KR20150085412A - Integral inverter and solar cell module including the same - Google Patents

Abstract

The present invention relates to an integrated inverter which is an integrated inverter used for a solar cell containing a solar cell panel comprising: a terminal connected to the solar cell panel; a bypass diode electrically connected to the terminal; and inverter members including a DC-AC inverter electrically connected to the bypass diode. At least one of the terminal or the bypass diode can be integrated with the DC-AC inverter.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an integrated inverter and a solar cell module including the inverter,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an integrated inverter and a solar cell module including the inverter. More particularly, the present invention relates to an integrated inverter improved in structure and a solar cell module including the same.

With the recent depletion of existing energy sources such as oil and coal, interest in alternative energy to replace them is increasing. Among them, solar cells are attracting attention as a next-generation battery that converts solar energy into electric energy.

The solar panel with the solar cell is connected to the junction box, and the junction box is connected to the DC-AC inverter through the DC output cable drawn from the junction box. More specifically, the DC voltage or the 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 the AC voltage or the AC current by the DC-AC inverter. The AC voltage or alternating current generated by the DC-AC inverter is again connected to another solar cell module by an AC output cable, or to a power grid or the like.

In this case, since the junction box and the DC-AC inverter must be separately manufactured and installed (for example, they must be separately manufactured in separate cases and installed separately), when the solar cell module is applied to the solar cell module, . Furthermore, since a DC output cable (i.e., two output cables) must be connected between the junction box and the DC-AC inverter to connect them, installation space and installation time are further required. In particular, the output cable has a large volume and weight, which is a great difficulty in installation. As a result, the productivity of the junction box and DC-AC inverter installation process is very low. In addition, the two output cables connecting the junction box and the DC-AC inverter can be shaken or separated from the transportation and use process, thereby causing various problems such as collision with the solar panel and damaging the solar panel .

The present invention provides an integrated inverter capable of improving the productivity of a solar cell module assembling process and improving the structural stability of the solar cell module, and a solar cell module including the same.

An integrated inverter according to an embodiment of the present invention is an integrated inverter used in a solar cell module including a solar cell panel, comprising: a terminal connected to the solar cell panel; A bypass diode electrically connected to the terminal; And an inverter member including a DC-AC inverter electrically connected to the bypass diode. At least one of the terminal and the bypass diode may be integrated with the DC-AC inverter.

Wherein at least one of the terminal and the bypass diode and the DC-AC inverter are located inside the case and integrated by the case, formed integrally with the circuit board and integrated by the circuit board or wrapped together by the potting member And can be integrated by the potting member.

At least one of the terminal and the bypass diode may be located on the circuit board.

The terminal, the bypass diode, and the DC-AC inverter may be formed on a circuit board and connected to each other by a circuit pattern.

The integrated inverter may further include one AC output cable for providing the AC power converted by the integrated inverter to the outside.

Wherein the first terminal, the bypass diode, and the DC-AC inverter are located inside the first case, the first case has a first through hole for connection between the solar cell and the terminal, And a second through hole for connection of the first and second substrates.

An adhesive member for bonding with the solar cell panel is disposed in the first case, and the bonding member may be formed so as to surround the through hole when viewed in a plan view.

The terminal may be connected to a ribbon drawn from a solar cell of the solar cell panel, and the ribbon may be connected to the terminal through the first through hole.

The ribbon may be releasably secured to the terminal.

A circuit board on which the terminal, the bypass diode and the DC-AC inverter are formed, and a circuit board on which the circuit board, the bypass diode, And a potting member surrounding the DC-AC inverter.

The first case includes a first case portion including an inner space portion and a joint flange extending from the upper inner space portion and on which the joining member is located; And a second case portion joined to the first case portion by the joining member to cover the first case portion.

And the joining flange may extend over the entire upper portion of the inner space portion so as to surround the inner space portion when viewed in a plan view. The joining flange may be formed of a flat surface formed on the same plane.

The second case portion may have an inner portion having an inner flat surface and a rim portion that is located at the outer periphery of the inner portion and is inclined away from the joining flange toward the outside.

The first case may include a fastening portion extending to be fastened to the frame of the solar cell module.

Wherein the inverter member includes: a current sensor for detecting an abnormality of a direct current passing through the bypass diode; A capacitor for storing a direct current voltage passing through the current sensor; And a dc-to-dc converter for converting the dc voltage provided from the capacitor to a dc voltage of a different magnitude and providing the converted dc voltage to the dc-ac converter. The current sensor and the bypass diode may be connected by a circuit pattern on a circuit board.

A plurality of DC-DC converters may be provided.

A solar cell module according to an embodiment of the present invention includes the above-described integrated inverter; And a solar cell panel connected to the integrated inverter.

And a frame for fixing the outer frame of the solar cell panel. The frame may include a panel inserting portion into which at least a part of the solar cell panel is inserted, and an extending portion extending rearward from the panel inserting portion. The integrated inverter may be located on the rear surface of the solar cell panel, and the thickness of the integrated inverter may be equal to or less than the height of the extension portion.

The integrated inverter includes a fastening portion to be fastened to the frame, a fastening portion is formed on the fastening portion, and a fastening groove is formed at a position corresponding to the fastening portion of the frame.

At least a portion of the fastening portion may be located within the extension.

The integrated inverter of the solar cell module according to the present embodiment is formed by integrating or integrating a bypass diode for providing a terminal and / or a bypass path connected to the ribbon, and an inverter member for converting a direct current to an alternating current. By forming them integrally, the installation process can be simplified and the structure can be simplified. In addition, it is unnecessary to use an output cable (that is, a DC output cable) for connecting them by connecting the bypass diode and the inverter member in a circuit pattern, thereby simplifying the structure, The damage of the panel can be prevented.

1 is a front perspective view showing a solar cell module including an integrated inverter according to an embodiment of the present invention.
2 is a rear perspective view showing the solar cell module of FIG.
3 is a cross-sectional view taken along line III-III in FIG.
4 is an exploded perspective view showing an enlarged view of a portion A in Fig.
Fig. 5 is an exploded perspective view showing the surface of the integrated inverter adjacent to the solar cell panel viewed from the solar cell panel by separating the integrated inverter from the solar cell panel by enlarging portion A in Fig. 2;
6 is a perspective view showing a part of the integrated inverter shown in Fig.
7 is a cross-sectional view taken along the line VII-VII of FIG.
8 is a perspective view showing various modifications that can be applied to the integrated inverter of the solar cell module of FIG.
FIG. 9 is a perspective view showing a terminal applicable to the integrated inverter of the solar cell module shown in FIG. 1 and a ribbon connected thereto.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it is needless to say that the present invention is not limited to these embodiments and can be modified into various forms.

In the drawings, the same reference numerals are used for the same or similar parts throughout the specification. In the drawings, the thickness, the width, and the like are enlarged or reduced in order to make the description more clear, and the thickness, width, etc. of the present invention are not limited to those shown in the drawings.

Wherever certain parts of the specification are referred to as "comprising ", the description does not exclude other parts and may include other parts, unless specifically stated otherwise. Also, when a portion of a layer, film, region, plate, or the like is referred to as being "on" another portion, it also includes the case where another portion is located in the middle as well as the other portion. When a portion of a layer, film, region, plate, or the like is referred to as being "directly on" another portion, it means that no other portion is located in the middle.

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

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

1 to 3, a solar cell module 100 according to the present embodiment includes a solar cell panel 10 including a solar cell 12, a solar cell module 10 connected to the solar cell panel 10, And an integrated inverter 30 mounted on the inverter 10. The solar cell module 100 may include a frame 20 for fixing the outer frame of the solar cell panel 10. This will be explained in more detail. Between the solar cell panel 10 and the frame 20, a sealing member (not shown) for sealing and adhering them may be located.

The solar panel 10 includes at least one solar cell 12. The solar cell panel 10 includes a sealing layer 14 covering and sealing the solar cell 12, a front substrate 16 positioned on the front surface of the solar cell 12 on one side of the sealing layer 14, And a rear substrate 18 positioned on the rear surface of the solar cell 12 on the other surface of the sealing layer 14. [

A semiconductor substrate (for example, a monocrystalline semiconductor substrate, more specifically, a monocrystalline silicon wafer), a first and a second semiconductor substrate 2 conductive region, and first and second electrodes connected to the first and second conductive regions, respectively. Here, one of the first and second conductivity type regions may have a p-type and the other may have an n-type. The first or second conductivity type region may be a doped region formed by doping a portion of the semiconductor substrate with a dopant, or may be formed of a semiconductor layer doped with dopant and formed separately on the semiconductor substrate. A plurality of solar cells 12 are provided and a first electrode of the solar cell 12 and a second electrode of the solar cell 12 adjacent thereto are connected by a ribbon 122 or the like to form a plurality of solar cells 12 Can form a solar cell string that forms a single row. The structure of the solar cell 12 and the connection structure of the plurality of solar cells 12 can be variously known structures.

Thus, in this embodiment, the use of a silicon semiconductor solar cell as the solar cell 12 has been illustrated. 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 type solar cell, and a compound semiconductor solar cell can be used as the solar cell 12. Although a plurality of solar cells 12 is illustrated as an example, only one solar cell 12 may be provided.

The sealing layer 14 includes a first sealing layer 14a positioned between the solar cell 12 and the front substrate 16 and a second sealing layer 14b located between the solar cell 12 and the rear substrate 18, And a second sealing layer 14b that is joined to the first sealing layer 14b. The sealing layer 14 surrounds and seals the solar cell 12 to block water or oxygen that may adversely affect the solar cell 12. [ And chemically combines the parts constituting the solar cell module 100 (i.e., the front substrate 16, the solar cell 12, and the rear substrate 18). After the rear substrate 18, the second sealing layer 14b, the solar cell 12 or the solar cell string, the first sealing layer 14a and the front substrate 16 are stacked in order and then heat and / And a lamination process for joining them can be performed to integrate them.

The first sealing layer 14a and the second sealing layer 14b may be made of ethylene-vinyl acetate copolymer resin (EVA), polyvinyl butyral, silicon resin, ester resin, olefin resin, or the like. At this time, the first sealing layer 14a and the second sealing layer 14b may be made of the same material or may be made of different materials. However, the present invention is not limited thereto. Accordingly, the first and second sealing layers 14a and 14b may be formed by a method other than lamination using various other materials.

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 a strength capable of protecting the solar cell 12 from an external impact or the like and a light transmissive material capable of transmitting light such as sunlight. For example, the front substrate 16 may be formed of a glass substrate or the like. At this time, the front substrate 16 may be formed of a tempered glass substrate so as to improve the strength, or may be variously modified to include various materials capable of improving various other characteristics. Alternatively, the front substrate 16 may be a sheet or a film made of 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 disposed on the second sealing layer 14b and protects the solar cell 12 from the rear surface of the solar cell 12, and can function as a waterproof, insulating, and ultraviolet shielding function.

The rear substrate 18 may have a strength capable of protecting the solar cell 12 from an external impact or the like and may have a property of transmitting or reflecting light according to the structure of the desired solar cell panel 10. [ For example, in the structure in which light is incident through the rear substrate 18, the rear substrate 18 may have a light-transmitting material and the light may be reflected through the rear substrate 18, Non-transmissive material or reflective material. For example, the rear substrate 18 may be formed in the form of a substrate such as glass, or in the form of a film or a sheet. For example, the back substrate 18 may be a TPD (Tedlar / PET / Tedlar) type or a polyvinylidene fluoride (PVDF) resin formed on at least one side of a polyethylene terephthalate (PET) . Poly (vinylidene fluoride) is a polymer having a structure of (CH ₂ CF ₂ ) n and has a double fluorine molecular structure, and therefore has excellent mechanical properties, weather resistance, and ultraviolet ray resistance. The present invention is not limited to the material of the rear substrate 18 and the like.

In order to stably fix the solar cell panel 10 composed of a plurality of layers as described above, the frame 20 to which the outer frame portion of the solar cell panel 10 is fixed may be positioned. Although the entire outer frame of the solar cell panel 10 is illustrated as being fixed to the frame 20, the present invention is not limited thereto. Accordingly, various modifications are possible, for example, such that the frame 20 fixes only a part of the edge of the solar cell panel 10.

The frame 20 in this embodiment includes a panel insertion portion 22 into which at least a part of the solar cell panel 10 is inserted and an extension portion 24 extending outwardly from the panel insertion portion 20 .

More specifically, the panel inserting portion 22 includes a front portion 222 disposed on the front surface of the solar cell panel 10, a side surface portion 224 disposed on the side surface of the solar panel 10, And the rear portion 226 located on the rear side are connected to each other so that the outer portion of the solar panel 10 can be positioned inside the rear portion 226. For example, the first frame 141 may have a " U "cross-sectional shape or a" U "shape in which the edge of the solar cell panel 10 is bent inside twice. However, the present invention is not limited thereto, and any one or a part of the front portion 222, the side portion 224, and the rear portion 226 may not be located. Other variations 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) And a second portion 244 extending from the first portion 242 and spaced apart from the rear or back portion 226 of the solar cell panel 12 can do. The second portion 244 may be parallel or inclined to the back or back portion 226 of the solar cell panel 12. Thus, the extension 24 may have a "B" shaped or "L" shaped cross-sectional shape that is once bent to form a space with the back portion 226.

The extended portion 24 is a portion that is fixed to the base, the support, or the bottom surface by increasing the strength of the frame 20, and the extending portion 24 is provided with a fastening member (Not shown) may be formed. Since the fastening member or the like is fastened to the second portion 244 spaced apart from the solar cell panel 10 as described above, it is possible to prevent the solar cell panel 10 from being damaged at the time of installing the solar cell module 100 using the fastening member .

The second portion 244 may be formed to have an area equal to or larger than the rear portion 226 (i.e., to have the same or larger width) so as to stably fix the fastening member or the like. And the structure of the fastening member and the like can be used. The present invention is not limited thereto, and the extension portion 24 may have various other shapes.

Such a frame 20 can be fixed to the solar cell panel 10 in various ways. For example, a portion of the solar cell panel 10 that forms an outer frame portion may be formed of a portion having elasticity (for example, a tape having elasticity) (10) can be inserted. However, the present invention is not limited thereto, and various modifications are possible, for example, by assembling the parts constituting the frame 20 at the outer frame of the solar cell panel 10 and assembling them.

In this embodiment, the integrated inverter 30 connected to the solar cell 12 of the solar cell panel 10 may be provided. For example, the integrated inverter 30 may be positioned on the rear side of the solar cell panel 10 and adjacent to the upper end portion of the solar cell panel 10. At this time, the thickness T1 of the integral inverter 30 may be equal to or less than the height H1 of the extension portion 24 of the frame 20 (more specifically, the height of the first portion 242). The height H1 of the extension portion 24 may be defined as a distance from the rear surface of the solar cell panel 10 to the outer surface of the second portion 24 of the extension portion 24. [ Accordingly, the integral inverter 30 may have a thickness that does not protrude from the outer surface of the second portion 244. [ That is, the rear surface (the surface located away from the solar cell panel 10) of the integrated inverter 30 may be located on the same plane as the outer surface of the second portion 244 or may be located closer to the solar cell panel 10 . The rear surface (the surface located away from the solar cell panel 10) of the portion of the integrated inverter 30 located inside the extension portion 24 is the same as the inner surface of the second portion 244 or more than the inner surface of the solar cell panel 10 So that it can be easily positioned inside the extended portion 24. Thus, the volume of the solar cell module 100 can be minimized and the space on the rear side of the solar cell panel 10 can be efficiently utilized. In this embodiment, the integrated inverter 30 is connected to the extension portion 24 of the frame 20 adjacent to the upper end portion of the solar cell panel 10, and / or attached to the rear surface of the solar cell panel 10 . This will be described in more detail later.

The integrated inverter 30 according to the present embodiment is formed by integrating at least a part of a conventional junction box and at least a part of an inverter, and is called a junction box integrated inverter, a bypass diode integrated inverter, an integral junction box, . Such an integrated inverter 30 will be described in more detail with reference to Figs. 1 to 3 and Figs. 4 to 9. Fig.

Fig. 4 is an exploded perspective view showing an enlarged view of a portion A in Fig. 2, Fig. 5 is an enlarged view of a portion A in Fig. 2, showing the integral inverter 30 removed from the solar cell panel 10, Is an exploded rotary perspective view showing the surface of the adjacent integrated inverter (30). 6 is a perspective view showing a part of the integrated inverter 30 shown in Fig. For simplicity and clarity, the illustration of the potting member 372 is omitted in FIG. 4, and the potting member 372 will be described in detail with reference to FIG.

4 and 5, an integrated inverter 30 according to the present embodiment includes a terminal (not shown) connected to a solar cell (reference numeral 12 in Fig. 3, hereinafter the same) (or a solar cell 10 A bypass diode 33 electrically connected to the bypass diode 33 and / or the terminal 31 and an inverter member 35 electrically connected to the bypass diode 33 and including a DC-AC inverter 352 are integrated Respectively. At this time, the terminal 31 may be connected to the ribbon 122 drawn out from the solar cell 12.

Here, the integrated state may include all states recognized as one component, article, object, or member when fixed to the solar cell panel 10 and / or the frame 20 during the installation process or after the installation process . For example, the term " integrated " means that they are integrally formed by the same case, placed in the same case, integrated by the same member fixed or attached to the same member, or the like May mean formed together on the same member to form part of the same member, or may be meant to be wrapped or fixed together by the same member. Conversely, it may be hard to say that the connection by a separate output cable is unified. At this time, the terminal 31, the bypass diode 33, and the inverter member 35 may be integrated with each other in a detachable manner or may be detachably integrated with each other so that the terminal 31, the bypass diode 33,

The integrated inverter 30 according to the present embodiment is formed on the circuit board 37 having the circuit pattern (or circuit, wiring) with the terminal 31, the bypass diode 33 and the inverter member 35 together. Thus, the terminal 31, the bypass diode 33, and the inverter member 35 can be seen to be integrated by the circuit board 37. 6, the potting member 372 can be positioned while covering or wrapping the circuit board 37 and the bypass diode 33 and the inverter member 35 can be positioned by the potting member 372. [ May be regarded as being integrated by the potting member 372. The circuit board 37 on which the terminal 31, the bypass diode 33 and the inverter member 35 are formed can be located inside the same case 39. [ Accordingly, the terminal 31, the bypass diode 33, and the inverter member 35 may be considered to be integrated by the same case 39. [

The bypass diode 33 and the inverter member 35 are integrated by the same circuit board 37, the same potting member 372 and the same case 39 in the present embodiment . Thus, the terminal 31, the bypass diode 33, and the inverter member 35 can be integrated more firmly. However, the present invention is not limited thereto, and it is also possible to integrate them using a simple structure using at least one of various methods for integrating them. In this 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, only the bypass diode 33 and the inverter member 35 can be integrated, and various other modifications are possible.

In this embodiment, the case 39 is provided with a space in which the integrated terminal 31, the bypass diode 33 and the inverter member 35 are located, and the solar battery panel 10 and / As shown in Fig.

For example, in this embodiment, the case 39 includes a first case 49 which forms an outer shape or an outer surface. This case 39 provides a space in which at least the integrated terminal 31, the bypass diode 33 and the inverter member 35 are located and is fixed to the solar cell panel 10 and / or the frame 20 . The first case 47 will be described in more detail with reference to Fig. 7 together with Figs. 4 and 5. Fig. 7 is a cross-sectional view taken along the line VII-VII of FIG.

In this embodiment, the first case 49 includes a first case portion 491 and a second case portion 492 which are joined together to form an integral case. The bypass diode 33 and the inverter member 35 can be easily inserted or removed when the first case portion 491 and the second case portion 492 are separated from each other. The bypass diode 33 and the inverter member 35 can be stably accommodated in a state where the first case portion 491 and the second case portion 492 are coupled to each other .

Here, the first case portion 491 includes an inner space portion 494 having a bottom surface 4942 and a side surface 4944 and an inner space therebetween, and a bottom surface 4942 extending from the top of the inner space portion 494 And a flange 496 extending parallel or inclined with respect to the flange 496. At this time, the side surface 4944 is formed on all the edges of the bottom surface 4942 so that the inner space portion 494 can be formed to open only one side of the inner space. For example, when the bottom surface 4942 is a rectangle, the bottom surface 4942 may have four sides 4944 extending from four edges constituting the quadrangle so that only one surface is formed in the rectangular parallelepiped. For example, the inner space portion 494 may have at least five surfaces and only one side thereof may have an open structure.

In the drawing, the bottom surface 4942 may have a shape having four straight lines and a rounded corner at a portion where two adjacent straight lines meet. For example, the bottom surface 4942 may have a roughly rectangular shape, and a portion corresponding to four corners of the rectangular shape may have a rounded shape. The side surface 4944 may extend entirely from the edge of the bottom surface 4942 and extend (for example, perpendicularly) to intersect the bottom surface 4942. Thus, the side surface 4944 can be formed to include four rounded surfaces each located between four planes corresponding to four straight lines and two planes adjacent to each other. Accordingly, the internal space can be sufficiently secured, and the user can be prevented from being injured by sharp edges. 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 in a shape that bends and extends from the side surface 4944. The joining flange 496 provides a region to which the joining member 493 is applied so that the first case portion 491 and the second case portion 492 can be joined to each other by the joining member 493. [ At this time, the joint flange 496 is bent from the side surface 4944 and extends outward to open all the internal spaces of the internal space portion 494 to connect the terminal 31, the bypass diode 33 and the inverter member 35 Can be easily mounted and released without being caught by the joint flange 496. [ The joint flange 496 may be comprised of a flat surface parallel to the bottom surface 4942 and / or a flat surface perpendicular to the side surface 4944. Then, the joining member 493 can be stably applied on the joining flange 496. [ However, the present invention is not limited thereto.

In this embodiment, the joint flange 496 is formed continuously so as to extend entirely from the end of the side surface 4944 and to close the inside of the internal space portion 494 when seen in plan view. Here, the joint flange 496 may be formed to be a flat surface so as to be positioned on the same plane. The first case portion 491 and the second case portion 492 are entirely joined by the joint member 493 applied to the joint flange 496 so that the airtightness of the interior of the first case 49 is increased . At this time, the width of the joint flange 496 is made uniform as a whole to uniformly apply the joining member 493, so that the first case portion 491 and the second case portion 492 can be stably bonded. When a cutting mechanism (for example, a knife or the like) is inserted between the joint flange 496 and the second case portion 492 and the joint flange 496 is moved a single turn when repair, replacement, or the like is required, The first case portion 491 and the second case portion 492 can be easily separated by cutting the second case portion 493. That is, since the cutting mechanism is moved along the flat surface of the joint flange 496, the first case portion 491 and the second case portion 492 can be easily separated from each other.

In this embodiment, the second case portion 492 may have a plate shape having an edge shape whose edge corresponds to the outer edge of the joint flange 496, and which covers an opened one side of the internal space portion 494. [

At this time, the second case portion 492 has an inner portion 497 which is formed to be flat so as to be parallel with the bottom surface 4942 and a second case portion 492 which is away from the first case portion 491 while facing outward from the inner portion 497 (Not shown). A portion of the outer portion 499 overlapping with the joining flange 496 is joined by the joining flange 496 and the joining member 493.

When forming the outer portion 499 inclined toward the outside as described above, a boundary line (or a boundary portion) that can be visually recognized or perceived by the equipment can be provided between the inner portion 497 and the outer portion 499 . The approximate position of the first case portion 491 and the second case portion 492 can be aligned by positioning the inner portion 497 above the joint flange 496 or not to leave the joint flange 496 have. At this time, the inner portion 497 may have an area smaller than the bottom surface 4942. For example, the width W2 of the outer portion 499 may be greater than the width W1 of the joint flange 496. [ The boundary between the inner portion 497 and the outer portion 499 may then be positioned within the joint flange 496 (i.e., on the inner space) to define a first case portion 491 and a second case portion 492, It is possible to more easily adjust the approximate position of Thus, the boundary between the inner portion 497 and the outer portion 499 can be used as a kind of guide, alignment mark, and the like.

When the outer portion 499 is tilted away from the inner portion 497 toward the outside, the distance between the joining flange 496 and the outer portion 499, i.e., the distance between them The thickness of the joining member 493 located at the outer edge of the joining member 493 becomes larger at the outer edge than at the inner edge. Since the distance between the first case portion 491 and the second case portion 492 at the outer edge portion of the joint flange 496 is large, the first case portion 491 and the second case portion 492 The cutting mechanism can more easily be cut between the joint flange 496 and the outer portion 499 when cutting the flange 492. [

The joining member 493 positioned between the joining flange 496 of the first case portion 491 and the outer portion 499 of the second case portion 492 overlapping the first case portion 491 and the second case portion 492, The case portion 492 is bonded and sealed to prevent impurities, contaminants, and the like from entering from the outside, and to improve sealing characteristics and waterproof characteristics. Various materials having bonding and / or sealing properties can be used for the joining member 493. For example, a sealant or the like may be used. However, the present invention is not limited thereto.

However, the present invention is not limited thereto, and it is also possible that the first case 49 is formed without covering the inner space as a whole. In addition, various modifications are possible, such that the side surface is not formed or the side surface is formed only in a part of the first case portion 491, and the side surface is formed in at least a part of the second case portion 492. It is also possible that the first case 49 includes three or more parts to be coupled to each other, and various other modifications are possible.

If the first case portion 491 and the second case portion 492 are provided together, the components and the like located therein can be easily inserted and removed. By joining them by the joining member 493, It is possible to prevent problems caused by external moisture or the like from being sealed, and to stably protect parts located inside from external impacts. However, the present invention is not limited thereto, and it is also possible that the first case 49 includes at least one of the first case portion 491 and the second case portion 492. For example, the solar cell panel 10 may be attached to the second case 491 by fitting the joining flange 496 of the first case portion 491 to the solar cell panel 10 side without forming the second case portion 492, Part 492, and so forth.

The first case 49 may include a structure for connection with the solar cell 12, the outside (for example, another solar cell module 100 or a power grid), and the like. That is, the first case 49 has a first through hole 49a through which the ribbon 122 for connection with the solar cell 12 passes, and a second through hole 49b through which one And a second through hole 49b through which the AC output cable 38 passes.

That is, a first through hole 49a for connection with the solar cell 12 and a second through hole 49b for the AC output cable 38 are formed in the same first case 49. This is because the terminal 31 and / or the bypass diode 33 and the inverter member 35 are integrated. Conventionally, a first through hole for connection with a solar cell is formed in the case of the junction box, and a second through hole for the AC output cable is formed in the case of the inverter in which the inverter member is located, The holes can not be formed in the same case. That is, the circuit board 37 may be integrally formed with a structure for connection to the solar panel 10 and an output cable 38 for providing an AC voltage to the outside.

For example, the first through hole 49a may be formed on the surface adjacent to the solar cell panel 10 (i.e., the bottom surface 4942 of the first case portion 491). Then, the ribbon 122 drawn out from the solar cell 12 through the second sealing layer 14b and the hole (not shown) formed in the rear substrate 18 is guided to the terminal 31 in a shorter path You can connect. The first through holes 49a may be a single hole through which a plurality of (n) ribbons 122 corresponding to solar cell strings or the like are passed together, or a plurality of Holes may be included. In the drawing, a first through hole 49a through which a plurality of ribbons 122 pass together is shown, so that the first case portion 491 can be more easily processed.

The second through hole 49b may be formed at a position where external circuit connection can be easily performed. The second through hole 49b is located on the side surface 4944 remote from the terminal 31 in this embodiment and the voltage provided from the solar panel 10 to the terminal 31 is supplied to the bypass diode 33, And the inverter member 35, and then is led out to the outside through the AC output cable 38. Thus, the arrangement of the terminal 31, the bypass diode 33, and the inverter member 35 can be efficiently performed.

In this embodiment, the output cable of the integral converter 30, in which the terminal 31 connected to the ribbon 122 and / or the bypass diode 33 is located, is constituted by the AC output cable 38. Accordingly, one AC output cable 38 can be drawn out through the second through hole 49b. Generally, the AC output cable 38 may have three conductors with three-phase voltage (current), one AC output cable 38 comprising three conductors. Three conductors constituting one AC output cable 38 may be combined to pass through one second through hole 49b. Thus, the structure can be simplified. However, the present invention is not limited thereto, and various modifications are possible, for example, three conductors are drawn out through different second through holes 49b.

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 constituted by the AC output cable 38, It does not have a cable. This is because the terminal 31 and / or the bypass diode 33 and the inverter member 35 are integrated. Conventionally, there are two direct-current output cables of (+) output cable and (-) output cable because the direct voltage or direct current is drawn out from the junction box where the terminal and the bypass are located.

A fastening portion 49c for fastening the frame 20 to the first case 49 may be formed. The fastening portion 49c is a portion that is coupled to the frame 20 by the fastening member 62. In this embodiment, the fastening portion 49c can be formed integrally with the first case portion 491 or the second case portion 492 and extend therefrom. Then, the first case 49 having the fastening portion 49c can be formed together by the same process, so that the productivity can be improved.

The fastening portion 49c extends from the first case 49 adjacent to the frame 20 (the upper end in the figure) to form at least one surface (in particular, the second portion 244 of the frame 20) ). ≪ / RTI > A fastening hole 490c is formed in the fastening portions 49c and the second portion 244 and fastening members 62 (for example, screws, screws, etc.) are fastened to the fastening holes 490c So that the first case 49 can be fixed to the frame 20. Thus, the first case 49 and the frame 20 can be firmly fixed by a simple structure.

For example, in this embodiment, the fastening portion 49c includes a first fastening portion 491c fastened to the frame 20. The fastening portion 49c is bent from the first fastening portion 491c to extend toward the solar cell panel 10 side and the second fastening portion 492c from the second fastening portion 492c, And a fourth fastening portion 494c that extends from the third fastening portion 493c to the fastening flange 464. The third fastening portion 493c may extend from the first fastening portion 492c to the second fastening portion 492c, .

The first fastening portion 491c can be positioned to contact (or come into contact with) the second portion 244 of the frame 20. The first fastening portion 491c is positioned so as to be in close contact with the inner surface of the second portion 244 (i.e., the rear surface portion 226 or the surface facing the solar cell panel 10) The fastening portion 49c can be positioned in the inner space. At this time, the fastening holes 224c and 490c are positioned at the positions corresponding to the second fastening portions 491c closely contacting the second portions 244 and the inner surfaces of the second portions 244. A latching portion 490d penetrating the latching groove 244d of the second portion 244 may be positioned at a side edge of the first fastening portion 491c. Then the engaging portion 490d of the first engaging portion 491c is fitted into the engaging groove 244d of the second portion 244 so that the position of the engaging portion 49c is adjusted to the desired position, The fastening portion 49c and the second portion 244 can be fixed to each other. In this embodiment, the latching portion 490d is constituted by a protruding portion which protrudes in a direction away from the solar cell panel 10 so as to pass through the second portion 244, and the latching groove 244d is formed by the latching portion 490d And a groove formed corresponding to the portion. Thus, the position of the fastening portion 49c and the second portion 244 can be easily adjusted by using a simple structure. The engaging portions 490d are positioned one on each side edge of the first fastening portion 491c, and the two engaging grooves 244d correspond to the engaging portions 490d. Thus, the alignment characteristics can be further improved. However, the present invention is not limited thereto. Therefore, the structure, shape, position, number and the like of the fastening structure of the fastening portion 49c and the frame 20, the fastening portion 490d and the fastening groove 244d can be variously modified.

The second fastening portion 492c can contact (or come into contact with) the frame 20 (more precisely, the first portion 242). More specifically, the second fastening portions 492c can contact (or come into contact with) the inner surface of the first portion 242 with each other. Then, the fastening portions 49c and the frame 20 can be more firmly fixed to each other.

The third fastening portion 493c may be spaced apart from the solar cell panel 10 or the frame 20. The first case portion 491 and the second case portion 492 can be fastened to each other by the fastening member 64 using the third fastening portion 493c. The third fastening portion 493c, So that the fastening of the first case part 491 and the second case part 492 can be performed more easily. However, the present invention is not limited thereto, and the first case portion 491 and the second case portion 492 may be joined only by the joining member 93 and may not be separately engaged, or may be fastened to each other at different positions. At this time, the second fastening portion 493c can be firmly attached to the rear surface of the solar cell panel 10 or the rear surface portion 226 of the frame 20, thereby improving the fixing stability. Various other variations are possible.

The through hole 490f is formed over the second fastening part 492c and the third fastening part 493c so that the fastening part 49c which is bent a plurality of times can be more easily processed. A plurality of through holes 490f may be formed to improve ease of processing, but the present invention is not limited thereto. Also, the shape, size, and the like of the through hole 490f are not limited to a great extent.

As described above, if the fastening portion 49c is formed by bending it several times including the second to fourth fastening portions 492c, 493c and 494c in addition to the first fastening portion 491c, And can have a high strength. Thereby, it is possible to have a sufficient strength at the portion to be fastened to the frame 20. [

A bracket portion (not shown) that covers the front surface of the fastening portion 49c (that is, at least between the first fastening portion 491c and the fourth fastening portion 494c) can do. The bracket portion can be detachably fixed to the coupling portion 49c by a latch structure or the like. However, the present invention is not limited thereto, and the bracket part can be fixed by various methods.

A fixing portion 49d fixed to the coupling portion 49c may be further formed at a portion of the second case portion 492 corresponding to the coupling portion 49c. The fixing portion 49d includes a first fixing portion 491d which is in contact with (or is in close contact with) the third fixing portion 493c and a second fixing portion 491d which is bent from the first fixing portion 491c and extends to the outer portion 499, 499. The first and second fastening portions 492d, The fastening holes 490e and 490g can be positioned at positions corresponding to the first fastening portion 491d and the third fastening portion 493c and the fastening member 64 is fastened to the fastening holes 490e and 490g. The first case portion 491 and the second case portion 492 can be more firmly fastened. Thus, the airtight structure and the fixing structure of the first case 49 can be improved. Further, the fastening member 64 or the like may be used for grounding or the like in accordance with the embodiment.

In this embodiment, the first case 49 is fixed or attached on the solar cell panel 10. That is, in this embodiment, the adhesive member 69 is attached to the bottom surface (for example, the bottom surface 4942 of the first case portion 491) of the first case 49 adjacent to the solar cell panel 10 So that the solar cell panel 10 and the first case 49 (or the integrated inverter 30) are stably fixed to have excellent airtightness, sealing and waterproof characteristics.

More specifically, the adhesive member 69 may be formed so as to surround the first through-hole 49a of the first case 49 in a plan view and have a closed space therein. This allows the ribbon 122 to be positioned inside the first case 49 by the first through hole 49a formed in the first case 49, And separates and separates the space between the first case (10) and the first case (49) and the external space. Thus, the first case 49 having the first through-hole 49a can be sealed.

As described above, the first case 49 includes the first through hole 49a and the second through hole 49b, and the second through hole 49b includes the AC output cable 38, The first through hole 49a must be opened so that the ribbon 122 can smoothly pass through, while the airtight property can be maintained. Accordingly, if a separate adhesive member 69 is not formed, foreign substances, moisture, impurities and the like may be introduced into the first case 49 by the first through hole 49a. Accordingly, in this embodiment, the adhesive member 69 surrounding the space opened by the first through-hole 49a is formed so that the outside and the inside of the first case 49 communicate with each other through the first through-hole 49a Can be prevented. Thus, the airtightness, sealing, and waterproof characteristics of the first case 49 can be improved. In addition, the first case 49 can be fixed to the solar cell panel 10 by the adhesive member 69 to improve the fixing stability.

For example, the adhesive member 69 may have a shape such as a circular shape, a polygonal shape, or the like when viewed in plan view. In the drawing, the first through hole 49a may be formed in a square shape and the adhesive member 69 may be formed in a square shape. However, the present invention is not limited thereto, and the adhesive member 69 may have various structures and shapes to prevent the communication between the first through-hole 49a and the first case 49.

In this embodiment, since the integrated inverter 30 is provided with the first through hole 49a for connecting the ribbon 122 and the terminal 31, the adhesive member 69 is formed to improve airtight characteristics. On the other hand, the conventional inverter does not have a first through hole for connection with the solar cell 12.

As the adhesive member 69, various materials having excellent adhesive properties, sealing properties and the like can be used. For example, a sealant or the like may be used for the adhesive member 69. However, the present invention is not limited thereto. Accordingly, the adhesive member 69 is made of a structure made of resin, metal, or the like, and can be variously modified, for example, by bonding the first case 49 and the solar cell panel 10 by heat or the like.

The first case 49 may include various materials capable of maintaining an outer shape or an outer surface and capable of protecting various parts, articles, members, and the like located therein. For example, the first case 49 may be composed of various materials such as resin, metal, surface-treated metal (or coated metal), and the like. When the first case 49 is made of resin, it is possible to improve the insulation characteristic and reduce the cost. If the first case 49 is made of metal, the structural stability can be improved and the first case 49 can be used for grounding or the like. In this case, if the first case 49 is made of a surface-treated metal (or a coated metal), a substance having conductivity may be located inside and a substance having an insulating characteristic may be placed around the first case 49. As a result, the corrosion resistance can be improved by the insulating material, the appearance can be improved, and the metal material located inside can be applied to a ground structure or the like. In one example, the first case 49 may be made of an anodized metal (for example, anodized aluminum). In addition, the hue of the first case 49 can be adjusted together during the surface treatment (for example, an anodizing treatment) to further improve the appearance. For example, the first case 49 may have a color such as black, brown or silver.

In the present embodiment, the second case 59 may be located inside the first case 49. [ The second case 59 will be described in more detail with reference to Figs. 4 to 6. Fig. 6 shows the internal space portion 594 of the second case 59 and the terminal 31, the bypass diode 33, the inverter member 35 and the potting member 372 located therein .

The second case 59 serves to support or accommodate the terminal 31, the bypass diode 33, the inverter member 35 and the like so that they can be easily separated from the first case 49. The bypass diode 33, the inverter member 35, and the like at a time by separating the second case 59 after opening the first case 49 when repair, replacement, And can be separated from the first case 49. By inserting the second case 59 in which the terminal 31 to be replaced, the bypass diode 33, the inverter member 35 and the like are supported or accommodated into the first case 49 when replacement is required, So that the replacement can be performed simply.

The second case 59 may also serve as a receiving portion for holding the potting member 372 that encloses the terminal 31, the bypass diode 33, and the inverter member 35 together. That is, the potting member 372 is injected or poured into the second case 59 while the terminal 31, the bypass diode 33, the inverter member 35, and the like are positioned inside the second case 59, The terminal 31, the bypass diode 33, the inverter member 35, and the like can be integrated together. This simplifies the process of applying the potting member 372 and makes the integrated structure of the bypass diode 33 and the inverter member 35 more rigid.

The second case 59 may have various structures that can support or accommodate the terminal 31, the bypass diode 33, the inverter member 35, and the like together.

For example, in this embodiment, the second case 59 includes a bottom surface 5942 located in a portion of the first case 49 excluding the first through hole 49a, and a bottom surface 5942 extending from the bottom surface 5942 And an inner space portion 594 having a side surface 5944. When the side surface 5944 is entirely formed corresponding to all the edges of the bottom surface 5942, the receiving portion for containing the potting member 372 can be more effectively performed. However, the present invention is not limited thereto, and the inner space portion 594 may be formed as a bottom surface 5942 without having an inner space. The second case 59 may include a lid portion 592 that covers the upper surface of the inner space portion 594. The lid portion 592 is formed to expose the first through-hole 49a and the terminal 31 so as not to cover the first through-hole 49a and the terminal 31, It is possible to make the connecting process of the connecting member more easily. However, the present invention is not limited thereto, and it is also possible that the lid part 592 is not separately provided.

In addition, the second case 59 can play a role of maintaining the insulation distance of the circuit pattern of the circuit board 37 or the like (if the first case 49 has conductivity). In this case, the second case 59 may be formed of an insulating material so as to maintain the insulation distance between the first case 49 and the circuit board 37. However, the present invention is not limited thereto. In other words, even when the first case 49 has conductivity, the second case 59 can be made of a conductive material to have conductivity. Alternatively, the second case 59 may not be provided. The second case 59 may further include another structure for satisfying the insulation distance when the second case 59 does not fulfill the insulation distance or the second case 59 is not provided. This will be described in more detail with reference to FIG.

8 is a perspective view showing various modifications that can be applied to the integrated inverter 30 of the solar cell module 100 of FIG. For clarity and simplicity, only the components necessary for the explanation are shown in FIG. 8, and the other constitutional views are omitted.

8 (a), the terminal 31, the bypass diode 33, the inverter member 35, the circuit board 37, and the like are connected to the potting member 372 or a separate insulating member It can be wrapped entirely by material. A bypass diode 33, an inverter member 35, a circuit 35, and the like, which are surrounded by a potting member 372 or a separate insulating material inside the first case 49 without the second case 59. [ The substrate 37 or the like can be positioned. Then, the insulating distance can be satisfied by the potting member 372 or another insulating material.

8 (b), the first case 49 and the second case 49 may be provided in the interior of the first case 49 (for example, the inner surface of the first case portion 492) 59 or the circuit board 37 and spacers 72 containing insulating material may be located at regular intervals. Then, the insulating distance can be satisfied by the spacer 72. The shape, arrangement, and the like of the spacer 72 can be variously modified.

As another example, an insulating pad (not shown) may be formed on the inner surface of the first case 49 (for example, the inner surface of the first case portion 492) 74 can be attached. 8 (d), an insulating sheet 76 is provided between the first case 49 and the second case 59 or between the first case 49 and the circuit board 37, And so on. Alternatively, the first case 49 may be coated with an insulating material or subjected to a surface treatment so as to satisfy the insulation distance. Various methods and structures may be applied.

4 to 6, although the second case 59 is not formed at a portion where the first through-hole 49a is formed, for example, the present invention is not limited thereto and the second case 59 It is also possible that an opening corresponding to the first through hole 49a is formed. A variety of structures can be applied to the second case 59 so that the ribbon 122 passing through the first through hole 49a can be connected to the ribbon 122 through the second case 59. [

The first case 49 and the second case 59 may be detachably fixed by various structures. For example, in this embodiment, a press fitting nut (pneumatic nut) 490h is positioned in the first case 49, and a fastening hole 590f is formed in the second case 59 at a portion corresponding to the press fitting nut 490h . The press fitting nut 490f may be fixed to the first case 49 by a caulking process or the like. The second case 59 is fastened to the first case 49 by fastening the fastening member 66 to the press-fitting nut 490f in a state where the fastening hole 590f of the second case 59 is positioned on the press fitting nut 490f ). The second case 59 can be easily separated from the first case 49 by releasing the fastening member 66 while firmly fixing the second case 59 and the first case 49 by the fastening member 66 .

At this time, the press-fitting nut 490h and the fastening hole 590f for fixing are located on both sides of the terminal 31 (or the first through-hole 49a) to which the ribbon 122 is connected and the first through-hole 49a The first case 49 and the second case 59 are fastened to each other at a position where the terminal 31 to which the ribbon 122 passed through the first and second cases 59 and 59 is connected. So that the ribbon 122 can be stably fastened.

A terminal 31, a bypass diode 33, an inverter member 35, and the like are located inside the case 39. Located. In this embodiment, the terminals 31, the bypass diode 33, and the inverter member 35 are co-located on the circuit board 37 and integrated by the circuit board 38. The terminal 31 and the bypass diode 33 to which the ribbon 122 is connected are positioned on the circuit board 37 in the present embodiment.

The circuit board 37 may be a substrate on which various circuit patterns (wiring, terminals, various parts for connecting each other in the circuit board 37, etc.) are formed. As the circuit board 37, various structures can be used, for example, a printed circuit board can be used. In the drawing, 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 to this, and a plurality of circuit boards 37 may be provided on the other circuit boards (for example, flexible printed circuit boards (FPCB) A connector, or the like. Other various modifications are possible.

In this embodiment, the terminal 31 and / or the bypass diode 33 are located on the circuit board 37. And thus the terminal and the bypass diode are located in the junction box and are not formed on the circuit board. When the terminal 31 and / or the bypass diode 33 are 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 the circuit pattern of the circuit board 37 to simplify the connection structure. Further, the heat radiation characteristics can be improved by a metal plate (for example, a copper plate) constituting the circuit board 37 or the like. In particular, the bypass diode 33 generates a lot of heat during driving. By forming such a bypass diode 33 on the circuit board 37, the heat radiation characteristic can be greatly improved.

The terminal 31 to which the ribbon 122 is connected is located at the edge of the circuit board 37 adjacent to the first through hole 49a. When the terminal 31 to which the ribbon 122 is connected is positioned adjacent to the first through hole 49a, the path of the ribbon 122 can be shortened and the ribbon 122 can be easily fixed to the terminal 31. [ The fixing structure of the ribbon 122 and the terminal 31 will be described in more detail with reference to Fig. 9 is a perspective view showing a terminal 31 that can be applied to the integrated inverter 30 of the solar cell module 100 shown in FIG. 1 and a ribbon 122 connected thereto.

9, a plurality of terminals 31 may be formed so as to correspond one-to-one with the ribbons 122 corresponding to the number of the ribbons 122. In this embodiment, the terminal 31 may have a structure in which the ribbon 122 can be detached. For example, the terminal 31 of the present embodiment may include an upper portion 312 located at the top of the ribbon 122 and a lower portion 314 located at the bottom of the ribbon 122. The upper portion 312 includes a first upper portion 312a secured to the circuit board 37 at one location of the ribbon 122 and extending therefrom to an upper portion of one side of the ribbon 122, And a second upper portion 312b that is fixed to the circuit board 37 at the other side and extends from the upper side to the other side of the ribbon 122 and is spaced apart from the first upper portion 312a. The lower portion 314 located below the first upper portion 312a and the second upper portion 312b is located farther away from the first through hole 49a than the first and second upper portions 312a and 312b, May extend parallel to the ribbon 122 to intersect the first and second upper portions 312a, 312b after being secured to the circuit board 37 and extending upwardly therefrom. The portion of the lower portion 314 that intersects the first and second upper portions 312a and 312b may be formed such that the middle portion thereof protrudes above the end portion. Then, the middle portion of the lower portion 314 is positioned closer to the first and second upper portions 312a, 312b than the end portion.

The upper portion 312 and the lower portion 314 are spaced apart from each other by pressing the portion of the lower portion 314 of the terminal 31 fixed to the circuit board 37 downward to separate the upper portion 312 and the lower portion 314 314 by removing the force pressing the lower portion 314 of the terminal 31 after inserting the ribbon 122 between the lower portion 314 and the upper portion 312, The middle portion of the upper portion 312) and the lower portion 314. The ribs 122 may be formed of any suitable material. When the ribbon 122 is separated from the lower portion 314 by pressing the portion fixed to the circuit board 37 downward to separate the ribbon 122 from the upper portion 312 and the lower portion 314 do.

The upper portion 312 and the lower portion 314 of the terminal 31 may be secured to the circuit board 37 in a variety of ways. For example, latch structures (or latching portions) 312c and 314c are formed at portions fixed to the circuit board 37 in the upper portion 312 and the lower portion 314, A latching hole 37c can be formed in the latching hole 37c. The terminals 31 can be easily attached and detached by inserting or disassembling the latch structures 312c and 314c of the upper portion 312 and the lower portion 314 into the latching holes 37c of the circuit board 37 . However, the present invention is not limited thereto, and the terminal 31 may be fixed on the circuit board 37 in a non-removable manner, and various modifications are possible.

In this way, when the terminal 31 needs to be repaired, replaced, or the like, it is possible to easily remove the ribbon 122 from the terminal 31 and remove the ribbon 122 again when necessary Easy to connect. However, the present invention is not limited thereto, and the terminal 122 may have various structures. The terminal 31 may be formed of a metal pad, a soldering pad, or the like, and the ribbon 122 may be bonded to the terminal 31 by welding, soldering, or the like. The ribbon 122 can be fixed to the terminal 31 in a detachable manner. Then, the structure of the terminal 31 can be simplified and the cost can be reduced.

4 to 6, a bypass diode 33 connected to the terminal 31 by a circuit pattern extending from the terminal 31 is located on the circuit board 37. The bypass diode 33 is provided in a number (n-1) smaller than the number (n) of the terminals 31 by one. Each bypass diode 33 can be connected to two terminals 31 between two terminals 31 by a circuit pattern. When a portion that is blocked by the solar panel 10 occurs or a failure occurs and an area where power generation is not generated occurs, the bypass diode 33 bypasses the corresponding portion and flows a current to protect the corresponding region do. Various structures known as the structure of the bypass diode 33 can be applied.

The circuit board 37 is provided with an inverter member 35 connected to the bypass diode 33 by a circuit pattern extending from the bypass diode 33. [ The inverter member 35 serves to convert the direct current (or direct current voltage) provided from the bypass diode 33 into an alternating current (alternating voltage). The inverter member 35 includes a DC-AC inverter 352 for converting a DC current into an AC current, and further includes a current sensor 354 for stably switching a DC current to an AC current, a capacitor 356, - DC converter 358, and the like. The current sensor 354, the capacitor 356, the DC-DC converter 358 and the DC-AC inverter 352 constituting the inverter member 352 are connected to the terminal 31 and / or the bypass diode 33, And the circuit board 37 or a circuit pattern formed thereon.

The current sensor 354 is connected to the 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 or the like by the circuit pattern. The current sensor 354 senses 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, . In this embodiment, the bypass diode 33 and the current sensor 354 can be connected by the circuit pattern formed on the circuit board 37 inside the same case 39. By connecting the bypass diode 33 and the current sensor 354 in this manner, a separate output cable or the like is not required, so that the structure can be simplified.

The current sensor 354 is connected to a capacitor 356 for storing a DC current passed through the current sensor 354 and delivering a constant voltage current to the DC-DC converter 358. The current sensor 354 and the capacitor 356 may also be connected by the circuit pattern formed on the circuit board 37 inside the same case 39. [

The current of the voltage uniformed in the capacitor 356 is transferred to the DC-to-DC converter 358 so that a certain level of other DC voltage can be converted. In this embodiment, a plurality of DC-DC converters 358 may be provided. DC converter 358 can reduce the thickness of each DC-DC converter 358 compared with the case where a single DC-DC converter 358 is provided, The thickness of the extension portion 24 can be made smaller than the height of the extension portion 24. However, the present invention is not limited thereto, and it is also possible to provide one DC-DC converter 358. [

The DC current passed through the DC-DC converter 358 may be transferred to the DC-AC inverter 352 and converted to an AC voltage. The 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 second through hole 49b of the case 39. [

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

6, the bypass diode 33, the inverter member 35, and the like located on the circuit board 37 and the circuit board 37 can be integrally enclosed by the potting member 372 . In this embodiment, the potting member 372 may be formed so as to fill the inside space portion 594 of the second case portion 590. The potting member 372 can be formed on both sides of the circuit board 37 so as to have a planar shape that is the same as or similar to the internal space portion 594 of the second case portion 590 and has a uniform overall thickness. As a result, the insulating properties can be improved and the mechanical stability can be improved. Further, the bypass diode 33, the inverter member 35, and the circuit board 37 can be integrated together. However, the present invention is not limited thereto, and the potting member 372 may be thinly coated along the outer surface of various parts formed on the circuit board 37 to have the same or similar shape as the upper shape of the various parts of the circuit board 37 It is also possible to have an upper surface Such a potting member 372 may be formed by spraying or the like. Alternatively, the potting member 372 may be located only on a part of the circuit board 37 that needs to be potted. Other various structures and shapes of the potting member 372 can be applied.

The integrated inverter 30 of the solar cell module 100 of the above-described structure includes a bypass diode 33 for providing a terminal 31 connected to the ribbon 122 and / or a bypass path, The inverter member 35 to be switched is formed integrally or integrally. By forming them integrally, the installation process can be simplified and the structure can be simplified. By connecting the bypass diode 33 and the inverter member 35 in a circuit pattern, it is not necessary to use an output cable (that is, a DC output cable) for connecting them, It is possible to prevent damage to the solar cell panel 10 that may occur.

On the other hand, conventionally, the junction box and the inverter should be separately manufactured and fixed to the respective solar panel or frame, and then the (+) output cable and the (-) output cable of the junction box should be connected to the inverter. The AC output cable of the inverter also exists. As a result, the installation space is increased and the installation time is lengthened, and the solar panel 10 is impacted during transportation or use by the three output cables, so that the solar panel 10 may be damaged or broken.

Features, structures, effects and the like according to the above-described embodiments are included in at least one embodiment of the present invention, and the present invention is not limited to only one embodiment. Further, the features, structures, effects, and the like illustrated in the embodiments may be combined or modified in other embodiments by those skilled in the art to which the embodiments belong. Therefore, it should be understood that the present invention is not limited to these combinations and modifications.

100: solar cell module
10: Solar panel
20: frame
30: Integrated inverter
31: Terminal
33: Bypass Diode
35: Inverter member
37: circuit board
39: Case
372: Potting member

Claims (20)

1. An integrated inverter used in a solar cell module including a solar panel,
A terminal connected to the solar panel;
A bypass diode electrically connected to the terminal; And
And an inverter member including a DC-AC inverter electrically connected to the bypass diode
/ RTI >
Wherein at least one of the terminal and the bypass diode is integrated with the DC-AC inverter. The method according to claim 1,
Wherein at least one of the terminal and the bypass diode and the DC-AC inverter are located inside the case and integrated by the case, formed integrally with the circuit board and integrated by the circuit board or wrapped together by the potting member And is integrated by the potting member. The method according to claim 1,
Wherein at least one of the terminal and the bypass diode is located on a circuit board. The method according to claim 1,
Wherein the terminal, the bypass diode, and the DC-AC inverter are formed on a circuit board and connected to each other by a circuit pattern. The method according to claim 1,
Wherein the integrated inverter further comprises one AC output cable for externally supplying the AC power converted by the integrated inverter. The method according to claim 1,
The bypass diode, and the DC-AC inverter are located inside the first case,
Wherein the first case includes a first through hole for connecting the solar cell and the terminal, and a second through hole for connecting the DC-AC inverter and the outside. The method according to claim 6,
Wherein an adhesive member for bonding with the solar cell panel is disposed in the first case,
And the joining member is formed so as to surround the through hole when viewed in plan. The method according to claim 6,
Wherein the terminal is connected to a ribbon drawn from a solar cell of the solar cell panel,
And the ribbon is connected to the terminal through the first through hole. 9. The method of claim 8,
And the ribbon is detachably fixed to the terminal. The method according to claim 6,
And a second case located inside the first case,
A circuit board on which the terminal, the bypass diode and the DC-AC inverter are formed, and a potting member surrounding the circuit board, the bypass diode, and the DC-AC inverter are located inside the second case. The method according to claim 6,
The first case includes:
A first case portion including an inner space portion and a joining flange extending from the upper inner space portion and on which the joining member is located;
And a second case portion joined to the first case portion by the joining member to cover the first case portion. 12. The method of claim 11,
Wherein the joint flange extends all over the upper portion of the inner space portion and surrounds the inner space portion when viewed in plan,
Wherein the joint flange is formed of a flat surface formed on the same plane. 12. The method of claim 11,
Wherein the second case portion has an inner portion having a flat surface inside and a rim portion located outside the inner portion and inclined away from the joining flange toward the outside. The method according to claim 6,
Wherein the first case has a fastening portion extending to be fastened to the frame of the solar cell module. The method according to claim 1,
Wherein the inverter member comprises:
A current sensor for detecting an abnormality of a direct current passing through the bypass diode;
A capacitor for storing a direct current voltage passing through the current sensor; And
A DC-DC converter converting the DC voltage provided from the capacitor into a DC voltage of different magnitude and providing the DC voltage to the DC-
Lt; / RTI >
Wherein the current sensor and the bypass diode are connected to each other on a circuit board by a circuit pattern. 16. The method of claim 15,
Wherein the plurality of DC-DC converters are provided. An integrated inverter according to any one of claims 1 to 16; And
And a solar cell panel
And a solar cell module. 18. The method of claim 17,
Further comprising a frame for fixing an outer frame portion of the solar cell panel,
Wherein the frame includes a panel inserting portion into which at least a part of the solar cell panel is inserted and an extending portion extending rearward from the panel inserting portion,
Wherein the integrated inverter is located on a rear surface of the solar cell panel,
Wherein the thickness of the integrated inverter is equal to or less than the height of the extension. 19. The method of claim 18,
Wherein the integrated inverter includes a fastening portion fastened to the frame,
A locking portion is formed in the locking portion,
And a latching groove is formed at a position corresponding to the latching portion in the frame. 19. The method of claim 18,
And at least a part of the fastening portion is located inside the extending portion.

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