. there is.

For example, as shown in FIG. 8, the second junction box 121 is located on one side of the first junction box 111, and the first inverter 119 and the second inverter are located on the other side of the first junction box 111. When the inverter 129 is located, the first connection wire 114 of the first junction box 111 is connected to the first inverter 119, and the second connection wire 125 of the second junction box 121 Can be connected to the second inverter 129 via the first passing conductor 116 of the first junction box 111.

As another example, although not shown in the drawings, the first junction box 111 is located on one side of the second junction box 121, and the first inverter 119 and the second inverter are located on the other side of the second junction box 121. When (129) is located, the second connection wire 125 of the second junction box 121 is connected to the second inverter 129, and the first connection wire 114 of the first junction box 111 is connected to the second inverter 129. It can be connected to the first inverter 119 via the second passing conductor 124 of the second junction box 121.

The output terminal 114b of the first connection wire 114 is connected to the positive terminal (+) of the first inverter 119, and the input terminal 114a of the first connection wire 114 is the negative terminal of the first inverter 119. It can be connected to terminal (-). The output terminal 116b of the first through conductor 116 is connected to the positive terminal (+) of the second inverter 129, and the input terminal 116a of the first through conductor 116 is the negative terminal of the second inverter 129. It can be connected to terminal (-).

In addition, the output terminal (125b) of the second connection conductor 125 is connected to the positive terminal (+) of the second inverter 129 via the first passing conductor 116, and the input terminal of the second connection conductor 125 (125a) may be connected to the negative terminal (-) of the second inverter 129 via the first passing conductor 116.

As described above, the first junction box 111 may be used as a passage to connect the second junction box 121 of the second solar cell module 120 and the second inverter 129. Additionally, the second junction box 121 may be used as a passage to connect the first junction box 111 of the first solar cell module 110 and the first inverter 119.

Meanwhile, a 1-1 passing conductor 117 and a 1-2 passing conductor 118 may be provided inside the first enclosure 112 of the first junction box 111.

In addition, inside the second enclosure 122 of the second junction box 121, there is a 2-1 through conductor 127 connected to the 1-1 through conductor 117, and a 1-2 through conductor 118. ) A 2-2 passing conductor 128 connected to ) may be provided.

At this time, the 1-1 through conductor 117 and the 1-2 through conductor 118 are provided to be spaced apart from the first connection conductor 114 and the first through conductor 116, respectively, and the 2-1 through conductor (127) and the 2-2 second through conductor 128 may be provided to be spaced apart from the second connection conductor 125 and the second through conductor 124, respectively.

The 1-1st through conductor 117, the 1-2nd through conductor 118, the 2-1st through conductor 127, and the 2-2 through conductor 128 are each connected to input terminals 117a, 118a, 127a, 128a) and output terminals (117b, 118b, 127b, 128b).

For example, as shown in FIG. 8, the second junction box 121 is located on one side of the first junction box 111, and the first inverter 119 and the second inverter are located on the other side of the first junction box 111. When the inverter 129 is located, one end of the second connection conductor 125 of the second junction box 121 is connected to the second inverter 129 via the first through conductor 116 of the first junction box 111. ) is connected to the positive terminal (+), and the other end of the second connecting conductor 125 is sequentially connected to the second inverter 129 via the 2-2 through conductor 128 and the 1-2 through conductor 118. It can be connected to the negative terminal (-) of

As another example, although not shown in the drawings, the first junction box 111 is located on one side of the second junction box 121, and the first inverter 119 and the second inverter are located on the other side of the second junction box 121. When (129) is located, one end of the first connecting conductor 114 of the first junction box 111 is connected to the positive terminal (+) of the first inverter 119 via the second passing conductor 124. The other end of the first connecting conductor 114 can be connected to the negative terminal (-) of the first inverter 119 via the 1-1 passing conductor 117 and the 2-1 passing conductor 127 in that order. there is.

The 1-1st passing conductor 117, the 1-2nd passing conductor 118, the 2-1st passing conductor 127, and the 2-2nd passing conductor 128 are connected to the first and second inverters 129, respectively. It can be used as a return wire to connect to the negative terminal (-) of

As described above, the first and second connecting conductors (114, 125), the first and second passing conductors (116, 124), and other 1-1, 1-2, 2-1, and 2nd conductors used as return conductors. -2 Solar cell modules 110 and 120 with different specifications can be connected to the first and second junction boxes 111 and 121, respectively, provided with passing conductors 117, 118, 127, and 128, making the solar power generation system 100 compact. It can be implemented. Accordingly, the convenience of construction and use of the solar power generation system 100 can be significantly improved, and there is an advantage in that construction costs and maintenance/repair costs can be significantly reduced.

Meanwhile, the first connection conductor 114, the first through conductor 116, the 1-1 through conductor 117, the 1-2 through conductor 118, the second connection conductor 125, and the second through conductor At least one conductor among (124), the 2-1st passing conductor 127, and the 2-2nd passing conductor 128 may be a waterproof connector. For example, the waterproof connector may be provided in a form similar to any one of (a), (b), and (c) of Figure 9, but is not necessarily limited thereto.

In addition, the first connection conductor 114, the first through conductor 116, the 1-1 through conductor 117, the 1-2 through conductor 118, the second connection conductor 125, and the second through conductor At least one of the conductors 124, 2-1st passing conductor 127, and 2-2nd passing conductor 128 may be equipped with a closing cap of the type shown in (d) of FIG. 9. In other words, the input terminals 114a and 125a of the first connection wire 114 and the second connection wire 125 are connected to the first diode circuit 113 and the second diode circuit 123 and have cutting sections 115 and 126. And a finishing cap may be installed at each end of the output terminals 114a and 125a.

Meanwhile, referring to FIGS. 10 and 11, the solar power generation system 100 according to an embodiment of the present invention includes a third junction box with specifications different from the first junction box 111 and the second junction box 121. (131) may be further included.

A third solar cell module (not shown) having different specifications from the first solar cell module 110 and the second solar cell module 120 may be connected to the third junction box 131.

In addition, the solar power generation system 100 according to an embodiment of the present invention may further include a third inverter 139 that supplies and converts the third direct current power generated by the third solar cell module.

Here, the third junction box 131 is provided in the third enclosure 132 having an internal space, in the same manner as the first junction box 111 and the second junction box 121, It may include one third connection conductor 136, a third through conductor 134, a 3-1 through conductor 135, and a 3-2 through conductor 138.

The third diode circuit 133 is connected to the third connection wire 136, and can supply the third direct current power generated from the third solar cell module to the third inverter 139 through the third connection wire 136. there is.

The third through conductor 134 is connected to the first connection conductor 114 and the second through conductor 124. The 3-1st passing conductor 135 is connected to the second connecting conductor 125 and the first passing conductor 116.

At this time, one end of the third connecting conductor 136 is connected to the positive terminal (+) of the third inverter 139 via the 2-1 through conductor 127 and the 1-1 through conductor 117, The other end of the third connection wire 136 is connected to the negative terminal (-) of the third inverter 139.

If necessary, the other end of the third connection conductor 136 is connected to the third inverter ( 139) can be connected to the negative terminal (-).

Here, the 3-2 through conductor 138 is the above-described 1-1 through conductor 117, 1-2 through conductor 118, 2-1 through conductor 127, and 2-2 through conductor. It can be used as a return wire to connect to the negative terminal (-) of the third inverter (139), as shown in (128).

Meanwhile, in the drawing, the first enclosure 112 of each first junction box 111, the second enclosure 122 of the second junction box 121, and the inside of the third enclosure 132 of the third junction box 131 It is shown that one connecting conductor (114, 125, 136) and three passing conductors (115, 117, 117, 124, 127, 128, 134, 135, 138) are provided, but this is not necessarily limited, and additional passing conductors may be provided as needed. The number of additionally provided passing conductors is the first enclosure 112 of the first junction box 111, the second enclosure 122 of the second junction box 121, and the third enclosure of the third junction box 131 ( 132) It may vary depending on each internal space and the number of solar cell modules included in the solar power generation system 100.

The preferred embodiments of the present invention described above have been disclosed for illustrative purposes, and those skilled in the art will be able to make various modifications, changes, and additions within the spirit and scope of the present invention, and such modifications and changes will be possible. and additions should be regarded as falling within the scope of the following claims.

100: Solar power generation system
110: first solar cell module 111: first junction box
112: first enclosure 113: first diode circuit
114: first connecting conductor 116: first passing conductor
117: 1-1 passing conductor 118: 1-2 passing conductor
119: first inverter
120: Second solar cell module 121: Second junction box
122: second enclosure 123: second diode circuit
124: second passing conductor 125: second connecting conductor
127: 2-1 passing conductor 128: 2-2 passing conductor
129: second inverter
131: Third junction box 132: Third enclosure
133: third diode circuit 134: third through conductor
135: 3-1 passing conductor 136: 3rd connecting conductor
138: 3-2 through conductor 139: 3rd inverter

Claims (10)

A first inverter to which direct current power generated from the first solar cell module is supplied;
A first junction box electrically connected to the first solar cell module and provided with a first diode circuit for transferring direct current power generated by the first solar cell module to the first inverter;
a second inverter supplied with direct current power generated from a second solar cell module having specifications different from those of the first solar cell module; and
a second junction box electrically connected to the second solar cell module and provided with a second diode circuit for transferring direct current power generated by the second solar cell module to the second inverter; Includes,
The first junction box includes a first connecting conductor that connects the first solar cell module and the first diode circuit, and a first passing conductor that has an input terminal and an output terminal and is not connected to the first diode circuit but connects the input terminal and the output terminal to each other. prepared,
The second junction box includes a second connecting conductor connecting the second solar cell module and the second diode circuit, and a second passing conductor having an input terminal and an output terminal and not connected to the second diode circuit, but connecting the input terminal and the output terminal to each other. provided,
A solar power generation system in which the first connection conductor is connected to the second through conductor, and the second connection conductor is connected to the first through conductor.
According to paragraph 1,
When the second junction box is located on one side of the first junction box and the first inverter and the second inverter are located on the other side of the first junction box,
The first connection wire of the first junction box is connected to the first inverter,
A solar power generation system in which the second connection conductor of the second junction box is provided to be connected to the second inverter via the first passing conductor of the first junction box.
According to paragraph 2,
A 1-1 passing conductor and a 1-2 passing conductor are provided in the first junction box,
The second junction box is provided with a 2-1 through conductor connected to the 1-1 through conductor and a 2-2 through conductor connected to the 1-2 through conductor,
One end of the second connection conductor of the second junction box is connected to the positive terminal of the second inverter via the second through conductor of the first junction box,
The other end of the second connection conductor of the second junction box is connected to the negative terminal of the second inverter via the 2-2 through conductor and the 1-2 through conductor in that order.
According to paragraph 1,
When the first junction box is located on one side of the second junction box and the first inverter and the second inverter are located on the other side of the second junction box,
The second connection wire of the second junction box is connected to the second inverter,
A solar power generation system in which the first connecting conductor of the first junction box is connected to the first inverter via the second passing conductor of the second junction box.
According to paragraph 4,
A 1-1 passing conductor and a 1-2 passing conductor are provided in the first junction box,
The second junction box is provided with a 2-1 through conductor connected to the 1-1 through conductor and a 2-2 through conductor connected to the 1-2 through conductor,
One end of the first connection conductor of the first junction box is connected to the positive terminal of the first inverter via the second through conductor of the second junction box,
The other end of the first connecting conductor of the first junction box is connected to the negative terminal of the first inverter via the 1-1 passing conductor and the 2-1 passing conductor in that order.
In the junction box where a first solar cell module and a second solar cell module with specifications different from the first solar cell module are connected,
An enclosure having an interior space;
A diode circuit provided inside the enclosure and connected to a first inverter corresponding to the first solar cell module;
A connecting wire provided inside the enclosure and electrically connected to the diode circuit and the first solar cell module; and
a passing conductor that is provided to be spaced apart from the connecting conductor, has an input terminal and an output terminal, and is not connected to the diode circuit, but the input terminal and the output terminal are connected to each other; Junction box for solar power generation system, including.
According to clause 6,
The passing conductor connects the second solar cell module and the second inverter corresponding to the second solar cell module,
A junction box for a solar power generation system in which the second solar cell module is connected to the second inverter via a passing conductor.
In clause 7,
One or more return conductors are provided in the enclosure,
One end of the connecting wire is connected to the positive terminal of the first inverter,
A junction box for a solar power generation system in which the other end of the connection wire is connected to the negative terminal of the first inverter via a return wire.
According to clause 8,
A junction box for a solar power generation system in which at least one of the connecting conductors, passing conductors, and return conductors is a waterproof connector.
According to clause 8,
A junction box for a solar power generation system in which a closing cap is installed on at least one of the connecting conductors, passing conductors, and return conductors.

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