KR102593027B1 - Louver assembly with solar cell panel - Google Patents

Abstract

The present invention provides a solar cell panel portion having a pair of terminal portions provided at each end, a pair of first electrode terminals for electrical connection to each terminal portion, and a solar cell panel portion surrounding each first electrode terminal. A plurality of solar cell module units including a pair of first caps mounted on; a second electrode terminal to be electrically connected to the first electrode terminal and a plurality of second caps for accommodating the second electrode terminal and for mounting the first cap; A frame portion including an inner frame on which a plurality of second caps are rotatably mounted, respectively, along the longitudinal direction, and an outer frame surrounding the inner frame; It is disposed between the inner frame and the outer frame, and when a plurality of solar cell module units are mounted within the frame unit, a pair of third electrode terminals for electrically connecting the second electrode terminals of two adjacent solar cell module units are provided. The object is to provide a solar cell louver assembly including a connector portion.

Description

Louver assembly on which a solar cell panel can be mounted {Louver assembly with solar cell panel}

The present invention relates to a louver assembly in which a solar cell panel (solar cell module) integrated into a louver window applicable to public buildings can be mounted.

Recently, efforts have been made to use natural energy such as solar energy as alternative energy as a way to reduce energy consumption. Among the solar energy mentioned above, a solar power generation system that utilizes solar energy installs solar modules on the exterior wall of a building in areas that receive a lot of sunlight, collects sunlight from the solar module, and then converts the concentrated sunlight into electrical energy. It is supplied inside the building.

When solar modules of such a solar power generation system are connected in series, not only is the electrically connected wiring connection structure complicated, but there is also a problem of damage or destruction of the wiring due to external factors due to exposure to the outside.

This not only increases the manufacturing and installation costs of solar modules, but also makes maintenance difficult in the event of a breakdown.

Therefore, there is a need for technology to solve the above problems.

The present invention was developed to solve the above-described problems, and provides a louver assembly equipped with a solar cell panel (solar module) that can more easily connect in series without the wiring of a plurality of solar cell modules being exposed to the outside. There is a purpose.

In addition, the purpose is to provide a louver assembly capable of generating solar power according to the angle by inserting and mounting a solar cell panel into the louver frame.

In order to achieve the above object, according to one aspect of the present invention, a solar cell panel unit having a pair of terminal portions respectively provided at both ends, a pair of first electrode terminals for being electrically connected to each terminal portion, and each A plurality of solar cell module units including a pair of first caps mounted on the solar cell panel unit to surround the first electrode terminal; a plurality of second caps including second electrode terminals to be electrically connected to the first electrode terminals; a frame portion on which a plurality of second caps are respectively rotatably mounted along the longitudinal direction; A solar cell louver assembly including a connector portion including a pair of third electrode terminals for electrically connecting the second electrode terminals of two adjacent solar cell module portions when a plurality of solar cell module portions are mounted in the frame portion. provides.

In addition, when the first cap is mounted on the second cap, the second electrode terminal is in contact with the first electrode terminal, and when the connector portion is mounted on the second cap, the third electrode terminal is in contact with the second electrode terminal. It is prepared.

In addition, one of the first and second electrode terminals is provided to have a space into which the remaining terminal is inserted, and when the first cap is mounted on the second cap, one of the first and second electrode terminals The terminal is inserted into the interior of the remaining terminal.

Additionally, the first electrode terminal includes a plurality of first electrode rods forming a space into which the second electrode terminal is inserted, at least one first electrode rod is bent at least once, and the second electrode terminal is connected to the first electrode. It is provided to contact the bent part of the rod or to be inserted into the space between the bent parts of the first electrode rod.

Additionally, the first electrode terminal includes a first connection portion electrically connected to the solar cell panel and a second connection portion for contacting the bypass diode.

Additionally, the plurality of first electrode rods, the first connection portion, and the second connection portion are formed integrally.

In addition, one of the second and third electrode terminals is provided to have a space into which the remaining terminal is inserted, and when the connector portion is mounted on the second cap, one of the second and third electrode terminals is It is inserted into the remaining terminals.

In addition, the second electrode terminal includes a plurality of second electrode rods forming a space into which the third electrode terminal is inserted, at least one second electrode rod is bent at least once, and the third electrode terminal is the second electrode terminal. It is provided to contact the bent part of the electrode rod or to be inserted into the space between the bent parts of the second electrode rod.

In addition, the frame unit includes an inner frame on which a plurality of second caps are each rotatably mounted along the longitudinal direction, and an outer frame surrounding the inner frame, and when the second cap is mounted on the inner frame, a plurality of second caps are provided. The two-electrode rod is provided so that at least a portion of the area is exposed to the space between the inner frame and the outer frame.

Additionally, the connector portion includes a connecting member surrounding each third electrode terminal; and a pair of mounting members connected to the connecting member, each located on the end side of the third electrode terminal to expose the third electrode terminal to the outside, and provided to be mounted on the second cap.

Additionally, the first electrode terminal and the second electrode terminal are provided to be inserted along the longitudinal direction of the inner frame.

In addition, each of the first caps has a first surface facing the solar cell panel unit and a second surface in an opposite direction to the first surface, and the first surface has a first cap into which at least a partial region of the solar cell panel is inserted. It has an insertion groove, and includes a first binding portion on the second surface to be coupled to the second cap. The first and second connection portions of the first electrode terminal are located in the first insertion groove, and the plurality of first electrode rods are connected to the second cap. 1 It is provided to be located on the binding part side.

In addition, each of the second caps has a first mounting portion having a predetermined space on the inside so that the first cap can be slidably inserted and mounted, and a second mounting portion provided to have a connector portion mounted in the opposite direction of the first mounting portion, and the second mounting portion The electrode terminal extends from a plurality of second electrode rods and has a third connection portion for electrically connecting to the first electrode rod of the first electrode terminal, and the third connection portion is provided to be exposed to the outside on the first mounting portion side. , a plurality of second electrode rods are provided to be located on the second mounting part side.

In addition, the third electrode terminal extends from a fourth connection part and a fourth connection part electrically connected to the second electrode rod of the second electrode terminal, and electrically connects two solar cell module parts adjacent to each other along the longitudinal direction of the inner frame. It has a fifth connection part for connection to the device, the fourth connection part is exposed to the outside toward the second mounting part, and the fifth connection part is provided to be located on the connection member side.

According to the present invention, the louver assembly of the present invention can be assembled in the same way as a conventional louver window is assembled, making assembly easier.

It also has the advantage of acting as a louver window and simultaneously producing electricity from solar panels connected in series.

Additionally, there is an advantage that the wiring of a plurality of solar cell panels can be more easily connected in series without being exposed to the outside.

Figure 1 is a perspective view showing the front and back of a louver assembly equipped with a solar cell panel according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing a solar cell module unit according to an embodiment of the present invention.
Figure 3 is a partially enlarged view of Figure 1.
Figure 4 is a cross-sectional view of Figure 3.
5 and 6 are perspective and side views showing first to third electrode terminals according to an embodiment of the present invention.
FIG. 7 is a diagram showing a state in which a plurality of solar cell module units of FIG. 2 are electrically connected.
Figure 8 is a perspective view and a side cross-sectional view of a blade frame on which a solar cell panel is mounted according to an embodiment of the present invention.
Figure 9 is a perspective view and a side cross-sectional view showing a state in which the blade frame is arranged along the vertical direction according to an embodiment of the present invention.
Figure 10 is a diagram showing a first cap provided with a first electrode terminal according to an embodiment of the present invention.
Figure 11 is a diagram showing a second cap according to an embodiment of the present invention.
Figure 12 is a diagram showing a fixing member according to an embodiment of the present invention.
Figures 13 and 14 are diagrams to explain a frame unit according to an embodiment of the present invention.
Figure 15 is a perspective view showing a connector portion according to an embodiment of the present invention.
Figure 16 is a diagram showing a state in which the solar cell module portion is mounted on the second cap and the connector portion is mounted on the second cap according to an embodiment of the present invention.
Figure 17 is a diagram showing a state in which solar cell louver assemblies according to an embodiment of the present invention are connected in series.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

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.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing this application, various alternatives are available to replace them. It should be understood that equivalents and variations may exist.

Hereinafter, the louver assembly 1 on which a solar cell panel can be mounted according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

First, throughout this specification, the vertical direction means a direction perpendicular to the ground, and the horizontal direction means a direction parallel to the ground.

Additionally, in this document, the side where sunlight enters the solar panel is referred to as the front (front), and the direction opposite to the front is referred to as the back (rear).

Here, the front may be installed to face the outdoor side, and the rear may be installed to face the indoor side.

Figure 1 is a perspective view showing the front and rear of a louver assembly (1) equipped with a solar cell panel according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing a solar cell module portion according to an embodiment of the present invention, FIG. 3 is a partially enlarged view of FIG. 1, FIG. 4 is a cross-sectional view of FIG. 3, and FIGS. 5 and 6 are perspective and side views showing first to third electrode terminals according to an embodiment of the present invention.

1 to 6, a louver assembly (1, hereinafter referred to as 'louver assembly') equipped with a solar cell panel according to an embodiment of the present invention includes a plurality of solar cell module units 10 and a second It includes a cap 30, a frame portion 50, and a connector portion 70.

Specifically, referring to FIG. 2, the plurality of solar cell module units 10 include a solar cell panel unit 100 having a pair of terminal units 111 provided at both ends, each terminal unit 111, and It includes a pair of first electrode terminals 270 for electrical connection and a pair of first caps 200 mounted on the solar cell panel unit 100 to surround each first electrode terminal 270. .

In addition, the second cap 30 accommodates a second electrode terminal 310 and a second electrode terminal 310 to be electrically connected to the first electrode terminal 270, and the first cap 200 is A plurality of devices may be provided to be installed.

The first electrode terminal 270 in each first cap 200 may be formed integrally with the first cap 200 by insert-molding into the first cap 200 .

Additionally, the second electrode terminal 310 in each second cap 30 may be formed integrally with the second cap 30 by being insert-molded into the second cap 30 .

In this document, insert injection refers to the commonly used insert injection molding. After installing a predetermined insert member in the injection molding mold device, molten resin is injected into this insert member to produce the final insert molded product. It says what to do.

That is, in the present invention, the first cap or the second cap can be manufactured by injecting molten resin into the first electrode terminal or the second electrode terminal as an insert member.

In addition, the frame portion 50 includes an inner frame 500 on which a plurality of second caps 30 are rotatably mounted, respectively, along the longitudinal direction, and an outer frame 600 surrounding the inner frame 500. Includes.

In addition, the connector portion 70 is disposed between the inner frame 500 and the outer frame 600, and when a plurality of solar cell module portions 10 are mounted within the frame portion 50, two adjacent It includes a pair of third electrode terminals 710 for electrically connecting the second electrode terminals 310 of the solar cell module units 10, 11, and 12.

Here, the third electrode terminal 710 in each connector part 70 may be formed integrally with the connector part 70 by being insert-molded into the connector part 70.

More specifically, referring to FIGS. 2 to 4, when the first cap 200 is mounted on the second cap 30, the second electrode terminal 310 is in contact with the first electrode terminal 270. , When the connector portion 70 is mounted on the second cap 30, the third electrode terminal 710 may be provided to contact the second electrode terminal 310.

That is, the first electrode terminal 270 and the second electrode terminal 310 are electrically connected by physical contact (direct contact), and the second electrode terminal 310 and the third electrode terminal 710 are physically contacted. By being electrically connected (in direct contact), the first electrode terminal 270 and the third electrode terminal 710 can be electrically connected.

In addition, one of the first and second electrode terminals 270 and 310 is provided to have a space into which the remaining terminal is inserted, and when the first cap 200 is mounted on the second cap 30, , one of the first and second electrode terminals 270 and 310 may be inserted into the remaining terminal.

Specifically, referring to FIGS. 5 and 6, the first electrode terminal 270 includes a plurality of first electrode rods 271; 271a, 271b forming a space s1 into which the second electrode terminal 310 is inserted. , 271c), wherein at least one first electrode rod 271 is bent one or more times, and the second electrode terminal of the bent portion of the first electrode rod contacts or is inserted into the space between the bent portions of the first electrode rod. It can be provided.

That is, the space s1 into which the second electrode terminal 310 is inserted may be a space formed between the plurality of first electrode rods 271 by bending them one or more times.

In one embodiment, as shown in FIG. 5, when the first electrode rods 271 are composed of three, the two first electrode rods 271a and 271c, spaced apart from each other by a predetermined distance, are bent toward the solar cell panel side (left side). It may be formed to have a first bent portion 2711 and a second bent portion 2712 extending from the first bent portion and bent toward the second cap 30 (right side).

At this time, the remaining first electrode rod 271b formed between the two first electrode rods 271a and 271c, on the contrary, has a third bent portion 2713 and a third bent portion bent toward the second cap 30. It may be formed to have a fourth bent portion 2714 that extends from the portion 2713 and is bent toward the solar cell panel.

That is, when the first electrode rods are each bent two or more times, at least one first electrode rod may be bent in a different direction from the remaining first electrode rods.

In particular, the first bent portion and the third bent portion may be formed to be bent toward different directions, and the second bent portion and the fourth bent portion may be formed to be bent toward different directions.

In another embodiment, as shown in FIG. 6, when the first electrode rods 271 are composed of three, the two first electrode rods 271a and 271c, spaced apart from each other by a predetermined distance, are bent toward the solar cell panel side. It may be formed to have a bent portion 2711a.

At this time, the remaining first electrode rod 271b formed between the two first electrode rods may, on the contrary, be formed to have a second bent portion 2713b bent toward the second cap 30.

That is, when the first electrode rods are each bent once, the first bent portion and the second bent portion are bent in different directions, so that a predetermined space can be formed between the first electrode rods.

In addition, the first electrode terminal 270 includes a first connection portion 272 electrically connected to the solar cell panel and a second connection portion 273 for contacting the bypass diode.

Additionally, the plurality of first electrode rods 271 (271a, 271b, 271c), the first connection portion 272, and the second connection portion 273 may be formed as one body.

In addition, one of the second and third electrode terminals 310 and 710 is provided to have a space s2 into which the remaining terminal is inserted, and the connector portion 70 is mounted on the second cap 30. In this case, one of the second and third electrode terminals 310 and 710 may be provided to be inserted into the remaining terminal.

Specifically, the second electrode terminal 310 includes a plurality of second electrode rods 311 (311a, 311b, 311c) forming a space into which the third electrode terminal 710 is inserted, and at least one second electrode The rod 311 is bent one or more times, and the third electrode terminal 710 is provided to contact the bent part of the second electrode rod 311 or to be inserted into the space between the bent parts of the second electrode rod 311. You can.

That is, the space s1 into which the third electrode terminal 710 is inserted may be a space formed between the first electrode rods by bending the plurality of second electrode rods 311 one or more times.

In one embodiment, as shown in FIG. 5, when the second electrode rods 311 are composed of three, the two second electrode rods 311a and 311c, spaced apart from each other by a predetermined distance, are bent downward (lower side). It may be formed to have a bent portion 3111 and a second bent portion 3112 that extends from the first bent portion and is bent upward.

At this time, the remaining first electrode rod 311b formed between the two first electrode rods 311a and 311c, on the contrary, has a third bent portion 3113 and a third bent portion (3113) bent upward (upper side). 2713) and may be formed to have a fourth bent portion 3114 bent downward.

That is, when the second electrode rods are each bent two or more times, at least one second electrode rod may be bent in a different direction from the remaining second electrode rods.

In particular, the first bent portion and the third bent portion may be formed to be bent toward different directions, and the second bent portion and the fourth bent portion may be formed to be bent toward different directions.

In another embodiment, as shown in FIG. 6, when the second electrode rods 311 are composed of three, the two second electrode rods 311a and 311c spaced apart from each other by a predetermined distance have a first bent portion ( 3111a).

At this time, the remaining second electrode rod 311b formed between the two second electrode rods may be formed to have a second bent portion 3113a bent upward.

That is, when the second electrode rods are each formed by bending once, the first bent portion and the second bent portion are formed to be bent in different directions, so that a predetermined space s2 can be formed between the second electrode rods. there is.

In addition, the second electrode terminal 310 extends from the second electrode rod 311 and has a third connection portion 312 for electrical connection to the first electrode terminal.

The plurality of second electrode rods 311 and third connection portions 312 may be formed integrally.

That is, the third connection portion 312 may be in contact with a bent portion of the first electrode rod, or may be inserted into a space between the bent portions of the first electrode rod and electrically connected to the first electrode terminal.

In addition, when the second cap 30 is mounted on the inner frame 500, the plurality of second electrode rods 311 are configured such that at least a portion of the area is exposed to the space between the inner frame 500 and the outer frame 600. It can be provided.

In addition, the third electrode terminal 710 includes a fourth connection portion 711 and a fourth connection portion 711 that contacts the bent portion of the second electrode rod of the second electrode terminal or is inserted into the space s2 between the bent portions of the second electrode rod. 4 It extends from the connection part 711 and has a fifth connection part 712 for electrically connecting two solar cell module parts 10 (11, 12) adjacent to each other along the longitudinal direction of the inner frame 500.

In addition, the connector portion 70 is connected to a connecting member 720 surrounding each third electrode terminal 710 and the connecting member 720, and exposes the third electrode terminal 710 to the outside. Each is located on the end side of the third electrode terminal 710 and includes a pair of mounting members 730 provided to be mounted on the second cap 30.

Here, the fourth connection part 711 of the third electrode terminal 710 may be located on the side of the mounting member 730 exposed to the outside, and the fifth connection part 712 may be located on the side of the connection member 720. there is.

The above configuration has the effect of allowing the first to third electrode terminals to be electrically connected more stably.

Meanwhile, Figure 7 is a perspective view showing the solar cell panel 110 according to an embodiment of the present invention.

Referring to FIG. 7, the solar cell panel 110 has a pair of terminal portions 111 provided at both ends.

The solar cell panel 110 (also referred to as a 'solar module') is provided to extend along the longitudinal direction and has first and second terminals 111a and 111b at both ends (first and second ends). .

The first terminal 111a may have either (+) or (-) polarity, and the second terminal 111b may have either (+) or (-) polarity.

In addition, the solar cell panel includes, for example, glass 1101, one or more encapsulants (EVA, 1102, 1104), one or more solar cells 1100, and connecting the solar cells 1100 in series. It may include a cell string (1103) and a backsheet (1105).

Here, the solar cells 1100 can be connected in series through a cell string 1103 to form a solar cell (also called a 'solar cell string').

The glass 1101 is a surface on which sunlight is incident, and serves to protect the internal solar cell from the external environment and to scatter light and re-enter the reflected light.

For example, the glass can protect solar cells, which are easily broken in the event of external hail or fire, from impact and external flames.

Here, the thickness of the glass may be 2.8 mm, but is not limited to this and may be 2.8 mm or less.

Specifically, 0.1 mm to 2.8 mm, 0.2 mm to 2.7 mm, 0.3 mm to 2.6 mm, 0.4 mm to 2.5 mm, 0.5 mm to 2.4 mm, 0.6 mm to 2.3 mm, 0.7 mm to 2.2 mm, 0.8 mm to 2.1 mm. , 0.9mm to 2.0mm, 1.0mm to 1.9mm, 1.1mm to 1.8mm, 1.2mm to 1.7mm, 1.3mm to 1.6mm, 1.4mm to 1.5mm, but is not limited thereto.

More specifically, the glass 1101 of the solar cell panel 110 has a first surface on which light is incident and a second surface facing the solar cell side in the opposite direction of the first surface, and the first surface is the lower surface. It may be anti-reflection coating (AR coating) and may be a surface without a pattern.

The low-reflection coating reduces light that does not pass through the first surface but is reflected and goes out when light hits the first surface.

Here, the low-reflection coating may be formed on the first side and the second side, or may be formed only on the first side.

More preferably, the thickness of the glass can be made uniform by applying a low-reflection coating to the first surface on which the pattern is not formed.

The light (sunlight) may sequentially pass through the first and second sides of the glass and enter the solar cell.

Additionally, the second surface of the glass 1101 may be formed with a predetermined pattern. For example, it may be an embossed pattern that forms irregularities on the second surface. (Not shown)

A predetermined pattern formed on the second surface of the glass scatters the incident light and scatters the light reflected from the solar cell or back sheet and re-injects it.

In other words, by a predetermined pattern, the incident light is scattered, the light reflected from the solar cell is prevented from going out immediately, and the reflected light going out is scattered and re-entered, thereby increasing the power generation of the solar cell. .

Here, when a predetermined pattern is formed on the first side, the pattern becomes vulnerable to contamination such as dust and may be formed only on the second side, but the pattern is not limited to this.

The glass 1101 may be low iron tempered glass, but is not limited thereto.

Here, the glass 1101 may be manufactured using a thermal strengthening method, but when manufactured using a chemical strengthening method, the glass 1101 of 1 mm or less may be formed.

The solar cell can be manufactured by connecting half-cut cells in series through a cell string 1103 to correspond to the size of a conventional louver blade.

For example, in the case of a P type solar cell, like a regular battery, the side on which light is incident forms a minus (-) pole and the opposite side forms a plus (+) pole. The solar cells are arranged in a row. In order to connect plus (+) and minus (-), the ribbon (electrode wire) attached to the top (- side) of the solar cell is attached to the back (+ side) of the solar cell next to it and connected in series to form a solar cell. A solar cell (solar cell string) is formed by forming a cell string, which is a line in which solar cells are connected to each other.

In addition, the encapsulants 1102 and 1104 surround the solar cell and are located between the glass 1101 and the back sheet 1105, thereby mitigating the direct shock transmitted to the solar cell and preventing moisture or contaminants from entering the solar cell. It plays a role in preventing direct influence.

In addition, the back sheet 1105, like the glass 1101, serves to protect the solar cell from the external environment.

FIG. 8 is a diagram showing a state in which a plurality of solar cell module units of FIG. 2 are electrically connected.

Referring to FIG. 8, the plurality of solar cell module units 10 are electrically connected to a solar cell panel unit 100 having a pair of terminal units 111 provided at both ends, respectively, and each terminal unit 111. It includes a pair of first electrode terminals 270 and a pair of first caps 200 mounted on the solar cell panel unit 100 to surround each first electrode terminal 270.

More specifically, the solar cell panel unit 100 includes a solar cell panel 110 having a pair of terminal parts 111 provided at both ends of the solar cell panel 110, and a blade frame on which the solar cell panel is mounted. Includes (120).

In addition, the solar cell panel unit 100 further includes a bypass diode 160 that is electrically connected to the solar cell panel 110.

Here, the bypass diode 160 may be a device for preventing power loss due to shadows generated on the solar cell panel 110.

The solar cell module unit 10 includes a first solar cell module unit 11 and a second solar cell module unit 12.

The first solar cell module unit 11 includes a solar cell panel unit 100 having a pair of terminal units 111 provided at both ends, and a pair of solar cell module units 100 to be electrically connected to each terminal unit 111. It includes one electrode terminal 270 and a pair of first caps 200 mounted on the solar cell panel unit 100 to surround each first electrode terminal 270.

In addition, the second solar cell module unit 12 includes a solar cell panel unit 100 having a pair of terminal units 111 provided at both ends, and a pair of solar cell module units 100 to be electrically connected to each terminal unit 111. It includes a first electrode terminal 270 and a pair of first caps 200 mounted on the solar cell panel unit 100 to surround each first electrode terminal 270.

Here, in the pair of terminal portions of the first solar cell module portion 11, the first terminal 111a of the first end (left end in FIG. 8) has a (-) polarity, and the first terminal 111a of the first end (left end in FIG. 8) has a (-) polarity. The second terminal 111b (at the right end) has a (+) polarity.

At this time, in the pair of terminal portions of the second solar cell module portion 12, the first terminal 111a of the first end (left end in FIG. 8) has a (+) polarity, and the first terminal 111a of the second end (Fig. The second terminal 111b (right end in 8) has a (-) polarity.

In other words, if the first terminal 111a of the first solar cell module unit 11 has either (+) or (-) polarity, the first terminal 111a of the second solar cell module unit 12 ) is arranged to have the remaining polarity of (+) or (-).

The first solar cell module unit 11 and the second solar cell module unit 12 may be arranged alternately with each other along the longitudinal direction (vertical direction) of the inner frame 500.

That is, when the plurality of solar cell module units 10 are respectively arranged along the longitudinal direction (vertical direction) of the inner frame 500, the terminal parts of the two solar cell module units adjacent to each other along the vertical direction have different polarities. It can be arranged to have

Accordingly, each terminal portion of the first solar cell module portion 11 and the second solar cell module portion 12 is arranged to have different polarities along the vertical direction, so that they can be connected in series through the connector portion 70. .

Figure 9 is a perspective view and a side cross-sectional view of the blade frame 120 on which the solar cell panel 110 is mounted according to an embodiment of the present invention.

Referring to FIG. 9, the blade frame 120 extends along the longitudinal direction (horizontal direction) and includes a base frame 121 for supporting the solar cell panel 110.

The base frame 121 has a plurality of first partition members 122 that partition the interior of the base frame so that first to third hollow chambers 1211, 1212, and 1213 each having a predetermined space therein are formed. .

In addition, the blade frame 120 includes a fixing groove 130 into which the solar cell panel 110 is inserted and fixed.

The fixing groove 130 may be formed so that both ends in the longitudinal direction (horizontal direction) are open so that the solar cell panel 110 can be slidably inserted through the side of the fixing groove 130, and has a cross-sectional shape. This is provided in an approximately 'ㄷ' shape so that the solar cell panel 110 can be inserted into the fixing groove 130 and assembled.

The fixing groove portion 130 may be formed to protrude from both ends of the base frame 121 in the vertical direction, that is, from the upper and lower sides of the base frame, respectively.

In addition, at the upper end of the blade frame 120, first and second grooves 123 and 124, which are recessed inward by a predetermined amount from the front side of the base frame 121 toward the rear side, are provided at a predetermined distance along the vertical direction. You can.

Here, the first and second groove portions 123 and 124 may be recessed inward along the longitudinal direction (horizontal direction).

At the lower end of the blade frame 120, first and second protrusions 125 and 126, which are inserted (seated) into the first and second grooves 123 and 124 of other blade frames, may be provided at a predetermined distance along the vertical direction. there is.

The first and second protrusions 125 and 126 may be provided to protrude outward from the base frame along the longitudinal direction (horizontal direction).

Here, the first and second protrusions 125 and 126 may be provided to correspond to the positions of the first and second grooves 123 and 124 of other adjacent blade frames along the vertical direction.

In addition, the base frame 121 in the area of the second hollow chamber 1212 includes a bypass diode insertion portion 140 into which a bypass diode is inserted and disposed.

The bypass diode insertion portion 140 may be provided to be recessed inward to a predetermined depth along the longitudinal direction (horizontal direction) from the front side to the back side.

A bypass diode element 160 may be disposed in the bypass diode insertion portion 140 and electrically connected to the solar cell panel 110.

In particular, bypass diode connection portions 112 to which bypass diode elements are electrically connected may be provided at both ends of the solar cell panel 110, respectively.

In addition, the blade frame 120 includes a first mounting groove portion 150 for mounting the blade gasket 170, which is provided to shield a portion of the fixing groove portion of another blade frame disposed adjacent to the lower portion.

The first mounting groove 150 may be provided with a predetermined groove so that the blade gasket 170 extending along the longitudinal direction (horizontal direction) can be inserted and mounted at one end (lower end) of the blade frame 120. there is.

In particular, the blade gasket 170 has one side mounted on the first mounting groove 150 and the other side contacts the upper fixing groove of another blade frame disposed adjacent to the lower part, and may be provided to cover the fixing groove. there is.

The blade gasket 170 suppresses the amount of ventilation between each solar cell module part, thereby improving the airtightness of the solar cell louver assembly.

When the solar cell panel 110 is mounted on the fixing groove 130 of the blade frame 120, at least a portion of the solar cell panel 110 protrudes further in the longitudinal direction than both ends of the blade frame 120. Can be installed.

That is, the length of the solar cell panel 110 in the longitudinal direction may be longer than the length of the blade frame 120 in the longitudinal direction.

In particular, some areas where the first and second terminals 111a and 111b of the solar cell panel 110 and the bypass diode connection portion 112 are provided may be provided to protrude outward from both ends of the blade frame 120. there is.

Figure 10 is a perspective view and a side cross-sectional view showing the blade frame 120 arranged along the vertical direction according to an embodiment of the present invention.

Referring to FIG. 10, when two blade frames 120 (120a, 120b) are arranged adjacent to each other along the vertical direction, for convenience of explanation, the blade frame disposed at the top is referred to as the first blade frame 120a. , The blade frame disposed at the bottom will be described and referred to as the second blade frame 120b.

The first and second protrusions 125 and 126 of the first blade frame 120a are provided to be inserted into the first and second grooves 123 and 124 of the second blade frame 120b, respectively, so that the first and second blade frames (120a, 120b) Each base frame 121 may be positioned on approximately the same plane along the vertical direction.

Figure 11 is a diagram showing the first cap 200 provided with the first electrode terminal 270 according to an embodiment of the present invention.

Referring to FIGS. 2 and 11 , the pair of first caps 200 may be mounted on both ends of the solar cell panel unit 100, respectively.

Specifically, each first cap 200 has a first surface 201 facing the solar cell panel unit 100 and a second surface 202 opposite to the first surface.

The first cap 200 includes a first protruding member 210 that protrudes from the first surface 201 by a predetermined height and is inserted into at least a partial area of the second hollow chamber 1212.

In addition, the first cap 200 includes a second protruding member 211 that protrudes from the first surface 201 by a predetermined height and is inserted into at least a partial area of the bypass diode insertion portion 140. .

Additionally, the first cap 200 includes a third protruding member 212 that protrudes from the first surface 201 by a predetermined height and is inserted into at least a partial area of the second hollow chamber 1212.

Here, the first protruding member 210 may be inserted into the upper part of the second hollow chamber 1212, and the third protruding members 210 and 212 may be inserted into the lower part of the second hollow chamber 1212.

That is, it can be inserted into the second hollow chamber 1212 with the bypass diode insertion part 140 in between.

The first to third protruding members 210, 211, and 212 are respectively inserted into a partial area of the second hollow chamber 1212, the bypass diode insertion portion 140, and the remaining partial area of the second hollow chamber 1212 to form a first cap ( 200) may be fixed to the solar cell panel unit 100.

Additionally, the first surface 201 of the first cap 200 includes a first insertion groove 220 into which at least a portion of the solar cell panel 110 mounted on the fixing groove 130 is inserted.

The first insertion groove 220 may be provided to be recessed inward from the first surface 201 toward the second surface 202.

In addition, the upper end of the first cap 200 will be provided with third and fourth grooves 231 and 232 respectively recessed inward to correspond to the first and second grooves 123 and 124 at the upper end of the blade frame 120. You can.

In addition, at the lower end of the first cap 200, third and fourth protrusions 233 and 234 are provided, respectively, protruding outward to correspond to the first and second protrusions 125 and 126 at the lower end of the blade frame 120. You can.

The first surface 201 of the first cap 200 is formed to have a substantially flat surface, so that when at least a portion of the solar cell panel is mounted in the first insertion groove 220, the first surface is of the blade frame. It may be arranged to shield the open side.

When the first cap 200 is mounted on the solar cell panel unit 100, either the first terminal or the second terminal of the solar cell panel and the bypass diode terminal unit are connected to the first insertion groove portion 220. Each can be located on the inner side.

In addition, a first binding portion 240 provided to be fastened to the second cap may be provided on the second surface 202 of the first cap 200.

The first binding portion 240 has a predetermined first hollow portion ( 241) can be provided.

The first hollow portion 241 may be opened on one side so that the second electrode terminal 310 provided in the second cap 30 is inserted into the inside.

That is, the first hollow portion may be opened toward the one end 240a (lower side) of the first binding portion 240.

Additionally, first binding grooves 250 that are predeterminedly recessed inward from both sides of the first cap 200 may be provided on both sides of the first binding portion 240 in the width direction.

In addition, the first cap 200 includes a fourth protruding member 260 that protrudes outward from the side at a predetermined angle.

The fourth protruding member 260 may be provided at the lower end of the first cap 200 and may be provided to protrude outward from the rear side.

The first connection portion 272 and the second connection portion 273 of the first electrode terminal 270 are positioned to be exposed to the space inside the fixing groove 220, and the plurality of first electrode rods 271 are connected to the first binding portion. It is positioned to be exposed to the space inside the first hollow portion 241 of (240).

Accordingly, when the first cap 200 is respectively mounted on the solar cell panel unit 100, the terminal unit 111 and the bypass diode connection unit 112 of the solar cell panel are inserted into the fixing groove unit 220, and the 1 The first and second connection parts located in the fixing groove 220 of the cap 200 are electrically connected to the terminal part 111 and the bypass diode connection part 112 of the solar cell panel, respectively.

Meanwhile, Figure 11 is a diagram showing the second cap 30 according to an embodiment of the present invention.

Referring to FIG. 11, the second cap 30 of the present invention accommodates a second electrode terminal 310 and a second electrode terminal 310 to be electrically connected to the first electrode terminal 270. 1 A plurality of caps 200 may be provided to be mounted.

The second cap 30 has a first surface 31 facing the first cap 200 and a second surface 32 opposite to the first surface.

In addition, the second cap 30 includes a first mounting part 320 having a predetermined space inside so that the first cap 200 can be slidably inserted and mounted.

The first mounting portion 320 may be formed so that both ends in the width direction (w) protrude from the first surface by a predetermined height so as to surround at least a portion of the first cap, and both ends in the longitudinal direction have openings. It can be (open).

The first mounting portion 320 includes a pair of first binding protrusions 321 that are respectively slide-inserted into the first binding grooves 250 of the first cap 200 and fixed thereto.

When the first cap 200 is slide-inserted along the longitudinal direction of the second cap 30, the first mounting portion 320 is one end of the first binding portion 240 of the first cap 200. A stepped portion 323 that protrudes outward from the first surface by a predetermined height may be provided so that 240a is caught and fixed.

Additionally, the first mounting portion 320 includes a first binding member 325 that is inserted into and fixed to the first hollow portion 241 of the first cap 200.

The first binding member 325 may be formed to protrude toward the upper side on the first step portion 323, and a predetermined through passage may be formed on the inside.

In particular, at least a portion of the second electrode terminal 310 may be positioned to be exposed to the outside through a predetermined through path of the first binding member 325.

In addition, when the first binding member 325 is inserted and fixed in the first hollow portion 241, a first O-ring 327 to improve the fixing force may be fitted into the first binding member 325. there is.

On the side of the first mounting part 320, a fitting groove 329 is provided so that the fourth protruding member 260 of the first cap is inserted and fixed, and is provided in a shape corresponding to a position corresponding to the fourth protruding member 260. It can be.

In addition, the second cap 30 is mounted on the frame portion 50 and includes a second mounting portion 340 on which the connector portion 70 is mounted.

The second mounting part 340 includes a rotating member 350 having a predetermined second hollow part 341 on the inside.

The pivoting member 350 has a second step portion 351 protruding from the second surface 32 side and a pair of first fixing pieces 352 that further protrude from the second step portion.

The second hollow portion of the second mounting portion 340 may be formed on the inside between the pair of first fixing pieces 352, and the third electrode terminal may be provided to be inserted into the second hollow portion.

In particular, at least a portion of the second electrode terminal may be located within the second hollow portion 341 of the second mounting portion.

Specifically, the plurality of second electrode rods 311 of the second electrode terminal 310 are positioned to be exposed to the inner space of the second hollow portion 341 of the second mounting portion, and the third connection portion 312 is connected to the first binding portion. It may be positioned to pass through a predetermined hollow part of the member 325 and be exposed to the outside.

Accordingly, when the first cap 200 is mounted on the second cap, the first binding member 325 of the second cap is inserted into at least a partial area of the first hollow portion 241 of the first cap 200. Then, the plurality of first electrode rods 271 located in the first hollow portion 241 and the third connection portion 312 exposed to the outside through the first binding member 325 can be electrically connected.

Meanwhile, Figure 12 is a diagram showing a fixing member 400 according to an embodiment of the present invention.

Referring to FIG. 12, the second cap 30 includes a fixing member 400 mounted on the second mounting portion 340 of the second cap 30 to rotatably support the second cap 30. Includes.

The fixing member 400 may be inserted into the frame through-hole 510 of the inner frame 500, which will be described later, to rotatably support the second cap 30.

The fixing member 400 is inserted into the frame through-hole 510 and serves to enable rotation and reduce friction when the second cap 30 rotates.

For example, if the fixing member 400 is not mounted, the second cap 30 made of plastic may be easily worn due to friction with the frame through-hole of the inner frame made of aluminum.

The fixing member 400 has a third step portion 410 inserted and fixed into the frame through hole 510 to correspond to the shape of the frame through hole 510 of the inner frame 500, and the second cap 30 ) A first through hole 420 penetrating the central part of the third step may be provided so that the rotating member 350 of ) can be inserted and mounted.

The third step portion 410 of the fixing member 400 may be mounted so as to pass through the frame through-hole 510 of the inner frame 500 and be exposed to the outside.

At this time, the second mounting portion 340 of the second cap 30 can be mounted on the fixing member 400, and the first fixing piece 352 passes through the first through hole 420 to the inner frame ( It is exposed to the space between 500) and the outer frame 600.

That is, the pair of first fixing pieces 352 may be located in the space between the inner frame and the outer frame.

Additionally, the fixing member 400 can surround and support at least a portion of the second step portion 351 and the first fixing piece 352.

Meanwhile, Figures 13 and 14 are diagrams to explain the frame unit 50 according to an embodiment of the present invention.

Referring to FIGS. 13 and 14, the frame portion 50 includes an inner frame 500 on which a plurality of second caps 30 are rotatably mounted, respectively, along the longitudinal direction, and an inner frame 500 surrounding the inner frame 500. Includes an outer frame 600.

The frame unit 50 has a predetermined space, and within the predetermined space, a plurality of solar cell module units 10 are respectively arranged along the longitudinal direction and can be rotatably mounted.

More specifically, the inner frame 500 extends along the longitudinal direction (vertical direction) and includes a plurality of frame through-holes 510 arranged at regular intervals along the longitudinal direction.

The inner frame 500 may be provided at both ends of the solar cell module unit 10, respectively.

Here, the inner frame 500 may be provided with a pair of load bars (not shown) provided on both sides with the frame through-hole 510 in between to rotate the solar cell module unit 10, and a connector A plurality of protruding bar fixing holes (not shown) provided in the portion 70 so that the pair of protruding bars 739 are respectively inserted and fixed may be provided at positions corresponding to the pair of protruding bars 739. .

The inner frame 500 may be provided with a pair of first fitting grooves 520 extending along the longitudinal direction.

The pair of first fitting grooves 520 may be provided on both ends of the inner frame 500 in the width direction, respectively.

The outer frame 600 extends along the longitudinal direction and includes a pair of side frames 610 provided to surround the side surfaces of the inner frame and both ends along the longitudinal direction of the pair of side frames 610. It includes upper and lower frames 620 and 630 respectively connected to each other.

Each of the side frames 610 may be provided with a first insertion protrusion 611 that is inserted into the first fitting groove 520, respectively.

Each of the side frames 610 may form a predetermined space 601 so that the connector portion 70 can be placed therein when the inner frame 500 is mounted.

In addition, the outer frame 600 includes an assembly member 650 for connecting the side frame and the upper frame or the side frame and the lower frame.

The assembly member 650 is provided to have an approximately 'L' shape, so that at least part of the area is inserted into the inside of the upper frame or lower frame, and the remaining part of the area is inserted into the inside of the side frame, so that the upper frame and the side frame or lower frame are inserted into the assembly member 650. and side frames can be connected.

In addition, the outer frame 600 includes a pair of guide members 660 mounted on the upper and lower frames 620 and 630, respectively, and a pair of guide slit members mounted on each guide member 660 ( 670).

The upper and lower frames 620 and 630 include a pair of second insertion protrusions 640 into which the guide members 660 are respectively fitted.

The pair of guide members 660 has a second fitting groove portion 661 into which the pair of second insertion protrusions 640 are respectively inserted, and a third fitting groove portion 661 into which the guide slit member 670 is inserted and fitted. Includes a groove portion 662.

The first and second fitting grooves 520 and 661 may be slidably inserted and coupled to the first and second insertion protrusions 620 and 640, respectively.

Each of the guide slit members 670 may be provided with third and fourth grooves 671 and 672 having shapes corresponding to the first and second grooves of the blade frame, respectively.

The guide slit member 670 is positioned at the upper and lower ends of the solar cell panel unit 100 located at the uppermost end in a state in which a plurality of solar cell module units 10 are mounted on the frame unit 50. Each may be provided to contact the lower end of the battery panel unit 100.

In particular, the first and second protrusions 125 and 126 of the blade frame may be inserted and seated in the third and fourth grooves of the guide slit member mounted on the lower frame.

In addition, the outer frame 600 may be provided with an external connector 680 that outputs electricity output through the connector portion 70 to the outside.

For example, the external connector 680 may be mounted and fixed to a side frame, and may be provided to be electrically connected to the connector portion 70.

Figure 15 is a perspective view showing the connector portion 70 according to an embodiment of the present invention.

Referring to FIG. 15, the pair of mounting members 730 have a pair of second through holes 731 into which the pair of first fixing pieces 352 of the pivoting member are respectively inserted and mounted.

In addition, it is provided between the pair of second through holes 731 and each includes a second binding member 732 provided to be inserted into the second hollow part 341 of the second mounting part 340.

The second binding member 732 may have a predetermined through passage formed on the inside, so that the fourth connection portion 711 of the third electrode terminal 710 is exposed to the outside through the through passage.

The second binding member 732 may be provided to be connected to the connecting member 720 surrounding the fifth connecting portion 712.

The connecting member 720 may electrically connect the fifth connection portion of the third electrode terminal to electrically connect two adjacent solar cell module units 10.

In addition, when the second binding member 732 is inserted and fixed in the second hollow portion 341, a second O-ring 734 to improve fixing force may be fitted into the second binding member 732. there is.

When the connector parts 70 are respectively mounted on the second cap, the second binding member 732 is inserted and fixed into the second hollow part 341 of the second cap, and the second binding member 732 is fixed to the second hollow part 341 of the second cap. A plurality of second electrode rods 311 of the two electrode terminal 310 and the fourth connection portion 711 may be electrically connected.

Additionally, the connector portion 70 includes a pair of protruding bars 739 provided to rotate the solar cell module portion 10 at a predetermined angle.

The pair of protruding bars 739 are provided to protrude outward from the mounting member 730, and may be positioned at a predetermined distance apart from each other to face each other with the second binding member 732 in between.

Figure 16 is a view showing a state in which the solar cell module portion is mounted on the second cap and the connector portion is mounted on the second cap according to an embodiment of the present invention, and Figure 17 is a solar cell louver according to an embodiment of the present invention. This drawing is shown to explain the state in which the assembly is connected in series.

Referring to FIG. 16, the second cap 30 may be rotated at a predetermined angle while mounted on the inner frame 50.

In the above state, the solar cell module unit 10 can be mounted on the second cap 30 by sliding it toward the downward side.

That is, the first electrode terminal 270 and the second electrode terminal 310 may be provided to be inserted along the longitudinal direction of the inner frame.

With the solar cell module part mounted on the second cap as described above, the connector part 70 may be mounted on the rotating member of the second cap.

The connector portion 70 of the present invention is configured to connect each solar cell module portion 10 in series, and the arrangement of the connector portion 70 for connecting the solar cell module portions 10 in series is as follows. .

Referring to FIGS. 1, 13, and 16, for convenience of explanation, when the first solar cell module portion 11 and the second solar cell module portion 12 are alternately arranged sequentially along the vertical direction of the frame portion, The first solar cell module portion 11 disposed below the second solar cell module portion 12 may be referred to as a third solar cell module portion, and the second solar cell module portion disposed below the third solar cell module portion may be referred to as a third solar cell module portion. It may be referred to as the fourth solar cell module unit.

At this time, the connection between the right end side and the left end side of the first to fourth solar cell module parts will be described based on the direction from the top to the bottom.

For example, in order for the plurality of solar cell module units 10 and 10' to be electrically connected to each other in series, the connector unit 70 is connected to the first solar cell module unit 11 and the second solar cell module unit ( 12) It is placed at the right end to electrically connect the right end of the first and second solar cell module parts.

At this time, the connector unit 70 is located at the left end of the second solar cell module unit 12 and the other first solar cell module unit (third solar cell module unit) 11' located below the second solar cell module unit. is disposed to electrically connect the left ends of the second solar cell module unit 12 and the third solar cell module unit 11'.

In addition, the connector portion 70 is disposed on the right ends of the third solar cell module portion 11' and the fourth solar cell module portion 12' to electrically connect the right ends of the third and fourth solar cell module portions. Connect.

By installing the connector unit by repeating the above configuration, a plurality of solar cell module units can be electrically connected in series.

That is, the connector portion 70 may be connected to each other at the left end and the right end, respectively, crossing each other for serial connection.

Since this connection can be made in the space between the inner frame and the outer frame, there is an effect that the wires are not exposed to the outside.

Additionally, the louver assembly of the present invention can be assembled in the same way as a conventional louver window is assembled, making assembly easier.

In addition, it has the advantage of acting as a louver window and simultaneously producing electricity from solar panels connected in series.

1: Louver assembly
10: Solar cell module part
30: second cap
50: frame part
70: connector part

Claims (14)

A solar cell panel unit having a pair of terminal portions provided at each end, a pair of first electrode terminals for electrical connection to each terminal portion, and a solar cell panel portion mounted on the solar cell panel portion to surround each first electrode terminal. A plurality of solar cell module units including a pair of first caps;
a plurality of second caps including second electrode terminals to be electrically connected to the first electrode terminals;
a frame portion on which a plurality of second caps are respectively rotatably mounted along the longitudinal direction;
A solar cell louver assembly including a connector portion including a pair of third electrode terminals for electrically connecting the second electrode terminals of two adjacent solar cell module portions when a plurality of solar cell module portions are mounted in the frame portion. . According to claim 1,
A solar cell provided such that when the first cap is mounted on the second cap, the second electrode terminal is in contact with the first electrode terminal, and when the connector portion is mounted on the second cap, the third electrode terminal is in contact with the second electrode terminal. Louver assembly. According to claim 2,
One of the first and second electrode terminals is provided to have a space into which the other terminal is inserted, and when the first cap is mounted on the second cap, one of the first and second electrode terminals is provided to have a space into which the other terminal is inserted. A solar cell louver assembly that is inserted into the interior of the terminal. According to claim 3,
The first electrode terminal includes a plurality of first electrode rods forming a space into which the second electrode terminal is inserted, and at least one first electrode rod is bent one or more times,
The second electrode terminal is provided to contact the bent part of the first electrode rod or to be inserted into the space between the bent parts of the first electrode rod. According to claim 4,
The solar cell panel unit includes a solar cell panel provided with a pair of terminal portions provided at each end and a bypass diode connection portion at both ends to which bypass diode elements are electrically connected,
The first electrode terminal is a solar cell louver assembly including a first connection portion for electrical connection with the terminal portion of the solar cell panel and a second connection portion for electrical connection with the bypass diode connection portion. According to claim 5,
A solar cell louver assembly, wherein the plurality of first electrode rods, the first connection portion, and the second connection portion of the first electrode terminal are integrally formed. According to claim 2,
One of the second and third electrode terminals is provided to have a space into which the other terminal is inserted, and when the connector portion is mounted on the second cap, one of the second and third electrode terminals is connected to the other terminal. Solar cell louver assembly inserted into the interior. According to claim 7,
The second electrode terminal includes a plurality of second electrode rods forming a space into which the third electrode terminal is inserted, and at least one second electrode rod is bent one or more times,
The third electrode terminal is provided to contact the bent part of the second electrode rod or to be inserted into the space between the bent parts of the second electrode rod. According to claim 8,
The frame unit includes an inner frame on which a plurality of second caps are rotatably mounted, respectively, along the longitudinal direction, and an outer frame surrounding the inner frame,
When the second cap is mounted on the inner frame, the plurality of second electrode rods are provided so that at least a portion of the area is exposed to the space between the inner frame and the outer frame. According to claim 2,
The connector portion includes a connecting member surrounding each third electrode terminal; and a pair of mounting members connected to the connecting member, each positioned on the end side of the third electrode terminal to expose the third electrode terminal to the outside, and provided to be mounted on the second cap. A solar cell louver assembly. delete According to claim 6,
Each first cap has a first surface facing the solar cell panel unit and a second surface in an opposite direction to the first surface, and a first insertion groove into which at least a portion of the solar cell panel is inserted on the first surface. It has, on the second side, a first fastening portion provided to be fastened to the second cap,
The first binding portion has a predetermined first hollow portion provided therein so that at least a partial region of the first electrode terminal and at least a partial region of the second electrode terminal are respectively accommodated and electrically connected,
The first and second connection portions of the first electrode terminal are provided to be located within the first insertion groove, so that when the terminal portion and bypass diode connection portion of the solar cell panel are inserted into the first insertion groove, the first and second connection portions are respectively It is electrically connected to the terminal part of the solar cell panel and the bypass diode connection part,
A solar cell louver assembly, wherein the plurality of first electrode rods of the first electrode terminal are positioned to be exposed to the inner space of the first hollow portion of the first binding portion. According to claim 12,
Each second cap has a first mounting portion having a predetermined space on the inside so that the first cap can be slidably inserted and mounted, and a second mounting portion provided to have a connector portion mounted in the opposite direction of the first mounting portion,
The second electrode terminal extends from a plurality of second electrode rods and has a third connection portion for electrical connection to the first electrode rod of the first electrode terminal,
The first mounting portion includes a first binding member provided to be inserted into and fixed to the first hollow portion of the first cap,
The third connection portion is positioned to be exposed to the outside through a predetermined through passage inside the first binding member,
The second mounting portion has a predetermined second hollow portion on the inside,
A solar cell louver assembly, wherein the plurality of second electrode rods are positioned to be exposed to the inner space of the second hollow portion. delete

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