KR20220076098A - Building intergrated photo voltaic module - Google Patents

Abstract

The present invention relates to a building-integrated photovoltaic module that is easy to install and whose wiring structure can be easily changed. an edge frame surrounding the edge of the solar panel and having first to fourth inter-module connection electrodes provided on first to fourth outer surfaces along the circumference; It is provided in the frame frame, is connected to the input terminal and output terminal of the solar panel, and the first to fourth inter-module connection electrodes, and two panel electrode connection parts among the first to fourth inter-module connection electrodes. and a wiring path switching unit connected to each of the input and output terminals of the solar panel.

Description

Building-integrated photovoltaic module {BUILDING INTERGRATED PHOTO VOLTAIC MODULE}

The present invention relates to a building-integrated photovoltaic module, and more particularly, to a building-integrated photovoltaic module in which connection between building-integrated photovoltaic modules is easy, and connection between building-integrated photovoltaic modules is easy to modify even after installation.

In general, photovoltaic power generation (photovoltaic) is a device that converts light energy into electrical energy using the properties of a semiconductor. it is made possible

Since such solar power generation has a small electromotive force, it is configured in a plate shape to have an appropriate electromotive force by connecting a plurality of unit solar cell modules.

Recently, a building integrated photovoltaic (BIPV) module that is integrated with the architecture of a building or house has also appeared.

Such a building-integrated photovoltaic module is connected to an adjacent photovoltaic module through cable work. In the process of installing a building-integrated photovoltaic module, the cable connection work is cumbersome, and if the cable is incorrectly connected, the process of repairing it is not easy.

Korean Patent Publication No. 10-2010-0130707

In order to solve the above problems, an object of the present invention is to provide a building-integrated photovoltaic module in which the connection between the building-integrated photovoltaic modules is easy and the connection between the building-integrated photovoltaic modules is easy to correct even after assembly is completed.

A building-integrated photovoltaic module of the present invention includes at least one solar cell and a rectangular solar cell panel; an edge frame surrounding the edge of the solar panel and having first to fourth inter-module connection electrodes provided on first to fourth outer surfaces along the circumference; It is provided in the frame frame, is connected to the input terminal and output terminal of the solar panel, and the first to fourth inter-module connection electrodes, and two panel electrode connection parts among the first to fourth inter-module connection electrodes. and a wiring path switching unit connected to each of the input and output terminals of the solar panel.

In addition, in an embodiment, the wiring path switching unit is provided in a state exposed to the frame frame.

In addition, in an embodiment, two inter-module connection electrodes among the first to fourth inter-module connection electrodes are provided as protruding electrodes, and the remaining two inter-module connection electrodes protrude from adjacent building-integrated solar modules. It is provided as a recessed electrode in the form of a groove that can be inserted and fixed by the electrode.

Further, in an embodiment, any one of the protruding electrode and the recessed electrode includes a magnetic material, and the other one includes a metallic conductor attracted to the magnetic material.

In addition, in the combined structure of the building-integrated photovoltaic module and the support frame supporting the building-integrated photovoltaic module, the building-integrated photovoltaic module of any one of claims 1 to 4; and a support frame supporting the building-integrated photovoltaic module and having a vertical frame in a vertical direction and a horizontal frame in the horizontal direction, wherein each of the vertical frame and the horizontal frame has a building-integrated photovoltaic module adjacent to each other. A frame connection electrode for connecting the module-to-module connection electrodes is provided.

According to the present invention, since the protruding electrode provided on the outer surface of the frame frame and the recessed electrode into which the protruding electrode of the adjacent building-integrated photovoltaic module can be inserted are provided, a separate cable connection is performed when assembling the building-integrated photovoltaic module. won't be needed

In addition, according to the present invention, since the wiring path switching unit is provided, it is possible to easily change the connection structure between the building-integrated photovoltaic modules.

In addition, according to the present invention, since the wiring path switching unit is provided on the frame frame and exposed to the outside, even when the wiring path switching unit is incorrectly set and the building-integrated solar module is assembled, the solar module is not separated to the outside. It can be readjusted by manipulating the exposed wiring path switching unit.

1 is an exploded perspective view of a building-integrated photovoltaic module according to an embodiment of the present invention.
FIG. 2 is a view for explaining the solar cell panel shown in FIG. 1 .
FIG. 3 is a view for explaining the frame frame shown in FIG. 1 .
4 is a view for explaining a connection method between the frame electrode provided in the frame frame and the panel connection electrode provided in the solar cell panel.
FIG. 5 is a diagram for explaining the control unit illustrated in FIG. 1 .
6 is a view for explaining a connection method between the terminal connection part of the control unit provided in the frame frame shown in FIG. 1 between the panel electrode connection terminals of the solar cell panel.
7 is a view for explaining the coupling state of the building-integrated photovoltaic module shown in FIG.
8 is a view for explaining the structure before the building-integrated solar module is combined with the support frame.
9 is a view for explaining the structure after the building-integrated solar module is combined with the support frame.
10 is a view showing a solar cell panel of a building-integrated photovoltaic module according to another embodiment of the present invention.
11 is a view for explaining a frame frame of a building-integrated photovoltaic module according to another embodiment of the present invention.

Hereinafter, a building-integrated photovoltaic module according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is an exploded perspective view of a building-integrated photovoltaic module according to an embodiment of the present invention, and FIG. 2 is a view for explaining the solar cell panel shown in FIG. 1 . And FIG. 3 is a view for explaining the frame frame shown in FIG. 1 .

Referring to FIG. 1 , a building-integrated photovoltaic module 10 according to a first embodiment of the present invention includes a rectangular solar panel 100 including at least one solar cell, and an edge of the solar panel. Includes a border frame 200 surrounding the.

A building-integrated photovoltaic module is BIPV (Building Integrated Photo Voltanic), which simultaneously functions as an exterior wall material or roof material of a building and a function of photovoltaic power generation.

The solar panel 100 includes an input/output terminal 110 and a panel electrode connection terminal 120 provided on one side of the front part, and a protective film 130 provided on the front part.

The solar panel 100 includes at least one solar cell and has a quadrangular shape with four sides. The solar panel 100 may be provided in various shapes other than a square shape. The solar cells in the solar panel 100 are connected to each other in various structures such as series, series and parallel.

The protective film 130 is provided on the front portion of the solar panel 100 , and serves to protect the front portion of the solar panel 100 . The protective film 130 may be provided with a protective film or glass.

The solar panel 100 is attached to the remaining front part except for one part of the front part where the input/output terminal 110 and the panel electrode connection terminal 120 are provided. In FIG. 1 , it is attached to the front part of the solar panel 100 except for the upper part of the front part of the solar panel 100 .

Referring to FIG. 2 , an input/output terminal 110 and a panel connection electrode terminal 120 are provided on one side of the front portion of the solar panel 110 to which the protective film 130 is not attached.

The input/output terminal 110 is provided in an exposed state on one side of the front part of the solar panel 110 . The input/output terminal 110 includes an input terminal 110a and an output terminal 110b of the solar panel 100 . The input/output terminal 110 is electrically connected to the control unit 300 , specifically, the junction unit 320 provided in the control unit 300 . The input/output terminal 110 provided in an exposed state is connected by the electrode connection unit 310 of the control unit 300 provided in the frame frame 200 .

The panel connection electrode terminals 120 are provided in plurality, and the plurality of panel connection electrode terminals 120b, 120c, and 120d are provided on one side of the front surface of the solar cell panel 100 . On the other hand, the panel connection electrode terminal on one side close to the control unit 300 may be omitted as shown in the drawing.

The panel connection electrode 130 is provided at each edge of the solar cell panel 100 . On the other hand, one side of the solar panel 100, for example, the panel connection electrode of the upper part may be omitted.

The panel connection electrode terminals 120b, 120c, and 120d are provided in a state of being electrically connected to the panel connection electrodes 130b, 130c, 130d respectively provided along the edge of the solar panel 100, respectively. And when the edge frame 200 is coupled to the solar panel 100 , the panel connection electrode terminals 120 are respectively connected to the control terminals 310 of the control unit 300 .

3, when the edge frame 200 is mounted on the solar panel 100, the panel connection electrodes 130b, 130c, 130d are the edge frame electrodes 221b, 221c, 221d of the edge frame 200 and electrically connected. The panel connection electrode terminals 120b, 120c, and 120d are electrically connected to the edge frame electrodes 221b, 221c, and 221d of the edge frame 200 .

The edge frame 200 surrounds the edge of the solar panel 100 to protect the edge of the solar panel 100 . The frame 200 may be assembled into one after being provided in plurality in the form of a bar. At this time, the frame 200 is provided with the control unit 300 exposed to the outside.

Referring to FIG. 3 , on the inner surface of the edge frame 200 , the edge frame electrodes 221b , 221c , 221d that can be electrically connected to the panel connection electrodes 130b , 130c , 130d of the solar panel 100 , respectively, are provided. It is provided, and the module-to-module connection electrodes 222a to 222d capable of electrical connection between adjacent solar modules are provided on the outer surface of the frame 200 . At this time, the control unit 300 is coupled to the position corresponding to the input/output terminal 110 and the panel connection electrode terminal 120 of the solar panel 100, and the input/output terminal 110 and the panel connection electrode terminal 120 are the control unit ( 300) is directly connected to the first and second control terminals 310a to 310f.

The edge frame electrodes 221b, 221c, and 221d are respectively connected to the corresponding inter-module connection electrodes 222a to 222d. In particular, some of the module-to-module connection electrodes 222a may be directly connected to the control unit 300 .

The module-to-module connection electrodes 222a to 222d include protruding electrodes 222a and 222d and recessed electrodes 222b and 222d into which the protruding electrodes of the adjacent building-integrated solar module can be inserted. The positions of the protruding electrode and the recessed electrode shown in the drawings may be changed as needed.

On the other hand, one type of the protruding electrode and the recessed electrode may be provided with a magnetic material, and the other type may be provided with a metallic conductor attracted to the magnetic material. In this case, it is possible to further facilitate the coupling of the protruding electrode and the recessed electrode of the building-integrated solar module adjacent to each other.

4 is a view for explaining a connection method between the frame electrode provided in the frame frame and the panel connection electrode provided in the solar cell panel.

Referring to FIG. 4 , the panel connection electrode 130d provided in the solar panel 100 and the edge frame electrode 221d provided in the frame frame 200 are electrically connected without a cable connection.

The edge frame electrode 221d provided in the edge frame 200 has one end protruding from the edge frame 200 in an outer diagonal direction, and may be made of a conductive elastic material. When the edge frame 200 is combined with the solar panel 100 , the panel connection electrode 130d and the edge frame electrode 221d provided in the edge frame 200 can be simply connected without a separate cabling.

FIG. 5 is a diagram for explaining the control unit illustrated in FIG. 1 .

Referring to FIG. 5 , the control unit 300 includes a terminal connection unit 310 , a junction unit 320 , and a wiring path switching unit 330 .

The terminal connection part 310 includes first terminal connection parts 310a and 310b and second terminal connection parts 310a and 310b.

The first terminal connection parts 310a and 310b are respectively connected to the input terminal 110a and the output terminal 110b, and the second terminal connection parts 310a and 310b among the terminal connection parts 310a to 310f are the panel electrode connection terminals 120b. , 120c, 120d). On the other hand, some of the terminal connection portions 310c are directly electrically connected to the module-to-module connection electrode 221a of the frame frame 200 through wiring in the frame frame 200 .

The first terminal connection units 310a and 310b connected to the input terminal 110a and the output terminal 110b are input to the wiring path switching unit 330 through the junction unit 320, and the second terminal connection units 310c to 310f) is directly connected to the wiring path switching unit 330 .

6 is a view for explaining a connection method between the terminal connection part of the control unit provided in the frame frame shown in FIG. 1 between the panel electrode connection terminals of the solar cell panel.

Each of the terminal connection units 310 of the control unit 300 includes an electrical connection means that can be simply connected to the panel electrode connection terminal 120 without cabling.

Referring to FIG. 6 , each of the terminal connection parts 310 of the control unit 300 is formed through the frame frame 200 , one end is located outside the frame frame 200 , and the other end is inside the frame frame 200 . It protrudes in a diagonal direction from the , and may be provided with a conductive elastic material. When the edge frame 200 is coupled to the solar panel 100 , each of the terminal connection parts 310a to 310f may be simply connected to the panel electrode connection terminal 120 without separate cabling.

Referring back to FIG. 5 , the junction unit 320 functions as a junction box and may include a bypass diode and the like therein.

The wiring path switching unit 330 connects two second terminal connection parts of the second terminal connection parts 310c to 310f to the first terminal connection parts 310a and 310b, respectively. At this time, since switches s1 to s8 are provided on each line, the first terminal connection parts 310a and 310b can be selectively switched and connected with two second terminal connection parts of the second terminal connection parts 310c to 310f.

At this time, each of the second terminal connection parts 310c to 310f is connected to the module-to-module connection electrodes 222a to 222d of the frame 200, and the second terminal connection parts 310a and 310b, respectively, of the solar panel 100. It is connected to the input terminal 110a and the output terminal 110b through the junction unit 320 .

Specifically, the wiring path switching unit 330 closes two of these switches s1 to s8, and connects the input terminal 110a to any one of the module-to-module connection electrodes 222a to 222d of the frame 200. and connect the output terminal 110b to the other one of the module-to-module connection electrodes 222a to 222d of the edge frame 200 .

At this time, since the input terminal 110a and the output terminal 110b have passed through the junction unit 320, one becomes a + terminal and the other becomes a - terminal. The wiring path switching unit 300 connects two different inter-module connection electrodes among the module-to-module connection electrodes 222a to 222d of the edge frame 200 to the + terminal and the - terminal.

7 is a view for explaining the coupling state of the building-integrated solar module shown in FIG.

By manipulating the wiring path switching unit 330 of each of the solar modules a to f, it is possible to implement the connection state in all cases. For example, when building-integrated photovoltaic modules are connected in series in the order of a-b-c-f-e-d, by manipulating each wiring path switching unit 330 , it is possible to have directionality and change the wiring structure.

It is assumed that the input terminal 310a is a - terminal and the output terminal 310b is a + terminal.

a, b Close s2 of the wiring path switching unit 300 in the building-integrated photovoltaic module, and close s8. c Close s2 of the wiring path switching unit 300 in the building-integrated photovoltaic module and close s6. d Close s1 of the wiring path switching unit 300 in the building-integrated photovoltaic module and close s4. e, d Close s1 of the wiring path switching unit 300 in the building-integrated photovoltaic module and close s7. Through the operation of the wiring path switching unit 300 as described above, it is possible to achieve the coupling between the building-integrated photovoltaic modules having the above structure.

In this case, each of the switches s1 to s8 may be provided as one switch having various options.

According to the present invention, the protruding electrodes 222a and 222d provided on the outer surface of the frame 200 and the recessed electrodes 222b and 222d into which the protruding electrodes of the adjacent building-integrated solar module can be inserted are provided, When assembling building-integrated photovoltaic modules, a separate cable connection is not required.

In addition, according to the present invention, since the wiring path switching unit is provided, it is possible to easily change the connection structure between the building-integrated photovoltaic modules.

According to the present invention, since the wiring path switching unit is provided in the frame frame and is exposed to the outside, even when the wiring path switching unit is assembled in a state where the wiring path switching unit is incorrectly set, the solar module is not separated and exposed to the outside It can be readjusted by manipulating the wired path switching unit.

8 is a view for explaining the structure before the building-integrated photovoltaic module is coupled to the support frame, Figure 9 is a view for explaining the structure before the building-integrated photovoltaic module is coupled with the support frame.

Referring to FIGS. 8 and 9 , the building-integrated photovoltaic module 10 includes an inter-module connection electrode 222 on the frame 200 . The module-to-module connection electrode 222 includes protruding protruding electrodes 222a and 222d and recessed electrodes 222b and 222d into which protruding electrodes of an adjacent building-integrated solar module can be inserted.

The support frame 1000 performs a function of fixing and supporting the building-integrated photovoltaic module 10 . The support frame 1000 may be provided as a curtain wall.

The support frame 1000 is composed of a combination of a vertical frame 1100 in a vertical direction and a horizontal frame 1200 in a horizontal direction.

Frame connection electrodes 1110 and 1120 connecting the module-to-module connection electrodes of the building-integrated photovoltaic module adjacent to each other on both sides of the vertical frame 1100 are provided on the inside and outside of the vertical frame 1100, respectively, and the inside and the frame connection electrodes 1110 and 1120 located outside are electrically connected.

And on both sides of the horizontal frame 1200, frame connection electrodes 1210 and 1220 for connecting the inter-module connection electrodes of the building-integrated solar module adjacent to each other are provided on the inside and outside of the horizontal frame 1200, respectively, It is electrically connected between the frame connection electrodes 1210 and 1220 located on the inner side and the outer side. When the inter-module connection electrode of the building-integrated solar module is a protruding electrode, the corresponding frame connection electrode is provided as a recessed electrode, and when the inter-module connection electrode of the building-integrated solar module is a recessed electrode, the corresponding frame connection The electrode is provided as a protruding electrode.

According to the present invention, even if the support frame is located between the building-integrated photovoltaic modules, by using the frame connection electrode in the support frame, it is possible to connect between the module-to-module connection electrodes of the building-integrated photovoltaic module adjacent to each other.

10 is a view illustrating a solar cell panel of a building-integrated photovoltaic module according to another embodiment of the present invention, and FIG. 11 is a view for explaining a frame frame of a building-integrated photovoltaic module according to another embodiment of the present invention to be.

Referring to FIG. 10 , the solar panel 100 is provided with input/output terminals 110a and 110b and panel connection electrode terminals 120a to 120d. In the drawing, the dotted line is a portion where the solar cell panel 100 is located.

The solar panel 100 of the building-integrated photovoltaic module of this embodiment is not provided with panel connection electrodes 130b, 130c, 130d for connecting to the frame frame 200, and the corresponding configuration is the frame frame 200. is provided in

Referring to FIG. 11 , the frame 200 includes a control unit 300 including first terminal connection parts 310a and 310b and second terminal connection parts 310c to 310f, and second terminal connection parts 310c to 310f. ) is directly connected to the module-to-module connection electrodes 222a to 222d through a line. Accordingly, it is possible to omit the edge frame electrode 221d provided in the edge frame 200 in the previous embodiment.

The solar cell panel of this embodiment has the advantage of simplifying the configuration of the solar cell panel of the previous embodiment.

According to the present invention, since the protruding electrode provided on the outer surface of the frame frame and the recessed electrode into which the protruding electrode of the adjacent building-integrated photovoltaic module can be inserted are provided, a separate cable connection is performed when assembling the building-integrated photovoltaic module. won't be needed

In addition, according to the present invention, since the wiring path switching unit is provided, it is possible to easily change the connection structure between the building-integrated photovoltaic modules.

In addition, according to the present invention, since the wiring path switching unit is provided on the frame frame and exposed to the outside, even when the wiring path switching unit is incorrectly set and the building-integrated solar module is assembled, the solar module is not separated to the outside. It can be readjusted by manipulating the exposed wiring path switching unit.

Above, although the preferred embodiment has been described, those of ordinary skill in the art to which the present invention pertains will understand that various modifications and variations are possible without departing from the technical spirit of the present invention.

10: Building-integrated photovoltaic module
100: solar panel
110: input/output terminal
120: panel connection electrode terminal
130: panel connection electrode
200: border frame
221: border frame electrode
222: module-to-module connection electrode
300: control unit
310a, 310b: terminal connection part
320: junction unit
330: wiring path switching unit

Claims (5)

A solar cell panel having at least one solar cell and having a solar cell shape;
an edge frame surrounding the edge of the solar panel and having first to fourth inter-module connection electrodes provided on first to fourth outer surfaces along the circumference;
It is provided in the frame frame, and is connected to the input terminal and output terminal of the solar panel, and the first to fourth inter-module connection electrodes, and two panel electrode connection parts among the first to fourth inter-module connection electrodes. A building-integrated photovoltaic module comprising a wiring path switching unit connected to each of the input and output terminals of the solar panel. According to claim 1,
The wiring path switching unit, a building-integrated photovoltaic module, characterized in that provided in a state exposed to the frame. According to claim 1,
Among the first to fourth module-to-module connection electrodes, two inter-module connection electrodes are provided as protruding electrodes, and the remaining two inter-module connection electrodes are inserted and fixed by protruding electrodes of adjacent building-integrated photovoltaic modules. A building-integrated photovoltaic module, characterized in that it is provided with a recessed electrode in the form of a groove. According to claim 1,
One of the protruding electrode and the recessed electrode includes a magnetic material, and the other one includes a metal conductor attracted to the magnetic material. In the combined structure of the building-integrated photovoltaic module and the support frame supporting the building-integrated photovoltaic module,
The building-integrated photovoltaic module of any one of claims 1 to 4; and
It supports the building-integrated photovoltaic module and includes a support frame having a vertical frame in a vertical direction and a horizontal frame in the horizontal direction,
A combination structure of a building-integrated photovoltaic module and a support frame, characterized in that each of the vertical frame and the horizontal frame is provided with a frame connection electrode for connecting the inter-module connection electrodes of the adjacent building-integrated photovoltaic module to each other.

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