KR102289890B1 - Integrated inverter and solar cell module including the same - Google Patents

Abstract

A solar cell module according to an embodiment of the present invention is an integrated inverter used in a solar cell module including a solar cell panel, and includes a terminal connected to the solar cell panel, and a DC-AC inverter electrically connected to the terminal. a circuit unit including an inverter member; and a accommodating part for accommodating the circuit part. The circuit part and the accommodating part are coupled in a sliding manner.

Description

Integrated inverter and solar cell module including same

The present invention relates to an integrated inverter and a solar cell module including the same, and more particularly, to an integrated inverter with an improved structure and a solar cell module including the same.

Recently, as existing energy resources such as oil and coal are expected to be depleted, interest in alternative energy to replace them is increasing. Among them, a solar cell is spotlighted as a next-generation battery that converts solar energy into electrical energy.

A solar cell panel with solar cells is connected to a junction box, and the junction box is connected to a DC-AC inverter through a DC output cable drawn from the junction box. More specifically, the DC voltage or DC current delivered by the output cable of the (+) terminal and the output cable of the (-) terminal drawn from the junction box is converted into AC voltage or AC current by the DC-AC inverter. The AC voltage or AC current generated by the DC-AC inverter is again connected to another solar cell module by an AC output cable, or is connected to a power grid, a power system, or the like.

At this time, since the junction box and the DC-AC inverter must be manufactured and installed separately from each other (for example, each must be separately manufactured and installed in a separate case), when applied to a solar cell module, the installation space increases and installation time this increases Moreover, since a DC output cable (ie, two output cables) must be located between the junction box and the DC-AC inverter to connect them, additional installation space and installation time are required. In particular, the output cable has a large volume and weight, so it is difficult to install. Accordingly, the productivity of the installation process of the junction box and the DC-AC inverter is very low. In addition, the two output cables connecting the junction box and the DC-AC inverter may sway or deviate from them during transportation and use, thus avoiding various problems such as colliding with the solar panel and damaging the solar panel. can cause

An object of the present invention is to provide an integrated inverter and solar cell module capable of simplifying the structure and simplifying the bonding process.

A solar cell module according to an embodiment of the present invention is an integrated inverter used in a solar cell module including a solar cell panel, and includes a terminal connected to the solar cell panel, and a DC-AC inverter electrically connected to the terminal. a circuit unit including an inverter member; and a accommodating part for accommodating the circuit part. The circuit part and the accommodating part are coupled in a sliding manner.

The integrated inverter of the solar cell module according to the present embodiment is formed by integrating or integrating a bypass diode that provides a terminal connected to the ribbon and/or a bypass path, and an inverter member that converts direct current into alternating current. By integrating them and forming them, the installation process can be simplified and the structure can be simplified. And by connecting the terminal and/or the bypass diode and the inverter member in a circuit pattern, it is not necessary to use an output cable (ie, a direct current output cable) for connecting them, thereby simplifying the structure and generating an output cable It can prevent damage to the solar panel.

In addition, the circuit part (or the fixed part to which the circuit part is fixed) can be inserted into the accommodating part or separated from the accommodating part through the open side of the accommodating part by a simple process of sliding. Accordingly, the circuit unit and the receiving unit can be fixed by a simple process, and processes such as repair, replacement, and inspection of the circuit unit can be simplified. Therefore, even if a failure occurs in the circuit part, the housing part and the like can be used as it is, thereby reducing the repair cost. In particular, when the accommodating part is made of metal to improve durability, the repair cost can be greatly reduced.

1 is a front perspective view illustrating a solar cell module including an integrated inverter according to an embodiment of the present invention.
FIG. 2 is a rear perspective view illustrating the solar cell module of FIG. 1 .
FIG. 3 is a cross-sectional view taken along line III-III of FIG. 1 .
4 is an exploded perspective view illustrating an enlarged portion A of FIG. 2 .
FIG. 5 is a cross-sectional view taken along line VV of FIG. 4 .
6 is a partial perspective view of an integrated inverter according to a modified example of the present invention.
7 is a perspective view illustrating a terminal applicable to the integrated inverter of the solar cell module shown in FIG. 1 and a ribbon connected thereto.
8A to 8F are perspective views illustrating an assembly process of the solar cell module shown in FIG. 1 .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it goes without saying that the present invention is not limited to these embodiments and may be modified in various forms.

In the drawings, in order to clearly and briefly describe the present invention, the illustration of parts irrelevant to the description is omitted, and the same reference numerals are used for the same or extremely similar parts throughout the specification. In addition, in the drawings, the thickness, the width, etc. are enlarged or reduced in order to make the description more clear, and the thickness, the width, etc. of the present invention are not limited to the bars shown in the drawings.

And, when a certain part "includes" another part throughout the specification, other parts are not excluded unless otherwise stated, and other parts may be further included. Also, when a part of a layer, film, region, plate, etc. is said to be “on” another part, this includes not only the case where the other part is “directly on” but also the case where another part is located in the middle. When a part, such as a layer, film, region, plate, etc., is "directly above" another part, it means that no other part is located in the middle.

Hereinafter, a solar cell module and a photovoltaic device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front perspective view of a solar cell module including an integrated inverter according to an embodiment of the present invention, and FIG. 2 is a rear perspective view of the solar cell module of FIG. 1 . And FIG. 3 is a cross-sectional view taken along line III-III of FIG. 1 .

1 to 3 , the solar cell module 100 according to the present embodiment includes a solar cell panel 10 including a solar cell 12 and an integrated inverter connected to the solar cell panel 10 ( 30). In this case, the integrated inverter 30 includes a circuit part (reference numeral 300 in FIG. 4, hereinafter the same) and a accommodating part for accommodating the circuit part 300 (reference numeral 491 in FIG. 4, hereinafter the same), and the circuit part 300 ) and the receiving portion 491 are coupled to each other in a sliding manner. In addition, the solar cell module 100 may include a frame 20 for fixing the outer portion of the solar cell panel 10 . A sealing member (not shown) for sealing and bonding the solar cell panel 10 and the frame 20 may be positioned.

The solar panel 10 includes at least one solar cell 12 . In addition, the solar cell panel 10 includes a sealing layer 14 for enclosing and sealing the solar cell 12 , and a front substrate 16 positioned on the front surface of the solar cell 12 on one surface of the sealing layer 14 , and , may include a rear substrate 18 positioned on the rear surface of the solar cell 12 on the other surface of the sealing layer 14 .

For example, the solar cell 12 , a semiconductor substrate (eg, a single crystal semiconductor substrate, more specifically, a single crystal silicon wafer), and first and second semiconductor substrates formed on or on the semiconductor substrate and having opposite conductivity types. It may include a second conductivity type region, and first and second electrodes respectively connected thereto. Here, the semiconductor substrate may have a low doping concentration of p-type or n-type, and one of the first and second conductivity-type regions may have p-type and the other may have n-type. In addition, the first or second conductivity type region may be a doped region formed by doping a part of a semiconductor substrate with a dopant, or a semiconductor layer formed separately on the semiconductor substrate and doped with a dopant. In addition, a plurality of solar cells 12 are provided, and the first electrode of the solar cell 12 and the second electrode of the adjacent solar cell 12 are connected by a ribbon 122 or the like, so that the plurality of solar cells 12 are connected to each other. ) may form a solar cell string constituting one row. As for the structure of the solar cell 12 and the connection structure of the plurality of solar cells 12, various known structures may be applied.

As described above, in this embodiment, a silicon single crystal semiconductor solar cell is used as the solar cell 12 . As such, a silicon single crystal semiconductor solar cell based on a semiconductor substrate formed of a single crystal semiconductor having high crystallinity and few defects may have excellent electrical characteristics. However, the present invention is not limited thereto, and solar cells having various structures, such as a thin film solar cell, a dye-sensitized solar cell, a tandem solar cell, and a compound semiconductor solar cell, may be used as the solar cell 12 . In addition, although it has been illustrated that a plurality of solar cells 12 are provided, it is also possible to provide only one solar cell 12 .

The sealing layer 14 includes a first sealing layer 14a located between the solar cell 12 and the front substrate 16 , and a first sealing layer located between the solar cell 12 and the rear substrate 18 . It may include a second sealing layer (14b) bonded to (14b). The sealing layer 14 encloses and seals the solar cell 12 to block moisture or oxygen that may adversely affect the solar cell 12 . Then, the parts constituting the solar cell module 100 (ie, the front substrate 16 , the solar cell 12 , and the rear substrate 18 ) are chemically bonded. The rear substrate 18, the second sealing layer 14b, the solar cell 12 or string of solar cells, the first sealing layer 14a and the front substrate 16 are sequentially laminated and then heat and/or pressure are applied to them. It is possible to integrate them by performing a lamination process or the like for bonding.

As the first sealing layer 14a and the second sealing layer 14b, ethylene vinyl acetate copolymer resin (EVA), polyvinyl butyral, silicon resin, ester-based resin, olefin-based resin, etc. may be used. In this case, the first sealing layer 14a and the second sealing layer 14b may be made of the same material or different materials. However, the present invention is not limited thereto. Therefore, the first and second sealing layers 14a and 14b may use various other materials and may be formed by methods other than lamination.

The front substrate 16 is positioned on the first sealing layer 14a to constitute the front surface of the solar cell panel 10 . The front substrate 16 may be made of a material having strength to protect the solar cell 12 from external impact and the like and light transmittance to transmit light such as sunlight. For example, the front substrate 16 may be formed of a glass substrate or the like. In this case, the front substrate 16 may be formed of a tempered glass substrate to improve strength, and various modifications are possible, such as additionally including various materials capable of improving various other properties. Alternatively, the front substrate 16 may be a sheet or film composed of a resin or the like. That is, the present invention is not limited to the material of the front substrate 16 , and the front substrate 16 may be formed of various materials.

The rear substrate 18 is positioned on the second sealing layer 14b to protect the solar cell 12 from the rear surface of the solar cell 12 , and may function as a waterproof, insulating and UV-blocking layer.

The rear substrate 18 may have a strength to protect the solar cell 12 from external impact, etc., and may have a property of transmitting or reflecting light according to a desired structure of the solar cell panel 10 . For example, in a structure in which light is incident through the rear substrate 18 , the rear substrate 18 may have a light-transmitting material, and in a structure in which light is reflected through the rear substrate 18 , the rear substrate 18 is It may be composed of a non-transmissive material or a reflective material. For example, the rear substrate 18 may be formed in the form of a substrate such as glass, or may be formed in the form of a film or a sheet. For example, the rear substrate 18 may be a Tedlar/PET/Tedlar (TPT) type, or may be made of a polyvinylidene fluoride (PVDF) resin formed on at least one surface of polyethylene terephthalate (PET). . Polyvinylidene fluoride is a polymer having a structure of (CH ₂ CF ₂ )n. Since it has a double fluorine molecular structure, it has excellent mechanical properties, weather resistance, and UV resistance. The present invention is not limited to the material of the back substrate 18 or the like.

As described above, in order to stably fix the solar cell panel 10 composed of a plurality of layers, the frame 20 to which the outer portion of the solar cell panel 10 is fixed may be positioned. Although the figure shows that the entire outer part of the solar cell panel 10 is fixed to the frame 20 , the present invention is not limited thereto. Accordingly, various modifications are possible, such as the frame 20 fixing only some edges of the solar cell panel 10 .

In this embodiment, the frame 20 may include a panel inserting part 22 into which at least a portion of the solar cell panel 10 is inserted, and an extension part 24 extending outwardly from the panel inserting part 22 . can

More specifically, the panel insert 22 includes a front portion 222 located on the front side of the solar cell panel 10 , a side portion 224 located on the side surface of the solar cell panel 10 , and the solar panel 10 . The rear portions 226 located on the rear surface may be connected to each other so that the outer portion of the solar cell panel 10 is located therein. For example, the panel inserting part 22 may have a "U" shape or a "U" shape in which the edge of the solar cell panel 10 is positioned inside by being bent twice. However, the present invention is not limited thereto, and any one or part of the front portion 222 , the side portion 224 , and the rear portion 226 may not be located. In addition, various modifications are possible.

The extension 24 extending rearwardly from the panel insert 22 extends rearward from the panel insert 22 and is formed parallel to the side portion 224 (or coplanar with the side portion 224 ). a first portion 242 (formed thereon) and a second portion 244 extending bent from the first portion 242 and spaced apart from the rear or rear portion 226 of the solar panel 12 . can do. The second portion 244 may be formed parallel to or inclined with the rear or rear portion 226 of the solar panel 12 . As a result, the extension part 24 may have an “L” shape or an “L” cross-sectional shape that is bent once and forms a space between it and the rear part 226 .

Such an extension 24 increases the strength of the frame 20 and is connected to a part fixed to a mount, a support, or a bottom surface, etc. A hole 24a to which a fastening member (not shown) is fastened may be formed. Since the fastening member is fastened to the second part 244 spaced apart from the solar cell panel 10 in this way, it is possible to prevent the solar cell panel 10 from being damaged when the solar cell module 100 is installed using the fastening member. can

The second portion 244 may be formed to have an area equal to or larger than that of the rear portion 226 (ie, to have a width equal to or greater than that of the rear portion 226 ) to stably fix the fastening member or the like. In addition, various known structures may be used as the structure of the fastening member. The present invention is not limited thereto, and the extension 24 may have various other shapes.

The frame 20 may be fixed to the solar cell panel 10 in various ways. For example, a portion constituting the outer portion of the solar cell panel 10 is formed as a portion having elasticity (eg, a tape having elasticity), and the portion having elasticity is used to insert the solar cell panel into the panel insertion portion 22 . (10) can be inserted. However, the present invention is not limited thereto, and various modifications are possible, such as assembling and combining parts constituting the frame 20 at the outer portion of the solar cell panel 10 .

And in this embodiment, the integrated inverter 30 connected to the solar cell 12 of the solar panel 10 may be provided. For example, the integrated inverter 30 may be located on the rear surface of the solar cell panel 10 .

The integrated inverter 30 according to this embodiment integrates at least a part of a conventional junction box and at least a part of the inverter, and is named as a junction box integrated inverter, a bypass diode integrated inverter, an integrated junction box, an inverter integrated junction box, and the like. could be This integrated inverter 30 will be described in more detail with reference to FIGS. 4 to 7 along with FIGS. 1 to 3 .

4 is an exploded perspective view showing an enlarged portion A of FIG. 2 , and FIG. 5 is a cross-sectional view taken along the line V-V of FIG. 4 .

4 and 5 , the integrated inverter 30 according to the present embodiment includes a solar cell (reference numeral 12 in FIG. 3 , the same hereinafter) or a terminal 31 connected to the solar panel 10 and a direct current - a circuit portion 300 comprising an inverter member 35 comprising an alternating current inverter 352 . And the circuit unit 300 includes a bypass diode 33 electrically connecting them between the terminal 31 and the DC-AC inverter 352 , the terminal 31 , the bypass diode 33 and the inverter member 35 . It may further include a circuit board 37 on which is located.

The circuit unit 300 is positioned inside the accommodating part 491 , and the circuit part 300 and the accommodating part 491 are coupled by a sliding method. More specifically, the circuit unit 300 is slid into the receiving portion 491 while being fixed to the fixing portion 310 to be coupled to the receiving portion 491 . When the circuit unit 300 is fixed to the fixing unit 310 and slides as described above, it is possible to minimize the impact that may occur in the circuit unit 300 on which various electronic components are mounted or mounted during sliding, and the like, and the fixing of the circuit unit 300 . Stability can be improved. However, the present invention is not limited thereto, and various modifications are possible, such as not having the fixing part 310 and only the circuit part 300 sliding into the receiving part 491 .

In the present embodiment, at least one side surface (a surface that intersects or inclines with the solar cell panel 10) of the receiving portion 491 is opened to constitute an open side surface 491a, and the open side 491a of the receiving portion 491 is opened. ) through which the fixing part 310 and the circuit part 300 fixed thereto are inserted and slid. In this case, the fixing part 310 may include a covering member 312 formed of a surface that crosses or slopes with the solar cell panel 10 so as to block the open side of the receiving part 491 . Accordingly, after the circuit part 300 is slid and inserted into the accommodating part 491, the accommodating part 491 and the covering member 312 have side surfaces surrounding the circuit part 300 as a whole so that the circuit part 300 is positioned. It constitutes a single housing having an internal space. Therefore, since it is not necessary to assemble, mount, or fix a separate configuration for blocking the open side 491a of the receiving portion 491 , the structure and the coupling process of the integrated inverter 30 can be simplified.

This integrated inverter 30 will be described in more detail.

In this embodiment, the terminal 31 and/or the bypass diode 33 and the inverter member 35 are integrally formed.

Here, the term “integrated” may include any state recognized as one part, article, object or member when fixed to the solar panel 10 and/or frame 20 during the installation process or after the installation process. . For example, being integrated may mean that they are located together in the same housing or case and are integrated by the same case, or are fixed by being fitted or attached to the same member and integrated by the same member. It may mean that it is formed together on the same member to constitute a part of the same member, or it may mean that it is wrapped or fixed together by the same member. Conversely, it may be difficult to see that things connected by a separate output cable or the like are integrated. At this time, the terminal 31 , the bypass diode 33 , and the inverter member 35 may be non-detachably integrated with each other, or may be detachably integrated with each other so that they can be easily detached during repair or replacement.

In the integrated inverter 30 according to the present embodiment, the terminal 31 , the bypass diode 33 and the inverter member 35 are formed together on a circuit board 37 having a circuit pattern (or circuit, wiring). Accordingly, it can be seen that the terminal 31 , the bypass diode 33 , and the inverter member 35 are integrated by the circuit board 37 . In addition, the potting member 372 may be positioned while covering or surrounding the circuit board 37 . Accordingly, it can be seen that the bypass diode 33 and the inverter member 35 are integrated by the potting member 372 . . Also, the circuit board 37 on which the terminal 31 , the bypass diode 33 , and the inverter member 35 are formed may be located in one fixing part 310 , and accordingly, the terminal 31 , the bypass The pass diode 33 and the inverter member 35 may be considered to be integrated by the same fixing part 310 . In addition, the circuit board 37 on which the terminal 31 , the bypass diode 33 , and the inverter member 35 are formed may be located inside the same accommodation part 491 . Accordingly, the terminal 31 , the bypass diode 33 , and the inverter member 35 may be considered to be integrated by the same accommodating part 491 .

In this embodiment, the terminal 31 , the bypass diode 33 , and the inverter member 35 are connected to the same circuit board 37 , the same potting member 372 , the same fixing part 310 , and the same receiving part 491 . It is exemplified that it is integrated by In more detail, the terminal 31, the bypass diode 33, and the inverter member 35 are positioned on the same circuit board 37, and the potting member 372 is the bypass diode 33, the inverter member ( 35 ) and the circuit board 37 , the terminal 31 , the inverter member 33 , the circuit board 37 , and the potting member 372 are integrated to form the circuit part 300 . The circuit unit 300 may be fixed to the fixing unit 310 and fixed inside the receiving unit 491 . Accordingly, the terminal 31 , the bypass diode 33 , and the inverter member 35 may be more firmly integrated. However, the present invention is not limited thereto, and it is also possible to integrate them into a simple structure using at least one of various methods for integrating them. In the present embodiment, the terminal 31, the bypass diode 33, and the inverter member 35 are integrated together, but the present invention is not limited thereto. Therefore, since the bypass diode 33 is not provided, only the terminal 31 and the inverter member 36 may be integrated, and only the bypass diode 33 and the inverter member 35 may be integrated. Various modifications are possible.

The accommodating part 491 provides a space in which the circuit part 300 is located and may have various structures and shapes that can be stably fixed to the solar cell panel 10 . At this time, the accommodating part 491 is provided with a space in which the circuit part 300 and the fixing part 310 are accommodated, and has at least one open side 491a to put the circuit part 300 and the fixing part 310 or Make it easy to remove.

For example, in this embodiment, the receiving part 491 has a bottom surface 4942 and a side surface 4944 to provide an internal space 494 in which the internal space is located, and the bottom from the upper end of the internal space 494 . abutment flange 496 extending parallel or obliquely to face 4942 . At this time, at least one open side surface 491a is located on the side surface 4944 , and the joint flange 496 is also not provided in the portion where the open side surface 491a is located. Although the figure illustrates that one open side 491a is positioned, the present invention is not limited thereto. Accordingly, two or more open side surfaces 491a may be located, and various other modifications are possible. And in the drawings, the open side 491a is illustrated as being provided on each side as a whole, but the present invention is not limited thereto. Since the open side 491a is sufficient as an opening into which the circuit unit 300 and the fixing unit 310 can be inserted, it may be partially formed on each side 4944 . The joint flange 496 may also be formed in a portion where the open side 491a is located, as long as it does not interfere with the insertion of the circuit part 300 and the fixing part 310 .

In the drawings and description, the side facing the solar cell panel 10 in the receiving portion 491 (more precisely, the side facing the solar panel 10 in the inner space 494 or the bonding flange 496 is located side) is opened. That is, in the receiving portion 491 , there is no surface parallel to the bottom surface 4942 and adjacent to the solar cell panel 10 . In this way, the surface of the accommodating part 491 opened to face the solar cell panel 10 is covered by the solar cell panel 10 .

For example, when the bottom surface 4942 is a rectangle, it has a side surface 4944 extending from the four edges constituting the rectangle and a joint flange 496 extending therefrom, so that the open side surface 491a and the sun in the cuboid are provided. A surface opposite to the battery panel 10 is opened.

In the drawing, the bottom surface 4942 has four straight lines and may have a shape having rounded corners at a portion where two adjacent straight lines meet. For example, the bottom surface 4942 may have an approximate rectangular shape, but portions corresponding to four corners of the rectangular shape may have a rounded shape. Side 4944 is formed continuously from some edges of bottom surface 4942 and may extend to intersect (eg, orthogonal to) bottom surface 4942 . Accordingly, the side surface 4944 may be formed to include a number of less than four planes corresponding to the edges of a straight line less than four, and a rounded curved surface positioned between two adjacent planes. According to this, it is possible to sufficiently secure the internal space, and it is possible to prevent the user from being injured by the sharp edge. However, the present invention is not limited thereto, and the shape of the bottom surface 4942 and the side surface 4944 may be variously modified.

The joint flange 496 may be formed to extend by being bent from the side surface 4944 . The bonding flange 496 provides an area to which the first bonding member 493 is applied so that the receiving portion 491 can be fixed to the solar cell panel 10 side by the first bonding member 493 . At this time, the bonding flange 496 is bent from the entire end of the side surface 4944 and extends outward, providing a portion that can be bonded to the solar cell panel 10 by the first bonding member 493 . . The abutment flange 496 can be configured with a flat face parallel to the bottom face 4942 and/or can be configured with a flat face perpendicular to the side face 4944 . Then, the first bonding member 493 may be stably applied on the bonding flange 496 , and may be stably bonded to the solar cell panel 10 . However, the present invention is not limited thereto.

In this embodiment, the abutment flange 496 may extend entirely from the end of the side side 4944 excluding the open side side 491a. Here, the joint flange 496 may be formed to be formed as a flat surface to be positioned on the same plane. Then, the bonding flange 496 can be stably bonded to the solar cell panel 10 side by the first bonding member 493 applied to the bonding flange 496 , whereby the airtightness of the inside of the receiving portion 491 is can be kept high. In this case, the first bonding member 493 may be uniformly applied by making the overall width of the bonding flange 496 uniform, thereby further improving bonding stability with the solar cell panel 10 . However, the present invention is not limited thereto, and the width of the joint flange 496 may be variously changed.

This receiving portion 491 is fixed to the solar cell panel 10 in a state in which the bonding flange 496 is adjacent to the solar cell panel 10 side. That is, the bottom surface 4942 of the receiving part 491 is located far from the solar cell panel 10 and the side surface 4944 is extended toward the solar panel 10 so that the bottom surface 4942 is at least the side surface 4944 . It may be spaced apart from the solar cell panel 10 by a height. Accordingly, the bottom surface 4942 and the side surface 4944 of the accommodating part 491 are positioned to constitute the external shape or the outer surface of the integrated inverter 30, and of the accommodating part 491 facing the solar cell panel 10. The face (ie, the face on which the bonding flange 496 is located) is fixed covered by the solar panel 10 . Accordingly, in a state in which the bonding flange 496 is fixed to the solar cell panel 10 side, the circuit portion 300 and the fixing portion 310 in the inner space 494 are connected to the receiving portion 491 and the solar cell panel 10 . ) is stably fixed between

In this way, if the opposite side to the bottom surface 4942 is not formed in the accommodating part 491 , and this surface is covered by the solar cell panel 10 , it is not necessary to provide a separate cover part covering the corresponding surface. Accordingly, the structure of the integrated inverter 30 can be simplified, the thickness of the integrated inverter 30 can be reduced as much as the cover portion, and the cost can be reduced by reducing the amount of material used therefor. However, the present invention is not limited thereto, and it is also possible to separately provide a cover for covering the receiving portion 491 .

An opening 494a formed in a portion corresponding to the terminal 31 may be formed on the bottom surface 4942 of the receiving portion 491 . This opening 494a may be covered or covered by the cover portion 494b. The opening 494a may expose the part where the terminal 31 is located to the outside so that the ribbon 122 can be easily fixed in a state where the integrated inverter 30 or the receiving part 491 is fixed to the solar panel 10 side. The cover portion 494b is formed to close the opening 494a after fixing the ribbon 122 to the terminal 31 .

The opening 494a may have a size and shape to completely expose the portion where the terminal 31 is formed, and the cover part 494b may have a size and shape to completely block the opening 494a. For example, the opening 494a has a size smaller than the area of the receiving portion 491 (the area of the bottom surface 4942 ) so that the receiving portion 491 has sufficient strength, and the portion where the terminal 31 is located. It may have a larger size than the portion where the terminal 31 is located so as to expose the . In addition, the cover portion 494b has a larger size than the opening 494a so that the edge of the cover portion 494b overlaps the bottom surface 4942 around the opening 494a to be easily bonded thereto. The cover part 494b may be formed of various materials capable of blocking the opening 494a, and may be made of the same material as the accommodating part 491 or may be made of a different material.

The adhesive member 494c is positioned between the opening 494a and the cover part 494b to improve airtightness, sealing, and waterproofing properties of the accommodating part 491 . In more detail, the adhesive member 494c may be formed to have a closed space therein while surrounding the opening 494a of the receiving portion 491 when viewed in a plan view. Thereby, it is possible to effectively partition and separate the space between the solar cell panel 10 and the accommodating part 491 and the external space of the integrated inverter 30 while stably positioning the cover part 494b on the bottom surface 4942 . there is. Thereby, it is possible to seal the accommodating portion 491 having the opening 494a.

As an example, the adhesive member 494c may have a shape such as a circular shape or a polygonal shape when viewed in a plan view. In the drawing, it is illustrated that the opening 494a is formed in a substantially rectangular shape, and the adhesive member 494c is formed in an approximately rectangular shape. However, the present invention is not limited thereto, and the adhesive member 494c may have various structures and shapes that block communication between the interior and external spaces of the receiving portion 491 while blocking the cover portion 494b.

In the present embodiment, since an opening 494a for connecting the ribbon 122 and the terminal 31 is provided in the integrated inverter 30 , the adhesive member 494c is formed in this way to improve airtightness characteristics. On the other hand, the conventional inverter is connected to the junction box and does not have an opening used for connection with the solar cell 12 or the ribbon 122 .

As the adhesive member 494c, various materials having excellent adhesive properties and sealing properties may be used. For example, a sealant or the like may be used as the adhesive member 494c. However, the present invention is not limited thereto. Accordingly, since the adhesive member 494c is formed of a structure formed of resin, metal, or the like, various modifications such as bonding the bottom surface 4942 and the cover portion 494c by heat or the like are possible. In addition, it is also possible to more firmly fix the bottom surface 4942 and the cover part 494c together with the adhesive member 494c by a separate structure (eg, screw coupling, latch structure, packing structure) or the like. Various other variations are possible.

The above-described accommodating portion 491 may include various materials capable of maintaining an external shape or an outer surface and protecting various parts, articles, members, etc. located therein. For example, the accommodating part 491 may be made of various materials such as a resin, a metal, a surface-treated metal (or a coating-treated metal). When the accommodating part 491 is formed of resin, insulating properties can be improved and cost can be reduced. In addition, when the accommodating part 491 includes a metal, structural stability can be increased and the accommodating part 491 can be used for grounding. In this case, when the receiving part 491 is made of a surface-treated metal (or a coated metal), a conductive material layer may be located inside, and a surface-treated layer having insulating properties while surrounding it may be located outside. Accordingly, corrosion resistance and appearance can be improved by the surface treatment layer including the insulating material, and the conductive material layer located therein can be applied to grounding or the like.

For example, the receiving part 491 may be made of an anodized metal (eg, anodized aluminum). Then, the accommodating part 491 is provided with a conductive material layer including aluminum and a surface treatment layer including aluminum oxide. In addition, by adjusting the color of the receiving part 491 during surface treatment (eg, anodizing treatment), the appearance may be further improved. For example, the color of the accommodating part 491 may be adjusted so that the accommodating part 491 has a color such as black, brown, or silver.

At this time, in the present embodiment, the bonding member 493 may be positioned between the bonding flange 496 and the solar cell panel 10 (eg, located so as to be in contact with them) to bond them. The bonding member 493 may be positioned to correspond to a portion in which the bonding flange 496 is formed and may have substantially the same or similar shape as the bonding flange 492 . The bonding member 493 joins and seals between the bonding flange 496 of the receiving portion 491 and the solar cell panel 10, preventing impurities, contaminants, etc. from entering from the outside, and improving sealing and waterproofing characteristics. can be improved Various materials having bonding and/or sealing properties for the bonding member 493 may be used. For example, a sealant may be used. However, the present invention is not limited thereto.

According to the present embodiment, even when repair, replacement, etc. of the circuit unit 300 is required, the circuit unit 300 is inserted through the open side 491a while the receiving unit 491 is mounted on the solar cell panel 10 . Or you can separate it. Accordingly, the accommodating part 491 is non-detachable to the solar cell panel 10 and it is not necessary to separate the accommodating part 491 even for repair or replacement of the circuit part 300 . Then, it is possible to prevent inconvenience that may occur when the receiving part 491 is removed and then re-installed.

However, the present invention is not limited thereto, and it is also possible to separate the receiving part 491 from the solar cell panel 100 by cutting the bonding member 493 if necessary. That is, when the bonding flange 496 is positioned on the same plane as in this embodiment, a cutting mechanism (eg, a knife, etc.) is inserted between the bonding flange 496 and the solar panel 10 and the bonding flange ( The bonding flange 496 may be separated into the solar cell panel 10 by cutting the bonding member 493 by moving one turn along the 496 . In this case, a separate guide portion or the like may be installed between the bonding flange 496 and the solar cell panel 10 to further prevent the solar cell panel 10 from being damaged by the cutting mechanism.

The bonding member 493 may be formed by continuously connecting to a portion where the bonding flange 496 is formed when viewed in a plan view. Accordingly, the receiving part 491 can be stably fixed to the solar cell panel 10 . However, the present invention is not limited thereto, and the bonding member 493 may have various structures and shapes.

The fixing part 310 surrounds the circuit part 300 together with the receiving part 491 by blocking the open side 491a of the accommodating part 491 with the role of allowing the circuit part 300 to be stably fixed (at least, Surrounding the side surface of the circuit part 300) constitutes one housing for accommodating.

The fixing part 310 includes a covering member 312 that closes the open side 491a. The covering member 312 may have a shape corresponding to the open side 312 . That is, formed by the edges of the rear surface of the solar cell panel 10 constituting the open side 491a, and the bottom surface 4942 and the side surfaces 4944 of the receiving portion 491 located on the open side 491a side. It may have a size, shape, etc. that can cover all of the internal space. Such a covering member 312 is fixed to the receiving portion 491 so as to block the open side 491a of the receiving portion 491, thereby sealing the open side (491a). Thereby, it is possible to improve the stability of fixing the circuit unit 300 located inside the accommodating part 491 and the like, and to improve the airtightness of the accommodating part 491 inside.

The receiving portion 491 and the covering member 312 may be fixed and coupled to each other by various methods. For example, the receiving portion 491 and the covering member 312 may be fixed by at least one of a screw coupling, an adhesive material, a sealing material, an adhesive tape, a packing member 495, and a latch structure.

That is, as shown in FIG. 4 , the covering member 312 is formed to protrude toward the receiving portion 491 and includes a bracket member 312a having a first through hole 312b, and the receiving portion 491 is the second A second through hole 491b may be included at a position corresponding to the first through hole 312b. Then, the covering member 312 and the accommodating part 491 may be coupled to each other by screw coupling for fastening the fastening member 68 such as a screw to the first through hole 312b and the second through hole 491b. A member such as a nut or a press-fitting nut may be further positioned to correspond to the first through hole 312b of the covering member 312 so that the screw connection can be made firmly.

In addition, a packing member 495 made of an elastic material such as rubber may be further positioned between the covering member 312 and the edge of the receiving part 491 . Accordingly, it is possible to improve sealing characteristics, waterproof characteristics, etc. of one housing that is positioned between the covering member 312 and the accommodating part 491 and constituted by the covering member 312 and the accommodating part 491 . The packing member 495 may be positioned to be separated from each of the accommodating part 491 and the covering member 312 , or may be positioned integrally by being joined to the accommodating part 491 , or bonded to the covering member 312 . and may be integrated and located. If the packing member 495 is located separately, it may be easy to replace the packing member 495 , and when the packing member 495 is integrated with the receiving part 491 or the covering member 312 , It is possible to simplify the structure and simplify the process of coupling the accommodating part 491 and the covering member 312 .

In this embodiment, the packing member 495 has the same or similar shape along the edge of the bottom surface 4942, the side surface 4944, and the joining flange 496 of the receiving portion 491 where the open side 491a is located. Thus, it is possible to minimize the area of the packing member 495 to improve sealing properties while minimizing material cost. However, the present invention is not limited thereto, and the packing member 495 may have various shapes.

4 illustrates that the receiving portion 491 and the covering member 312 are coupled by the screw coupling and the packing member 495 . However, in addition to this, a sealing member, an adhesive member, a double-sided adhesive tape, a latch structure, etc. may be additionally applied, and a sealing member, an adhesive member, a double-sided adhesive tape, a latch structure, etc. may be applied by replacing the screw coupling and/or packing member 495 . Various structures can be applied.

In this embodiment, the covering member 312 constituting one housing together with the accommodating part 491 is connected to the outside of the solar cell module 100 (eg, another solar cell module 100 or a power grid). structure may be included. That is, a through hole 49b through which one AC output cable 38 for transmitting the AC current (or AC voltage, current power, AC power) generated by the integrated inverter 30 to the covering member 312 passes through (49b) can be formed. Thereby, the AC output cable 38 is drawn out through the covering member 312 .

That is, in the present embodiment, a through hole 49b for the AC output cable 38 is formed in the housing in which the terminal 31 connected to the solar cell 12 is located. This is because the terminal 31 and/or the bypass diode 33 and the inverter member 35 are integrated. Conventionally, an opening, an opened surface, or a through-hole for connection with a solar cell is formed in a case of a junction box, and an opening, an opened surface, or a through-hole for an AC output cable is formed in a case of the inverter in which the inverter member is located. Thus, they cannot be formed in the same housing. On the other hand, in the present embodiment, the structure (eg, terminal 31 ) for connection with the solar cell panel 10 and the output cable 38 providing an AC voltage to the outside are integrated by the circuit board 37 . can be formed.

In this embodiment, the output cable of the integrated converter 30 in which the terminal 31 connected to the ribbon 122 and/or the bypass diode 33 is located is configured as an AC output cable 38 . Accordingly, one AC output cable 38 may be led out through the through hole 49b. In general, the AC output cable 38 may include three conductors having a three-phase voltage (current), and one AC output cable 38 includes three conductors. Three conductors constituting one AC output cable 38 may be combined into one and pass through one through hole 49b. Thereby, the structure can be simplified. However, the present invention is not limited thereto, and various modifications are possible, such as drawing out three conductive wires through different through-holes 49b.

The through hole 49b may be formed at a position where an external circuit connection can be easily made. For example, in this embodiment, the through hole 49b is located far from the terminal 31 so that the voltage provided from the solar cell panel 10 to the terminal 31 is bypassed by the diode 33 and the inverter member 35 . After sequentially passing through the AC output cable 38, it can be drawn out to the outside. Accordingly, the arrangement of the terminal 31 , the bypass diode 33 , and the inverter member 35 can be made efficiently.

In this embodiment, the output cable output from the integrated inverter 30 in which the terminal 31 connected to the ribbon 122 and/or the bypass diode 33 is located is composed of an AC output cable 38, and a DC output No cables are provided. This is because the terminal 31 and/or the bypass diode 33 and the inverter member 35 are integrated. Conventionally, since a DC voltage or a DC current is drawn from a junction box in which a terminal and a bypass are located, two DC output cables, a (+) output cable and a (-) output cable, exist.

In this embodiment, instead of the receiving portion 491 fixed to the solar cell panel 10, a through hole 49b is formed in the covering member 312 that can be easily separated from the receiving portion 491, so that the circuit portion 300 is When the fixed fixing part 310 is separated from the accommodating part 491 , the AC output cable 38 is also separated from the accommodating part 491 . Accordingly, if necessary, the replacement of the AC output cable 38 can be easily performed. However, the present invention is not limited thereto, and a through hole 49b is formed in the accommodating part 491 so that the AC output cable 38 may be drawn out through the accommodating part 491 .

In this embodiment, the fixing part 310 may include a bottom member 314 extending from the covering member 312 toward the inner space of the receiving part 491 to seat the circuit part 300 thereon. The bottom member 314 may have a flat plate shape having an area equal to or larger than that of the circuit unit 300 (more specifically, the circuit board 37 ) so that the circuit unit 300 can be positioned as a whole. However, the present invention is not limited thereto, and as long as the circuit unit 300 can be stably positioned, it is also possible to have a smaller area than the circuit unit 300 .

In this way, when the fixing part 310 is provided with the bottom member 314 and the circuit part 300 is seated thereon, the fixing stability of the circuit part 300 can be improved. However, the present invention is not limited thereto, and the fixing unit 310 does not include the bottom member 314 , and the circuit unit 300 may be fixed to the covering member 312 or the like by a bracket (not shown). Various other variations are possible.

As a structure for fixing the circuit unit 300 to the fixing unit 310 , various known structures may be used. That is, various structures such as screw coupling, sealing member, adhesive member, double-sided adhesive tape, and latch structure can be applied. At this time, in the present embodiment, the circuit unit 300 may be detachably fixed to the fixing unit 310 by various structures. Then, when replacement of the circuit part 300 is required, the circuit part 300 can be easily separated from or fastened to the fixing part 310 .

For example, in this embodiment, the bottom member 314 and the circuit part 300 are fixed by screw coupling using the press-fitting nuts 490h and 490i and the fastening members 62 and 64 .

That is, a first press-fitting nut (fem nut) 490h is positioned on the bottom member 314 , and a fastening hole 37h is provided in a portion corresponding to the first press-fitted nut 490h on the circuit board 37 or the circuit unit 300 . can be formed. More specifically, the first press-fitting nut 490h and the fastening hole 37h are respectively located on both sides of the terminal 31 to which the ribbon 122 is connected, so that the terminal 31 to which the ribbon 122 is connected is located. Since the bottom member 314 and the circuit board 37 are fastened to each other, a gap in this portion can be minimized. Accordingly, the ribbon 122 can be stably fastened to the terminal 31 .

The first press-fitting nut 490h may be fixed to the floor member 314 by a caulking process or the like. By fastening the first fastening member 62 to the first press-fitting nut 490h in a state where the fastening hole 37h of the circuit board 37 is positioned on the first press-fitting nut 490h, the circuit part 300 is fixed to the fixing part. It can be fixed to (310). The floor member 314 and the circuit part 300 can be firmly fixed by the first fastening member 62 , and the circuit part 300 can be easily separated into the floor member 314 by loosening the first fastening member 62 . can

In addition, the second press-in nut 490i may be positioned on an edge of the bottom member 314 opposite to the edge on which the first press-in nut 490h is positioned. In addition, a fastening hole 37i may be formed in the circuit board 37 or the circuit unit 300 to correspond to the second press-fitting nut 490i.

The second press-fitting nut 490i may be fixed to the floor member 314 by a caulking process or the like. It may have a shape protruding from the bottom member 314 toward the circuit board 37 . By fastening the second fastening member 64 to the second press-fitting nut 490i in a state where the fastening hole 37i of the circuit board 37 is positioned on the second press-fitting nut 490i, the circuit part 300 is fixed to the fixing part. It can be fixed to (310). The bottom member 314 and the circuit part 300 can be firmly fixed by the second fastening member 64 by the second fastening member 64 , and the circuit part 300 can be secured when the second fastening member 64 is loosened. It can be easily separated by the bottom member 314 .

In the present embodiment, the floor member 314 extends from the middle portion of the covering member 312 (that is, in the covering member 312 , it is located at a location spaced apart from the bottom surface adjacent to the solar cell panel 10 by a predetermined distance. extended) and spaced apart from the solar cell panel 10 . Accordingly, when the fixing part 310 on which the circuit part 300 is seated slides into the receiving part 491, the floor member 314 having a relatively large area rubs against the solar panel 10 to prevent sliding. can be minimized However, the present invention is not limited thereto, and the bottom member 314 is positioned on the bottom side of the covering member 312 so that the bottom member 314 is in contact with the solar cell panel 10 , and various other structures are possible. do.

At an edge of the floor member 314 opposite to the covering member 312 , a support member 316 for supporting the floor member 314 is provided so that the floor member 314 can be spaced apart from the solar cell panel 10 by a predetermined distance. can be located The support member 316 may have a certain height and may have various shapes capable of serving as a spacer supporting the floor member 314 .

In this way, the support member 312 may allow the floor member 314 to be spaced apart from the solar cell panel 10 by a predetermined distance from the opposite side of the covering member 312 so that the floor member 314 may have a balance. . By preventing the bottom member 314 from contacting the solar cell panel 10 by the support member 312 , the area in which the fixing part 310 contacts the solar cell panel 10 may be minimized.

However, the present invention is not limited thereto, and it is also possible that the support member 316 is not provided. In addition, other structures capable of balancing the floor member 314 may be applied instead of the support member 316 .

As a modification, as shown in FIG. 6 , the guide member 316a may be positioned in the receiving part 419 . 6 is a partial perspective view of an integrated inverter according to a modified example of the present invention. Although the covering member (reference numeral 312 in FIGS. 4 and 5 , hereinafter the same) of the fixing part 310 is not shown in FIG. 6 for clarity, the fixing part 310 may include the covering member 312 . .

Referring to FIG. 6 , in this modified example, a rail-shaped guide member 316a extending long along the sliding direction may be included on the inner surface of the side surface 4944 of the receiving part 419 . The guide member 316a may include two parts covering both surfaces of the fixing part 310 with an internal space as thick as the fixing part 310 can be inserted thereinto. Then, the fixing part 310 can be easily fixed by inserting the fixing part 310 into the inner space of the guide member 316a and pushing it. In addition, the bottom member 314 of the fixing part 310 may be stably fixed at a desired position.

Although the rail shape has been exemplified in the drawings and description, it goes without saying that the guide member 316a of various structures and shapes capable of fixing the position of the fixing part 310 may be applied. And when the fixing part 310 is not provided, the circuit part 300 or the circuit board 37 may be fixed to the guide member 316a.

It will be described again with reference to FIGS. 4 and 5 . The covering member 312 , the bottom member 314 , and the supporting member 316 of the fixing part 310 may be formed as an integral structure made of the same material. For example, the fixing part 310 may be entirely made of an insulating material formed by injection. Then, the fixing part 310 may sufficiently secure the insulation distance of the circuit part 300 .

However, the present invention is not limited thereto, and the fixing part 310 may include a conductive material (eg, a metal material). When the fixing part 310 includes a conductive material, the structural stability of the fixing part 310 may be improved to more firmly fix the circuit part 300 . In addition, when the bottom member 314 includes a conductive material, a grounding structure may be formed by the first and second fastening members 62 and 64 . Then, the circuit unit 300 may be grounded to improve electrical stability. In addition, after the covering member 312 , the bottom member 314 , and the supporting member 316 of the fixing part 310 are formed separately from each other, they are bonded to each other, and it is also possible to have different materials. In addition, various modifications are possible.

The circuit unit 300 fixed to the fixing unit 310 includes a terminal 31 , a bypass diode 33 , an inverter member 35 , and the like. In this embodiment, the terminal 31 , the bypass diode 33 and the inverter member 35 are positioned together on the circuit board 37 so that they are integrated by the circuit board 37 . Accordingly, in the present embodiment, the terminal 31 to which the ribbon 122 is connected and the bypass diode 33 are positioned on the circuit board 37 unlike the prior art.

The circuit board 37 may be a board on which various circuit patterns (wirings, terminals, various components for interconnection of the circuit board 37, etc.) are formed. Various structures may be used as the circuit board 37 , and as an example, a printed circuit board may be used. The figure illustrates that the terminal 31 , the bypass diode 33 , the inverter member 35 , and the like are all formed on one circuit board 37 to simplify the structure. However, the present invention is not limited thereto, and a plurality of circuit boards 37 are provided, and the plurality of circuit boards 37 are different circuit boards (eg, flexible printed circuit boards (FPCBs), It is also possible to be connected by a connector, etc. Various other modifications are possible.

In this embodiment, the terminal 31 and/or the bypass diode 33 are positioned on the circuit board 37 . Accordingly, the terminal and the bypass diode are located in the junction box and are different from the prior art in that they are not formed on the circuit board. As such, when the terminal 31 and/or the bypass diode 33 is formed on the circuit board 37 , the terminal 31 and the bypass diode 33 are connected by the circuit pattern of the circuit board 37 , The bypass diode 33 and the inverter member 35 are connected by a circuit pattern of the circuit board 37 to simplify the connection structure. In addition, heat dissipation characteristics can be improved by a metal plate (eg, a copper plate) constituting the circuit board 37 . In particular, the bypass diode 33 generates a lot of heat during driving. By forming the bypass diode 33 on the circuit board 37 , heat dissipation characteristics can be greatly improved.

The terminal 31 is connected to the ribbon 122 drawn out from the solar cell 12 and is electrically connected to the solar cell panel 10 to receive the DC voltage or DC current generated by the solar cell panel 10 , It is transmitted to the pass diode 33 and the inverter member 35 .

The terminal 31 to which the ribbon 122 is connected is located close to one side of the circuit board 37 (in particular, one edge adjacent to the ribbon 122 in the circuit board 37 and one edge adjacent to the opening 494a). Then, the ribbon 122 may be fixed to the terminal 31 through the opening 494a in a state in which the receiving part 491 is fixed to the solar cell panel 10 . This will be described in more detail later with reference to FIGS. 8A to 8F .

Referring to FIG. 7 , a plurality of terminals 31 may be formed to correspond to the ribbon 122 in one-to-one correspondence with the number of the ribbons 122 . In this embodiment, the terminal 31 may have a structure in which the ribbon 122 is detachable. For example, the terminal 31 of the present embodiment may include an upper portion 312 positioned above the ribbon 122 and a lower portion 314 positioned under the ribbon 122 . The upper portion 312 includes a first upper portion 312a that is fixed to the circuit board 37 at a position on one side of the ribbon 122 and extends from thereto to an upper portion of one side of the ribbon 122 , and It may include a second upper portion 312b fixed to the circuit board 37 at the other position and extending from the upper portion to the other upper portion of the ribbon 122 to be spaced apart from the first upper portion 312a. And the lower part 314 positioned below the first upper part 312a and the second upper part 312b is a part positioned inside the circuit board 37 rather than the first and second upper parts 312a and 312b. After being fixed to the circuit board 37 and extending upward therefrom, it may extend parallel to the ribbon 122 to cross the first and second upper portions 312a and 312b. In addition, a portion crossing the first and second upper portions 312a and 312b in the lower portion 314 may be formed such that the middle portion protrudes above the end portion. Then, the middle portion of the lower portion 314 is located closer to the first and second upper portions 312a and 312b than the ends.

In the lower part 314 of the terminal 31, the upper part 312 and the lower part ( After inserting the ribbon 122 between the 314 and removing the force pressing the lower portion 314 of the terminal 31, the lower portion 314 moves toward the upper portion 312 and the upper portion 312 (especially, A ribbon 122 is secured between the upper portion 312 ) and the lower portion 314 . When the ribbon 122 is separated, the ribbon 122 is removed in a state where the gap between the upper part 312 and the lower part 314 is widened by pressing the part fixed to the circuit board 37 in the lower part 314 downward. do.

The upper portion 312 and the lower portion 314 of the terminal 31 may be fixed to the circuit board 37 by various methods. For example, in the upper portion 312 and the lower portion 314 , latch structures (or locking portions) 312c and 314c are formed in portions fixed to the circuit board 37 , and positions corresponding to the circuit board 37 . A locking hole 37c may be formed therein. Accordingly, the terminal 31 can be easily detached by plugging or disassembling the latch structures 312c and 314c of the upper part 312 and the lower part 314 into the locking hole 37c of the circuit board 37 . . However, the present invention is not limited thereto, and the terminal 31 may be non-removably fixed on the circuit board 37 , and various modifications may be made.

As described above, since the terminal 31 has a structure in which the ribbon 122 can be detached, the ribbon 122 can be easily separated from the terminal 31 when repair or replacement is required, and when necessary, the ribbon 122 can be removed again. Easy to connect. However, the present invention is not limited thereto, and the terminal 122 may have various structures. Also, since the terminal 31 is formed of a metal pad or a soldering pad, the ribbon 122 may be joined to the terminal 31 by welding, soldering, or the like. Accordingly, the ribbon 122 may be non-detachable and fixed to the terminal 31 . Then, the structure of the terminal 31 can be simplified and cost can be reduced.

Referring back to FIGS. 4 and 5 , the bypass diode 33 connected to the terminal 31 by a circuit pattern extending from the terminal 31 is positioned on the circuit board 37 . The number of bypass diodes 33 is one less (n-1) than the number (n) of the terminals 31 . Each bypass diode 33 may be connected to the two terminals 31 between the two terminals 31 by a circuit pattern. When a portion that is covered by the solar panel 10 occurs or an area in which power generation does not occur occurs due to a failure, etc., the bypass diode 33 bypasses the portion and allows current to flow to protect the area. do. As the structure of the bypass diode 33 , various known structures may be applied.

In addition, the inverter member 35 connected to the bypass diode 33 by a circuit pattern extending from the bypass diode 33 is positioned on the circuit board 37 . The inverter member 35 serves to convert the direct current (or direct voltage) provided from the bypass diode 33 into an alternating current (or alternating voltage). The inverter member 35 includes a DC-AC inverter 352 for converting a DC current into an AC current, and a current sensor 354 for stably converting a DC current into an AC current, a capacitor 356, and a DC current. - A DC converter 358 and the like may be included. The current sensor 354 , the capacitor 356 , the DC-DC converter 358 , the DC-AC inverter 352 , etc. constituting the inverter member 352 is the terminal 31 and/or the bypass diode 33 . and the circuit board 37 or a circuit pattern formed thereon may be integrated.

The current sensor 354 is connected to a circuit pattern extended from the bypass diode 33 , and is connected to the capacitor 356 , the DC-DC converter 358 , the DC-AC inverter 352 , and the like by the circuit pattern. The current sensor 354 detects whether there is an abnormality or a problem in the current provided by the bypass diode 33 , and stops the operation of the capacitor 356 , the DC-DC converter 358 , the DC-AC inverter 352 , etc. plays a role In the present embodiment, the bypass diode 33 and the current sensor 354 may be connected by a circuit pattern formed on the circuit board 37 in the same housing 491 (or housing). By connecting the bypass diode 33 and the current sensor 354 as described above, a separate output cable is not required, so the structure can be simplified.

In addition, a capacitor 356 is connected to the current sensor 354 to store the DC current passing through the current sensor 354 and transmit a current of a constant voltage to the DC-DC converter 358 . The current sensor 354 and the capacitor 356 may also be connected by a circuit pattern formed on the circuit board 37 in the same housing 491 (or housing).

The current of the voltage equalized in the capacitor 356 may be transferred to the DC-DC converter 358 to be converted into another DC voltage of a predetermined level. In this embodiment, a plurality of DC-DC converters 358 may be provided. In this way, when a plurality of DC-DC converters 358 are provided, the thickness of each DC-DC converter 358 can be reduced as compared with a single DC-DC converter 358 , thereby reducing the integrated inverter 30 . The thickness of can be made smaller than the height of the extension (24). However, the present invention is not limited thereto, and it is also possible to include one DC-DC converter 358 .

The DC current or DC voltage passing through the DC-DC converter 358 may be transferred to the DC-AC inverter 352 to be converted into AC current or AC voltage. The AC current or AC voltage thus generated is transmitted to the outside by the AC output cable 38 connected to the DC-AC inverter 352 and passing through the through hole 49b of the covering member 312 (or housing). . For example, it is connected to another solar cell module 100 by the AC output cable 38 , or transmitted to a power grid, a power system, or the like.

Various structures known as the DC-AC inverter 352 , the current sensor 354 , the capacitor 356 , and the DC-DC converter 358 may be applied. In addition, various components such as a control member and a communication member may be positioned on the circuit board 37 .

The circuit board 37 , the bypass diode 33 , the inverter member 35 , and the like positioned on the circuit board 37 may be integrally surrounded by the potting member 372 .

In this embodiment, the potting member 372 may be formed to cover the bypass diode 33 , the inverter member 35 , the circuit board 37 , etc. while exposing the terminal 31 to which the ribbon 122 is connected. . Since the terminal 31 is a part to which the ribbon 122 is connected, when the terminal 31 is covered by the potting member 372, when the circuit part 300 needs to be replaced, it is connected to the terminal 31 because of the potting member 372. The ribbon 122 cannot be separated from the terminal 31 . Accordingly, only the portion exposed to the outside of the potting member 372 can be used by cutting the ribbon 122 in the middle, so that the length of the ribbon 122 is shortened and up to the terminal 31 of the circuit unit 300 to be replaced. can be difficult to reach. In addition, if the potting member 372 is also present in the terminal 31 of the circuit unit 300 to be newly replaced, it may be impossible to connect the ribbon 122 to the terminal 31 .

In consideration of this, in the present embodiment, the potting member 372 is formed to expose the terminal 31 . Accordingly, when the circuit unit 300 needs to be replaced, when the terminal 31 and the ribbon 122 are detachably fixed, the ribbon 122 is separated from the terminal 31 and the terminal 31 and the ribbon 122 are detachably fixed. ) is fixed by welding or the like, the ribbon 122 can be easily separated from the terminal 31 by tearing off the ribbon 122 from the terminal 31 . Thereby, it is possible to maintain the original length of the ribbon 122 . In addition, the ribbon 122 can be easily fixed or connected to the exposed terminal 31 of the newly replaced circuit unit 300 .

At this time, in the present embodiment, a first region in which the terminal 31 is positioned and a second region in which the bypass diode 33 , the inverter member 35 and the like are positioned may be partitioned. In addition, the potting member 372 may be positioned in the second region (or while covering the second region or covering the second region). At this time, as shown in FIG. 7 , a potting member 372 having fluidity by further comprising a separate partition member 60 dividing the first region and the second region flows during the process and is formed in the terminal 31 . It can also be physically prevented.

In the above description, referring to the potting member 372 covering an object such as the bypass diode 33 and the inverter member 35 includes covering the entire object or covering only a part of the object. That is, when there is a portion processed to have insulating characteristics in the bypass diode 33 , the inverter member 35 , or the like, only the portion excluding the portion may be covered. For example, only a portion corresponding to a circuit pattern such as a wiring exposed to the outside in the bypass diode 33 and the inverter member 35 may be partially covered. Accordingly, it can be considered that the bypass diode 33 , the inverter member 35 , etc. covering the circuit pattern are also potted by the potting member 372 . In addition, at least one of the DC-AC inverter 352 , the current sensor 354 , the capacitor 356 , and the DC-DC converter 358 constituting the inverter member 35 is covered by the potting member 372 for potting. and the inverter member 35 is potted by the potting member 372 even if other components are not covered by the potting member 372 . For example, according to an embodiment, the capacitor 356 may not be potted by the potting member 372 .

An insulating sheet 320 or the like may be positioned on the circuit unit 300 to improve insulation characteristics of the circuit unit 300 . The insulating sheet 320 may be placed on the circuit unit 300 as it is, or a part of the insulating sheet 320 may be fixed to the circuit unit 300 by means of a tape or an adhesive material. Various known materials may be applied as the insulating sheet 320 . In addition, although the term insulating sheet 320 is used, it may actually have a shape such as a case.

The integrated inverter 30 of the solar cell module 100 having the above structure includes a terminal 31 connected to the ribbon 122 and/or a bypass diode 33 providing a bypass path, and a direct current into an alternating current. The switching inverter member 35 is formed integrally or integrally. By being formed by integrating them, the installation process can be simplified and the structure can be simplified. And by connecting the bypass diode 33 and the inverter member 35 in a circuit pattern, it is not necessary to use an output cable (ie, a DC output cable) for connecting them, thereby simplifying the structure and connecting the output cable to the output cable. It is possible to prevent damage to the solar cell panel 10 that may occur.

On the other hand, in the related art, the junction box and the inverter are separately manufactured and fixed to each solar panel or frame, and then the (+) output cable and the (-) output cable of the junction box must be connected to the inverter. And the AC output cable of the inverter also exists. Then, the installation space becomes large, the installation time becomes long, and an impact is applied to the solar cell panel 10 during transportation or use by the three output cables, thereby causing damage or failure of the solar cell panel 10 .

In addition, assembly, replacement, inspection, repair, etc. of the integrated inverter 30 can be easily performed, which will be described in more detail with reference to FIGS. 8A to 8F . 8A to 8F are perspective views illustrating an assembly process of the solar cell module shown in FIG. 1 . In FIGS. 8A to 8F , the potting member 372 and the partition member 60 are omitted for simplicity and clarity, and the structure of the terminal 31 is simplified.

As shown in FIG. 8A , the fixing part 310 is prepared.

Next, as shown in FIG. 8B , after the circuit part 300 is positioned on the bottom member 314 of the fixing part 310 , the fixing part 310 and the circuit part 300 are fixed. In more detail, the first fastening member 62 is fastened in a state where the fastening hole (reference numeral 37h in FIG. 4) of the circuit board 37 is positioned on the first press-fitting nut (reference numeral 490h in FIG. 8A), The second fastening member 64 is fastened in a state where the fastening hole (reference numeral 47i in FIG. 4 ) of the circuit board 37 is positioned on the second press-fitting nut 490i. Accordingly, the fixing part 310 and the circuit part 300 are coupled by screw coupling. However, the present invention is not limited thereto, and the fixing unit 310 and the circuit unit 300 may be fixed to each other by various methods other than screw coupling.

At this time, the AC output cable 38 is extended to the outside through the through hole 49b.

Then, as shown in FIG. 8c , the fixing part 310 to which the circuit part 300 is fixed is slidably inserted into the receiving part 491 through the open side 491a. At this time, the opening 491a of the accommodating part 491 is not covered by the cover part (reference numeral 494b in FIG. 8f ), and is opened so that the inside of the accommodating part 491 and the outside of the accommodating part 491 communicate with each other. .

Subsequently, as shown in FIG. 8D , the packing member 495 is fixed between the receiving part 491 and the covering member 312 , and the first through hole 312b and the receiving part 491 of the bracket member 312a are fixed. ) by fastening the fastening member 68 to the second through-hole 491b to fix the receiving part 491 and the fixing part 310 and/or the circuit part 300 .

The packing member 495 is positioned between the fixing part 310 and the receiving part 491 before the fixing part 310 is completely in close contact with the receiving part 491, and thereafter, the fixing part 310 is placed in the receiving part. (491) The packing member 495 may be fixed by completely pushing it into the inside. Alternatively, the packing member 495 may be fixed after the fixing part 310 is completely pushed into the receiving part 491 . Various other variations are possible.

As shown in FIG. 8E , the ribbon 122 is fastened to the terminal 31 through the opening 494a. As described above, since the opening 494a formed on the bottom surface 4942 of the receiving portion 491 is not blocked by the cover portion 494c, the terminal 31 and the ribbon ( 122) is exposed to the outside. Accordingly, the terminal 31 and the ribbon 122 can be easily fixed through the opening 494a. Since the method of fastening or fixing the ribbon 122 to the terminal 31 has been described in detail with reference to FIG. 7 , the description thereof will be omitted.

Next, as shown in Fig. 8F, the cover portion 494b is fixed to close the opening portion 494a. More precisely, the bottom surface 4942 of the accommodating part 494 and the cover part 494b are joined by an adhesive member (reference numeral 494c in FIG. 4 , hereinafter the same) positioned to surround the opening 494a. The adhesive member 494c may be applied on the bottom surface 4942 of the receiving part 491 so as to surround the opening 494a, and then the cover part 494b may be placed on the adhesive member 494c and compressed, or the cover part 494b ) may be placed on the bottom surface 4942 of the receiving portion 491 and compressed in a state in which the adhesive member 494c is applied to the edge portion. Alternatively, in a state in which the adhesive member 494c and the cover part 494b are sequentially positioned on the bottom surface 4942 of the accommodating part 491 , heat, pressure, etc. may be applied to fix them. Various other variations are possible.

When repair, replacement, inspection, etc. of the circuit unit 300 is required, the process of FIGS. 8A to 8F or the process of FIGS. 8B to 8F is reversed to separate the circuit unit 300 from the receiving unit 491. there is. After the desired repair, replacement, inspection, etc. is completed, the process of FIGS. 8A to 8F or the process of FIGS. 8B to 8F may be performed again to fix the circuit part 300 to the receiving part 491 again.

According to this, the circuit part 300 (or the fixing part 310 to which the circuit part 300 is fixed) is inserted into the receiving part 491 or separated from the receiving part 491 through the open side 491a by a simple method. can do. Accordingly, the circuit part 300 and the receiving part 491 can be fixed by a simple process, and processes such as repair, replacement, and inspection of the circuit part 300 can be simplified. Accordingly, even if a failure occurs in the circuit unit 300 , the accommodating unit 491 and the like can be used as it is, thereby reducing repair costs. In particular, when the accommodating part 491 is made of metal to improve durability, the repair cost can be greatly reduced.

The features, structures, effects, etc. as described above are included in at least one embodiment of the present invention, and are not necessarily limited to one embodiment. Furthermore, features, structures, effects, etc. illustrated in each embodiment can be combined or modified for other embodiments by those of ordinary skill in the art to which the embodiments belong. Accordingly, the contents related to such combinations and modifications should be interpreted as being included in the scope of the present invention.

100: solar cell module
10: solar panel
20: frame
30: integrated inverter
31: terminal
33: bypass diode
35: inverter absent
37: circuit board
300: circuit part
310: fixed part
312: covering member
314: floor member
316: support member
49: receptacle

Claims (20)

As an integrated inverter used in a solar cell module including a solar panel,
a circuit unit including a terminal connected to the solar panel, and an inverter member including a DC-AC inverter electrically connected to the terminal; and
Receiving part for accommodating the circuit part
including,
An integrated inverter in which the circuit part is directly slidably coupled to the accommodating part between the solar cell panel and the accommodating part.
According to claim 1,
The integrated inverter further includes a fixing part to which the circuit part is fixed,
An integrated inverter coupled to the receiving unit by sliding the circuit unit into the receiving unit while being fixed to the fixing unit. 3. The method of claim 2,
At least one side of the receiving portion is opened to constitute an open side,
The fixed part is an integrated inverter having a covering member for blocking the open side of the accommodating part. 4. The method of claim 3,
The integrated inverter constitutes one housing by combining the covering member and the accommodating part to surround the circuit part. 4. The method of claim 3,
An integrated inverter in which the covering member is fixed to the receiving portion. 4. The method of claim 3,
An integrated inverter in which the fixing part and the receiving part are fixed by at least one of a screw coupling, an adhesive material, a sealing material, an adhesive tape, a packing member, and a latch structure. 4. The method of claim 3,
The covering member is formed to protrude toward the receiving portion and includes a bracket member having a first through hole,
The receiving portion includes a second through-hole at a position corresponding to the first through-hole,
An integrated inverter in which the accommodating part and the covering member are screwed together by a fastening member passing through the first through hole and the second through hole. 4. The method of claim 3,
The integrated inverter further comprising a packing member positioned between the covering member and the accommodating part. 9. The method of claim 8,
An integrated inverter in which the packing member is formed along an edge of the receiving portion where the open side is located. 4. The method of claim 3,
The integrated inverter includes an AC output cable,
An integrated inverter in which the AC output cable is led out through the covering member. 4. The method of claim 3,
The integral inverter comprising a bottom member on which the fixing part is mounted on the circuit part. 12. The method of claim 11,
The terminal and the inverter member are formed on a circuit board and are connected to each other by a circuit pattern to constitute a circuit part,
An integrated inverter in which the circuit board is fixed to the bottom member. 13. The method of claim 12,
A press-fit nut is positioned on the bottom member,
A fastening hole is located on the circuit board at a position corresponding to the press-fitting nut,
A fastening member is fastened to the press-fitting nut and the fastening hole to fix the circuit board and the bottom member. 12. The method of claim 11,
The integral inverter further comprising a support member positioned at an edge opposite to the edge on which the fixing part is positioned. 12. The method of claim 11,
The integrated inverter further comprising a guide member formed along the sliding direction of the fixing part on the inner surface of the receiving part. 3. The method of claim 2,
An integrated inverter comprising the fixing part of an insulating material or a conductive material. According to claim 1,
The accommodating part includes a bottom surface positioned to be spaced apart from the solar cell panel, and a side surface extending from the bottom surface toward the solar cell panel,
an opening formed in at least a portion corresponding to the terminal on the bottom surface;
The integrated inverter further includes a cover for blocking the opening. According to claim 1,
The solar cell panel includes a solar cell and a ribbon connected to the solar cell,
An integrated inverter in which the ribbon is fixed to the terminal inside the receiving part. solar panel; and
The integrated inverter according to any one of claims 1 to 18
A solar cell module comprising a. 20. The method of claim 19,
The accommodating part has an open side opposite to the solar cell module,
A solar cell module in which a surface of the accommodating part facing the solar cell module is covered by the solar cell panel.

Images