CN212518868U

CN212518868U - BIPV (building integrated photovoltaics) waterproof component and photovoltaic module

Info

Publication number: CN212518868U
Application number: CN202021182371.3U
Authority: CN
Inventors: 单康康; 张愿成
Original assignee: Xian Longi Green Energy Architecture Technology Co Ltd
Current assignee: Longi Solar Technology Co Ltd
Priority date: 2020-06-23
Filing date: 2020-06-23
Publication date: 2021-02-09
Anticipated expiration: 2030-06-23

Abstract

The utility model provides a BIPV waterproof component and photovoltaic module relates to solar photovoltaic technology field, and BIPV waterproof component includes frame subsection and overlap joint subsection, and the frame subsection includes relative first frame and the second frame that sets up, and one side of first frame sets up first bridging plate, and one side of second frame sets up first guiding gutter, and under the condition of first frame and second frame assembly, first bridging plate shelters from the notch of first guiding gutter. Rainwater between two adjacent photovoltaic modules can directly flow into the first water chute through the first lapping plate, and is discharged through the first water chute, so that the waterproof problem between two adjacent photovoltaic modules can be solved. In the installation process of the photovoltaic array, a large number of sealing strips can be prevented from being arranged between adjacent photovoltaic modules, and sealing glue is coated, so that the installation efficiency of the photovoltaic modules can be improved, and in the use process of the photovoltaic array, the hidden danger of water leakage caused by the aging of the sealing strips and the sealing glue can be avoided.

Description

BIPV (building integrated photovoltaics) waterproof component and photovoltaic module

Technical Field

The utility model relates to a solar photovoltaic technology field especially relates to a BIPV waterproof component and photovoltaic module.

Background

Compared with the traditional power generation technology, the photovoltaic power generation has the advantages of rich energy, simple power generation process, no noise, no pollution and the like. Building Integrated Photovoltaics (BIPV) is a technology for integrating a Photovoltaic array (formed by splicing a plurality of Photovoltaic modules) into a Building, such as a Photovoltaic tile roof, a Photovoltaic curtain wall, a Photovoltaic daylighting roof and the like. The combination of the photovoltaic array and the building does not occupy extra ground space, and the photovoltaic array is the best installation mode for the wide application of the photovoltaic power generation technology. Wherein, when photovoltaic array is as photoelectricity tile roof or photoelectricity daylighting top, photovoltaic array need possess waterproof function.

At present, in order to realize the waterproof function of the photovoltaic array, it is a common practice to arrange a sealing strip between adjacent photovoltaic modules and coat the sealing strip with a sealant for sealing. When the sealing strips and the sealing glue are used for sealing, a large number of sealing strips need to be arranged and the sealing glue needs to be coated in the installation process of the photovoltaic array, so that the installation process is complicated, and the cost is high. In addition, the sealing strips and the sealing glue are easy to age, and the hidden danger of water leakage is easy to cause.

SUMMERY OF THE UTILITY MODEL

The utility model provides a BIPV waterproof component and photovoltaic module aims at solving photovoltaic array's waterproof aquatic, and the installation is loaded down with trivial details, the cost is higher to and sealing strip and sealed glue are very easily ageing, cause the problem of the hidden danger of leaking easily.

The embodiment of the utility model provides a BIPV waterproof component is provided to the first aspect of the embodiment, including frame subsection and overlap joint subsection, the frame subsection includes relative first frame and the second frame that sets up, the overlap joint subsection includes first lap joint board and first guiding gutter;

the first lap joint plate is arranged on one side, away from the second frame, of the first frame and extends in the direction away from the second frame;

the first water chute is arranged on one side, away from the first frame, of the second frame, and the first water chute is arranged along the length direction of the second frame;

under the condition that the first frame is assembled with the second frame, the first lap joint plate shields the notch of the first water chute in the length direction.

Optionally, one side of the first water chute departing from the second frame is matched with one side of the first frame departing from the second frame in shape, and under the condition that the first frame is assembled with the second frame, one side of the first water chute departing from the second frame is abutted to the first frame, or one side of the first water chute departing from the second frame is separated from the first frame by a first preset distance.

Optionally, a second strap plate is arranged on one side of the first water chute opposite to the second frame, the second strap plate extends towards a direction close to the second frame, and the second strap plate abuts against the first strap plate or the second strap plate and the first strap plate are separated by a second preset distance under the condition that the first frame is assembled with the second frame.

Optionally, a barb structure is arranged on one side of the first overlapping plate close to the first water chute, and under the condition that the first border and the second border are assembled, part or all of the barb structure is located in the first water chute.

Optionally, the frame subsection further includes a third frame and a fourth frame which are oppositely disposed, and the lap joint subsection further includes a third lap plate and a fourth lap plate;

the first frame, the second frame, the third frame and the fourth frame are connected in a matching manner to obtain the frame parts;

the third lap joint plate is arranged on one side, away from the fourth frame, of the third frame and extends towards the direction away from the fourth frame;

the fourth lap joint plate is arranged on one side, away from the third frame, of the fourth frame and extends in the direction away from the third frame;

the fourth lap joint plate is superposed above the third lap joint plate in a state where the third bezel is assembled with the fourth bezel.

Optionally, the lap joint section further comprises a seal disposed between the third lap plate and the fourth lap plate in a state where the third rim is assembled with the fourth rim.

Optionally, a groove is formed in the third strap and/or the fourth strap, the sealing member includes a first section and a second section, the first section is fixed in the groove, one side of the second section is fixedly connected to the first section, and the other side of the second section abuts against the third strap or the fourth strap when the third frame and the fourth frame are assembled.

Optionally, the lap sub further comprises a second flume;

the second water chute is arranged on one side, away from the fourth frame, of the third frame, and the second water chute is arranged along the length direction of the third frame;

the third lapping plate is positioned at a notch of the second water guide groove along the length direction, and the width of the third lapping plate is smaller than that of the second water guide groove.

Optionally, one side of the fourth frame, which is away from the third frame, is provided with a fifth overlapping plate, the fifth overlapping plate extends in a direction away from the third frame, and the fifth overlapping plate shields the notch of the second water guiding groove in the length direction when the third frame is assembled with the fourth frame.

Optionally, one side of the second water chute departing from the third frame is matched with one side of the fourth frame departing from the third frame in shape, and one side of the second water chute departing from the third frame abuts against the fourth frame when the third frame is assembled with the fourth frame.

Optionally, a bearing plate is arranged on one side of the first frame, which is close to the second frame, and one side of the second frame, which is close to the first frame; the loading board is used for bearing battery plate subsections in the photovoltaic assembly, one side of each battery plate subsection deviating from the loading board is flush with the first frame and the second frame respectively, and sealing glue layers are arranged between the battery plate subsections and the first frames and between the battery plate subsections and the second frames respectively.

Optionally, the bearing plate is arranged on one side of the third frame, which is close to the fourth frame, and one side of the fourth frame, which is close to the third frame; the battery piece subsection deviates from one side of the loading plate respectively with the third frame with the fourth frame parallel and level, the battery piece subsection with between the third frame and the battery piece subsection with be provided with sealing glue layer between the fourth frame respectively.

The embodiment of the utility model provides a photovoltaic module is provided in the second aspect, include the embodiment of the utility model provides a BIPV waterproof component that the first aspect provided.

The embodiment of the utility model provides an in, BIPV waterproof component includes frame subsection and overlap joint subsection, and the frame subsection includes relative first frame and the second frame that sets up, and one side of first frame sets up first bridging plate, and one side of second frame sets up first guiding gutter, and under the condition of first frame and second frame assembly, first bridging plate shelters from the notch of first guiding gutter, can solve two adjacent photovoltaic module between waterproof problem. In the installation process of the photovoltaic array, a large number of sealing strips can be prevented from being arranged between adjacent photovoltaic modules, and sealing glue is coated, so that the installation efficiency of the photovoltaic modules can be improved, and in the use process of the photovoltaic array, the hidden danger of water leakage caused by the aging of the sealing strips and the sealing glue can be avoided.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments of the present invention will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor.

Fig. 1 shows a schematic view of a photovoltaic array in an embodiment of the invention;

fig. 2 shows a front view of a BIPV waterproofing member in an embodiment of the present invention;

fig. 3 shows a schematic assembly diagram of a first frame and a second frame in an embodiment of the invention;

fig. 4 shows an assembly diagram of another first and second rims in an embodiment of the present invention;

fig. 5 shows an assembly diagram of a third frame and a fourth frame in an embodiment of the invention;

fig. 6 shows a usage state diagram of the third frame and the fourth frame in the embodiment of the present invention;

fig. 7 shows a schematic diagram of a splicing surface of a second frame in an embodiment of the present invention;

fig. 8 shows a schematic view of a splicing surface of a third frame in an embodiment of the invention;

fig. 9 shows a schematic view of a splicing surface of a first frame in an embodiment of the invention;

fig. 10 is a schematic view illustrating a first water chute and a sleeve core in an embodiment of the present invention;

fig. 11 shows a schematic assembly diagram of a first frame and a second frame according to another embodiment of the present invention;

fig. 12 shows an assembly diagram of another third frame and a fourth frame in an embodiment of the invention.

Description of reference numerals:

100-cell section, 101-first border, 1011-first side plate, 1012-first lap plate, 1013-barb structure, 102-second border, 1021-second side plate, 1022-first water chute, 1023-second lap plate, 103-third border, 1031-third side plate, 1032-third lap plate, 1033-second water chute, 1034-first support plate, 104-fourth border, 1041-fourth side plate, 1042-fourth lap plate, 1043-fifth lap plate, 200-bracket, 301-groove, 302-first section, 303-second section, 401-first section, 402-second section, 403-third section, 404-fourth section, 500-nest core, 501-interface, 601-first section, 602-buckle plate, 603-fixing plate, 604-second supporting plate, 605-lug, 701-supporting piece, 702-connecting piece, 703-sealant layer and 704-isolating piece.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, of the embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1, fig. 1 shows a schematic diagram of a photovoltaic array in an embodiment of the present invention, as shown in fig. 1, the photovoltaic array is formed by splicing a plurality of photovoltaic modules, the photovoltaic array is installed on a support 200, the photovoltaic modules include a cell subsection 100, and a BIPV waterproof member located around the cell subsection 100, the BIPV waterproof member includes a frame subsection and a lap subsection. Wherein the cell subsection 100 is assembled from a plurality of cell strings, a photovoltaic module back sheet and a photovoltaic module front sheet, and for understanding the cell subsection 100 and the photovoltaic module, reference may be made to the prior art.

Referring to fig. 2 and 3, fig. 2 shows a front view of a BIPV waterproof component in an embodiment of the present invention, fig. 3 shows an assembly schematic diagram of a first frame and a second frame in an embodiment of the present invention, and the frame sections include a first frame 101 and a second frame 102 which are arranged oppositely, and the lap joint sections include a first lap plate 1012 and a first water guiding groove 1022.

For example, the frame sections may further include a third frame 103 and a fourth frame 104 which are oppositely disposed, and the first frame 101, the second frame 102, the third frame 103, and the fourth frame 104 may be sequentially connected in an end-to-end fit manner by welding, bolting, or snapping, so as to form a rectangular frame section around the periphery of the battery plate section 100. Wherein, a side of the first frame 101 close to the battery plate subsection 100, a side of the second frame 102 close to the battery plate subsection 100, a side of the third frame 103 close to the battery plate subsection 100, and a side of the fourth frame 104 close to the battery plate subsection 100 are respectively provided with a bearing mechanism, and the battery plate subsection 100 is fixed in the frame subsection through the bearing mechanisms. The first frame 101, the second frame 102, the third frame 103, and the fourth frame 104 may be made of a metal material having a relatively high strength, such as aluminum alloy and stainless steel. The specific structure of the bearing mechanism, the specific shape of the frame sections, the connection mode among the first frame, the second frame, the third frame and the fourth frame, etc. may be set as required, and this embodiment does not limit this.

In this embodiment, the first frame 101 and the second frame 102 are oppositely disposed at two sides of the cell subsection 100, and the first frame 101 and the second frame 102 are used for splicing two adjacent photovoltaic modules while bearing the cell subsection 100. Referring to fig. 1 and 3, in two adjacent photovoltaic modules, the first frame 101 of one photovoltaic module is assembled with the second frame 102 of the other photovoltaic module, so as to splice the two adjacent photovoltaic modules together.

Illustratively, the first side frame 101 includes a first side plate 1011, the first side plate 1011 constitutes a main body portion of the first side frame 101, a first overlapping plate 1012 is disposed on a side of the first side plate 1011 facing away from the second side frame 102, and the first overlapping plate 1012 extends in a direction away from the second side frame 102.

As shown in fig. 3, a bearing mechanism is installed on the first side plate 1011 near the second frame 102, that is, near the battery plate subsection 100, and connects the battery plate subsection 100 and the first frame 101 through the bearing mechanism. The first side plate 1011 is provided with a first bridging plate 1012 on one side away from the second frame 102, that is, on one side away from the battery plate subsection 100, and the first bridging plate 1012 and the battery plate subsection 100 are oppositely arranged on two sides of the first side plate 1011. The first overlapping plate 1012 intersects the first side plate 1011, the first overlapping plate 1012 is disposed along the length direction of the first side plate 1011, and the first overlapping plate 1012 has the same length as the first side frame 101. The first strap 1012 extends a distance in a direction away from the first side plate 1011 (away from the second frame opposite the first frame) to form a first strap 1012 having a certain width. The first bridging plate 1012 is located on the upper surface of the photovoltaic module (the upper surface of the photovoltaic module is the side of the photovoltaic module receiving the sunlight), or at a certain distance from the upper surface of the photovoltaic module, and the position of the first bridging plate 1012 in the first side plate 1011 can be set according to the requirement. The first overlapping plate 1012 may be perpendicular to the first side plate 1011 to form a regular first rim 101. The first strap 1012 and the first side plate 1011 may be integrally formed, or may be connected by welding or the like. When the first overlapping plate 1012 and the first side plate 1011 are connected by welding or the like, the first overlapping plate 1012 and the first side plate 1011 are hermetically connected.

Illustratively, the second bezel 102 includes a second side plate 1021, the second side plate 1021 constitutes a main body portion of the second bezel 102, and a first water chute 1022 is disposed along a length direction of the second bezel 102 on a side of the second side plate 1021 facing away from the first bezel 101.

As shown in fig. 3, a bearing mechanism is installed on one side of the second side plate 1021 near the first frame 101, that is, near the battery plate subsection 100, and the battery plate subsection 100 and the second frame 102 are connected through the bearing mechanism. The side of the second side plate 1021 remote from the first frame 101, that is, the side remote from the battery plate subsection 100, is provided with a first water guiding trough 1022, and the first water guiding trough 1022 and the battery plate subsection 100 are oppositely arranged on two sides of the second side plate 1021. The first water guiding channel 1022 is disposed along the length direction of the second frame 102, the length of the first water guiding channel 1022 is the same as that of the second frame 102, and a certain distance extends from the bottom of the first water guiding channel 1022 to a direction away from the second side plate 1021 (away from the first frame opposite to the second frame), so as to form the first water guiding channel 1022 with a certain width. The first water guiding trough 1022 is provided with a notch along the length direction, the notch along the length direction faces the upper surface of the photovoltaic module, and meanwhile, the two ends of the first water guiding trough 1022 are open, so that rainwater in the first water guiding trough 1022 can be discharged through the openings at the two ends. The first water chute 1022 may be located at an end of the second side panel 1021 remote from the cell segment 100, i.e., at the bottom of the photovoltaic module. The first water guide channel 1022 may be integrally formed with the second side plate 1021, and the second side plate 1021 constitutes one of the side walls of the first water guide channel 1022. Alternatively, the first water guide channel 1022 may be connected to the second side plate 1021 by welding or the like, and when the first water guide channel 1022 is connected to the second side plate 1021 by welding or the like, the second side plate 1021 and the first water guide channel 1022 are hermetically connected. The first water chute may be a rectangular chute as shown in fig. 3, or may be a water chute with other shapes, and the structure of the first water chute is not limited in this embodiment.

In this embodiment, in a case where the first rim 101 is assembled with the second rim 102, the first bridging plate 1012 may shield the notch of the first water chute 1022 in the length direction. As shown in fig. 1, in the use process of the photovoltaic array, the first frame 101 and the second frame 102 splice two adjacent photovoltaic modules left and right, so that the first frame 101 and the second frame 102 form an assembled state as shown in fig. 3 between the two adjacent photovoltaic modules left and right. At this time, the first bridging plate 1012 in one photovoltaic module extends to the second side plate 1021 in the other photovoltaic module, the first water chute 1022 is located between the two photovoltaic modules (between the first side plate 1011 and the second side plate 1021), and the first bridging plate 1012 is located above the first water chute 1022, and the distance between the two photovoltaic modules is adjusted, so that the first bridging plate 1012 can shield part or all of the notch of the first water chute 1022. Between two adjacent photovoltaic modules on the left and right, rainwater may enter the first water guiding gutter 1022 through a gap between the first bridging plate 1012 and the second side plate 1021, and be discharged through the first water guiding gutter 1022. At this time, the third frame 103 and the fourth frame 104 are spliced with two adjacent photovoltaic modules, and the two adjacent photovoltaic modules can be spliced in a lap joint manner (i.e. the photovoltaic module above is lapped on the photovoltaic module below), or spliced in a traditional sealing strip and sealing glue manner.

In summary, in this embodiment, the first bridging plate is disposed on one side of the first frame, the first water guiding groove is disposed on one side of the second frame, and when the first frame is assembled with the second frame, the first bridging plate can enable rainwater between two adjacent photovoltaic modules (i.e., between the first frame and the second frame) to directly flow into the first water guiding groove, and the rainwater is discharged through the first water guiding groove, so that the waterproof problem between two adjacent photovoltaic modules can be solved. In the installation process of the photovoltaic array, a large number of sealing strips can be prevented from being arranged between adjacent photovoltaic modules, and sealant is coated, so that the installation efficiency of the photovoltaic modules can be improved. And in the use process of the photovoltaic array, the hidden danger of water leakage caused by aging of the sealing strips and the sealing glue can be avoided. Simultaneously, through adjusting the interval between first frame and the second frame, can adjust the distance between two adjacent photovoltaic module in a flexible way, make things convenient for photovoltaic module's dismantlement and installation.

Optionally, a shape of a side of the first water guiding trough 1022 facing away from the second frame 102 is matched with a shape of a side of the first frame 101 facing away from the second frame 102, and when the first frame 101 is assembled with the second frame 102, a side of the first water guiding trough 1022 facing away from the second frame 102 abuts against the first frame 101, or a first preset distance is formed between a side of the first water guiding trough 1022 facing away from the second frame 102 and the first frame 101.

For example, as shown in fig. 3, a shape of a side of the first water guiding groove 1022 facing away from the second side plate 1021 is matched with a shape of a side of the first side plate 1011 facing away from the battery tab subsection 100, and when the first frame 101 is assembled with the second frame 102, a side of the first water guiding groove 1022 facing away from the second side plate 1021 abuts against the first side plate 1011, or a first preset distance is formed between a side of the first water guiding groove 1022 facing away from the second side plate 1021 and the first side plate 1011.

In this embodiment, the structure of the first water chute 1022 may match the structure of the first side plate 1011 to form a stable photovoltaic array. For example, the first water guiding trough 1022 may be a rectangular water guiding trough, a side wall of the first water guiding trough 1022 far from the second side plate 1021 may be a straight wall, and a side of the first side plate 1011 adjacent to the first water guiding trough 1022 is a straight wall. In the case that the first frame 101 and the second frame 102 are assembled, the first water chute 1022 may abut against the first side plate 1011, so that the first frame 101 and the second frame 102 are tightly fitted, and thus a stable fitting state is formed between adjacent photovoltaic modules. Or the first water guiding trough 1022 may also be spaced from the first side plate 1011 by a first preset distance, so as to adjust the distance between the two photovoltaic modules. The specific value of the first preset distance may be set according to requirements, and this embodiment does not limit this.

Optionally, a second strap 1023 is arranged on the side of the first water chute 1022 opposite to the second frame 102, the second strap 1023 extends in the direction close to the second frame 102, and when the first frame 101 and the second frame 102 are assembled, the second strap 1023 abuts against the first strap 1012, or the second strap 1023 and the first strap 1012 are spaced by a second preset distance.

For example, as shown in fig. 3, a second strap 1023 is disposed on a side of the first water chute 1022 opposite to the second side plate 1021, the second strap 1023 extends in a direction close to the second side plate 1021, and in a case where the first frame 101 and the second frame 102 are assembled, the second strap 1023 abuts against the first strap 1012, or the second strap 1023 and the first strap 1012 are spaced apart by a second predetermined distance.

In this embodiment, the second bridging plate 1023 can be disposed on the side wall of the first water guiding trough 1022 far away from the second side plate 1021, the second bridging plate 1023 is disposed at the notch position of the first water guiding trough 1022 along the length direction, and the second bridging plate 1023 extends out to a certain distance in the direction close to the second side plate 1021, so as to shield the partial notch of the first water guiding trough 1022. In practical applications, the height of the sidewall of the first water chute 1022 may be adjusted so that the second strap 1023 abuts the first strap 1012 when the first frame 101 and the second frame 102 are assembled. When the second bridging plate 1023 abuts against the first bridging plate 1012, the first bridging plate 1012 can be supported by the second bridging plate 1023, and then the first frame 101 is supported by the second frame 102, so that two adjacent photovoltaic modules are tightly matched. Meanwhile, when the second bridging plate 1023 is arranged at the notch of the first water chute 1022, rainwater in the first water chute 1022 can be prevented from entering the bottom of the photovoltaic array from a gap between the first side plate 1011 and the first water chute 1022 after overflowing from the notch of the first water chute 1022. Also can separate the second between second bridging plate and the first bridging plate and predetermine the distance to can conveniently adjust photovoltaic module's position, the specific numerical value of the second distance of predetermineeing can set up according to the demand, and this embodiment does not do the restriction to this.

Optionally, the first strap 1012 is provided with a barb structure 1013 at a side close to the first water chute 1022, and in a case where the first rim 101 is assembled with the second rim 102, part or all of the barb structure 1013 is located in the first water chute 1022.

For example, as shown in fig. 4, fig. 4 shows another schematic assembly diagram of the first side frame and the second side frame in the embodiment of the present invention, the barb structure 1013 may be disposed on one side of the first overlapping plate 1012 near the first water guiding trough 1022, the height of the side wall of the first water guiding trough 1022 and/or the size of the barb structure 1013 may be adjusted, in an assembled state of the first side frame 101 and the second side frame 102, an end of the barb structure 1013 away from the first overlapping plate 1012 may be located in the first water guiding trough 1022, that is, in the assembled state, the barb structure 1013 extends into the first water guiding trough 1022. In combination with the above example, when the second bridging plate 1023 is disposed on one side of the first water chute 1022, in the assembled state of the first frame 101 and the second frame 102, the end of the barb structure 1013 away from the first bridging plate 1012 is lower than the second bridging plate 1023, so that the barb structure 1013 is located in the first water chute 1022. When the barb 1013 extends into the first water chute 1022, the barb 1013 and the second strap 1023 cooperate to prevent the first frame 101 and the second frame 102 from being separated.

Referring to fig. 5, fig. 5 shows a schematic view of the assembly of the third and fourth rims in the embodiment of the present invention, and the lap joint part further includes a third lap plate 1302 and a fourth lap plate 1042. The third strap plate 1032 is mounted to a side of the third rim 103 facing away from the fourth rim 104 and extends in a direction away from the fourth rim 104. The fourth strap 1042 is mounted to a side of the fourth rim 104 facing away from the third rim 103 and extends in a direction away from the third rim 103. In the case where the third bezel 103 is assembled with the fourth bezel 104, the fourth strap 1042 is superposed over the third strap 1032.

Illustratively, as shown in fig. 5, the third frame 103 includes a third side plate 1031, the third side plate 1031 constitutes a main portion of the third frame 103, and a side of the third side plate 1031 close to the fourth side plate 1042 (a side close to the cell subsection 100) is mounted with a bearing mechanism, and the cell subsection 100 and the third frame 103 are connected by the bearing mechanism. The side of the third side plate 1031 facing away from the fourth side plate 1042, i.e. the side facing away from the cell subsection 100, is provided with a third strap 1032. The third strap 1032 intersects the third side plate 1031, the third strap 1032 is the same length as the third frame 103, and the third strap 1032 extends a distance in a direction away from the third side plate 1031 to form a third strap 1032 having a certain width. The connection relationship between the third strap 1032 and the third side plate 1031 can refer to the first strap 1012, which is not described in detail in this embodiment. Wherein the third strap 1032 may be spaced apart from the upper surface of the photovoltaic module, such that the fourth strap 1042 may be located above the third strap 1032 when the third frame 103 and the fourth frame 104 are assembled.

The fourth frame 104 includes a fourth side plate 1041, the fourth side plate 1041 constitutes a main portion of the fourth frame 104, and a side of the fourth side plate 1041 close to the third side plate 1032 (a side close to the battery plate subsection 100) is provided with a carrying mechanism, and the battery plate subsection 100 and the fourth frame 104 are connected through the carrying mechanism. For understanding the fourth strap 1042, reference may be made to the first strap 1012, which is not described in detail in this embodiment. The fourth strap 1042 can be located on the upper surface of the photovoltaic module, so that the fourth strap 1042 can be located above the third strap 1032 when the third frame 103 and the fourth frame 104 are assembled.

Referring to fig. 6, fig. 6 shows a usage state diagram of a third frame and a fourth frame in an embodiment of the present invention, a position of the third strap 1032 in the third strap 1031 and a position of the fourth strap 1042 in the fourth strap 1041 may be adjusted, and widths of the third strap 1032 and the fourth strap 1042 are adjusted, so that in a case where the third frame 103 is assembled with the fourth frame 104, the third strap 1032 and the fourth strap 1042 are alternately disposed between the third frame 103 and the fourth frame 104, and the fourth strap 1042 is overlapped above the third strap 1032. Referring to fig. 1, when the photovoltaic array is in an inclined state, the fourth frame 104 of the photovoltaic module located above and the third frame 103 of another photovoltaic module located below can be inserted between two adjacent photovoltaic modules, so as to achieve a matching state. In the mated state, the fourth strap 1042 overlies the third strap 1032. Since the photovoltaic matrix is in an inclined state, rainwater on the surface of the photovoltaic module located above can flow along the fourth bridging plate 1042 to the surface of the photovoltaic module located below. The third bridging plate 1032 can prevent rainwater from entering between the third side plate 1031 and the fourth side plate 1041, thereby solving the waterproof problem between two adjacent photovoltaic modules.

In this embodiment, first bridging plate can make about the rainwater between two adjacent photovoltaic module directly flow into first guiding gutter, discharges through first guiding gutter, controls the waterproof problem between two adjacent photovoltaic module about the solution, and waterproof problem between two adjacent photovoltaic module about third bridging plate and fourth bridging plate can solve. In the installation process of the photovoltaic array, the sealing strips can be prevented from being arranged between the adjacent photovoltaic modules, the sealing glue is coated, the installation efficiency of the photovoltaic modules is improved, and in the use process of the photovoltaic array, the hidden danger of water leakage caused by the aging of the sealing strips and the sealing glue can be avoided. Meanwhile, the photovoltaic modules can be prevented from being spliced in an up-down lap joint mode, so that the photovoltaic modules above are prevented from shielding the photovoltaic modules below, and the power generation efficiency of the photovoltaic modules is improved.

Optionally, the lap joint may further include a seal disposed between the third lap plate 1032 and the fourth lap plate 1042 in the case where the third rim 103 is assembled with the fourth rim 104.

Illustratively, as shown in fig. 5, a groove 301 is formed on the third strap 1032 and/or the fourth strap 1042, the sealing member includes a first section 302 and a second section 303, the first section 302 is fixed in the groove 301, one side of the second section 303 is fixedly connected with the first section 302, and the other side of the second section 303 abuts against the third strap 1032 or the fourth strap 1042 when the third frame 103 and the fourth frame 104 are assembled.

In this embodiment, at least one seal may be disposed between the third strap 1032 and the fourth strap 1042 to seal the gap between the third strap 1032 and the fourth strap 1042. The groove 301 may be disposed on a side of the fourth strap 1042 adjacent to the third strap 1032, or the groove 301 may be disposed on a side of the third strap 1032 adjacent to the fourth strap 1042, and the sealing member is installed in the groove 301, and in a case where the third rim 103 and the fourth rim 104 are assembled, the sealing member may seal a gap between the third strap 1032 and the fourth strap 1042, so as to prevent rainwater from entering the bottom of the photovoltaic array through the gap between the third strap 1032 and the fourth strap 1042.

The sealing member may be a herringbone sealing member, which includes a first branch 302 (a first sealing strip located in the groove 301 in fig. 5) and a second branch 303 (a second sealing strip located between the third strap 1032 and the fourth strap 1042), where the first branch 302 is fixed in the groove 301, one side of the second branch 303 is fixedly connected to the first branch 302, and the other side extends in a direction away from the groove 301, and the size of the second branch 303 is adjusted, so that the other side of the second branch 303 can abut against the third strap 1032 in an assembling condition of the third frame 103 and the fourth frame 104, thereby sealing the third strap 1032 and the fourth strap 1042. In practical application, the number of the sealing elements, the groove structure, and the structure of the sealing elements may be set according to requirements, which is not limited by the embodiment.

Optionally, the lap joint part may further include a second water guiding groove 1033, the second water guiding groove 1033 is installed at a side of the third frame 103 facing away from the fourth frame 104, and the second water guiding groove 1033 is disposed along a length direction of the third frame 103. The third bridging plate 1032 is located at a notch of the second water guide groove 1022 in the length direction, and the width of the third bridging plate 1032 is smaller than the width of the second water guide groove 1033.

For example, as shown in fig. 5, a second water chute 1033 may be provided below the third strap 1032, and rainwater entering between the third strap 1032 and the fourth strap 1042 may be received by the second water chute 1033. The structure of the second water chute 1033 can refer to the first water chute 1022, which is not limited by the embodiment. The third bridging plate 1032 is close to the upper surface of the photovoltaic module, and the second water chute 1033 is far away from the upper surface of the photovoltaic module, so that the third bridging plate 1032 is located at the position of the notch of the second water chute 1033, and the width of the third bridging plate 1032 is smaller than that of the second water chute 1033, and the third bridging plate 1032 can only shield part of the notch of the second water chute 1033. When rainwater enters from between the third and

fourth strap plates

1032 and 1042, the rainwater may enter the second water guide groove 1033 along the third strap plate 1032 and be discharged through the second water guide groove 1033.

Optionally, one side of the fourth frame 104 facing away from the third frame 103 is provided with a fifth bridging plate 1043, the fifth bridging plate 1043 extends in a direction away from the third frame 103, and under the condition that the third frame 103 is assembled with the fourth frame 104, the fifth bridging plate 1043 blocks the notch of the second water chute 1033 in the length direction.

For example, as shown in fig. 5 and 6, a fifth strap 1043 may be disposed under the fourth strap 1042 and juxtaposed to the fourth strap 1042, the fourth strap 1042 is spaced apart from the fifth strap 1043, and in a case where the third frame 103 is assembled with the fourth frame 104, the third strap 1032 is disposed between the fourth strap 1042 and the fifth strap 1043. And the width of the fifth bridging plate 1043 may be adjusted, so that the fifth bridging plate 1043 may shield a part or all of the notches of the second water chute 1033 in the length direction. In practical application, when rainwater enters from between the third bridging plate 1032 and the fourth bridging plate 1042, the rainwater may enter the bottom of the photovoltaic array from the gap between the second water chute 1033 and the fourth side plate 1041 under the action of the third bridging plate 1032, the fifth bridging plate 1043 is arranged to shield the notch of the second water chute 1033, so that the rainwater can be introduced into the second water chute 1033, and the rainwater is prevented from entering the bottom of the photovoltaic array from the gap between the second water chute 1033 and the fourth side plate 1041.

Optionally, a shape of a side of the second water guiding groove 1033 departing from the third rim 103 is matched with a shape of a side of the fourth rim 104 departing from the third rim 103, and when the third rim 103 and the fourth rim 104 are assembled, a side of the second water guiding groove 1033 departing from the third rim 103 abuts against the fourth rim 104.

For example, as shown in fig. 5 and 6, the outer contour of the second water chute 1033 may be rectangular, the width of the second water chute 1033 may be adjusted, and when the third rim 103 and the fourth rim 104 are assembled, the side wall of the second water chute 1033 away from the third side plate 1031 may abut against the fourth side plate 1041, so that the third rim 103 and the fourth rim 104 form a tight fit state. Because the third rim 103 is located below the fourth rim 104, in the installation and use process of the photovoltaic module, the fourth rim 104 can be supported by the second water chute 1033, so that the photovoltaic module located above is supported by the photovoltaic module located below, and the installation of the photovoltaic module is facilitated. It should be noted that a side of the second water chute 1033 away from the third side plate 1031 may also be separated from the fourth side plate 1041 by a first distance, so as to adjust a distance between two adjacent photovoltaic modules.

Optionally, a first supporting plate 1034 may be disposed at the bottom of the second water guiding channel 1033, the first supporting plate 1034 extends away from the third connecting plate 1032, and in a case where the third side frame 103 is assembled with the fourth side frame 104, the first supporting plate 1034 abuts against the fourth side plate 1041. When the first support plate 1034 is disposed at the bottom of the second water chute 1033, a contact area between the second water chute 1033 and the fourth side plate 1041 may be increased, and a support area of the photovoltaic module located below to the photovoltaic module located above may be increased, thereby improving stability of the photovoltaic array.

In the present embodiment, when the second rim 102 and the third rim 103 are coupled, the first water guide channel 1022 and the second water guide channel 1033 communicate with each other.

For example, as shown in fig. 7 and 8, fig. 7 shows a schematic diagram of a splicing surface of a second frame in an embodiment of the present invention, fig. 8 shows a schematic diagram of a splicing surface of a third frame in an embodiment of the present invention, and with reference to fig. 4, the second side plate 1021 may include a first portion 401 and a second portion 402, the second portion 402 is located at one side close to the first water guiding gutter 1022, and the second portion 402 is disposed at the bottom of the first water guiding gutter 1022, and the second portion 402 extends in a direction away from the bottom of the first water guiding gutter 1022. As shown in fig. 4, the first portion 401 constitutes a main body of the first side plate 1011, the second portion 402 is located at a side close to the first water chute 1022, the first portion 401 and the second portion 402 are integrally formed, and the second portion 402 is used to increase the thickness of the first side plate 1011.

When the second frame 102 and the third frame 103 are spliced, the second frame 102 and the third frame 103 may be cut, and a splicing surface that is matched with each other is formed at one end of the second frame 102 and one end of the third frame 103, respectively. As shown in fig. 7, during the cutting process, a splicing surface corresponding to the third frame 103 is formed by the cut first portion 401. Meanwhile, the second part 402 is remained, and the connection between the first water chute 1022 and the second water chute 1033 is achieved by the cooperation of the second part 402 and the second water chute 1033. In the process of connecting the first water chute 1022 and the second water chute 1033, a sealant may be disposed between the second water chute 1033 and the second portion 402 to prevent rainwater from entering the bottom of the photovoltaic array through a gap between the second water chute 1033 and the second portion 402. In practical application, the specific structures of the first portion 401 and the second portion 402 can be set as required, and only the splicing surface can be formed in the cutting process and can be matched with the second water chute 1033.

Optionally, the first side plate 1011 may include a third portion 403 and a fourth portion 404, and the fourth portion 404 is disposed on the first overlapping plate 1012 and extends away from the first overlapping plate 1012. As shown in fig. 4, the third portion 403 forms a main portion of the first side plate 1011 and the fourth portion 404 is used to increase the thickening of the third side plate 1031.

Referring to fig. 9, fig. 9 shows a schematic diagram of a splicing surface of a first frame in an embodiment of the present invention, in combination with the above example, when the first frame 101 and the third frame 103 are spliced, the first frame 101 and the third frame 103 may be cut, a fourth portion 404 is remained in the cutting process, the third portion 403 is cut, and a splicing surface corresponding to the third frame 103 is formed through the cut third portion 403. The remaining fourth portion 404 may be engaged with the second water chute 1033, and a sealant is disposed between the second water chute 1033 and the fourth portion 404, so as to seal an end of the second water chute 1033 close to the first side plate 1011. In practical application, the specific structures of the third portion 403 and the fourth portion 404 may be set as required, and only the splicing surface may be formed in the cutting process and may be matched with the second water chute 1033. It should be noted that, an end of the second water chute 1033 near the first side frame 101 may be sealed by other methods, which is not limited in this embodiment.

Optionally, the lap joint portion may further include a core sleeve 500, in a case where two adjacent second frames 102 are assembled, the core sleeve 500 is disposed in two adjacent first water guiding troughs 1022, and a sealant layer is disposed between an outer wall of the core sleeve 500 and an inner wall of the first water guiding trough 1022.

Referring to fig. 10, fig. 10 is a schematic view illustrating the cooperation of a first water guiding groove and a sleeve core in an embodiment of the present invention, and as shown in fig. 4, an outer contour of the sleeve core 500 may cooperate with an inner wall of the first water guiding groove 1022, the sleeve core 500 may be disposed in the first water guiding groove 1022, and a sealant layer is disposed between the sleeve core 500 and the first water guiding groove 1022. When the photovoltaic module located above is spliced with the photovoltaic module located below, the two adjacent first water chutes 1022 can be respectively connected through the sleeve core 500, rainwater in the first water chute 1022 located above is introduced into the first water chute 1022 located below, and the rainwater is prevented from flowing into the bottom of the photovoltaic array from a gap between the first water chute and the second water chute. In practical applications, two adjacent first water chutes may also be connected by other manners, which is not limited in this embodiment. Meanwhile, when the second frame 102 is engaged with the third frame 103, the sidewall of the core 500 may be cut to form a joint 501 engaged with the second water chute 1033, and rainwater in the second water chute 1033 may be introduced into the first water chute through the joint 501.

In this embodiment, the bearing mechanism may include a bearing plate 601 and a pinch plate 602. One side of the first side plate 1011 near the second side plate 1021 and one side of the second side plate 1021 near the first side plate 1011 are respectively provided with a bearing plate 601 and a pinch plate 602, and the bearing plate 601 and the pinch plate 602 form a mounting groove.

As shown in fig. 3, in the first frame 101, the supporting plate 601 and the buckle 602 are disposed side by side on one side of the first side plate 1011 close to the second side plate 1021, in the second frame 102, the supporting plate 601 and the buckle 602 are disposed side by side on one side of the second side plate 1021 close to the second side plate 1021, the supporting plate 601 and the buckle 602 are spaced apart by a certain distance, the supporting plate 601, the buckle 602 and the first side plate 101 enclose to form a mounting groove, the width of the mounting groove (the distance between the supporting plate and the buckle) is greater than the thickness of the battery plate subsection 100, and the battery plate subsection 100 can be clamped into the mounting groove. When the cell subsection 100 is installed in the installation groove, the buckle plate 602 is located on the light-facing side of the cell subsection 100 (the light-facing side is the side of the cell receiving the sunlight), and the carrier plate 601 is located on the backlight side of the cell subsection 100 (the backlight side is the side away from the light-facing side). Meanwhile, a sealant may be disposed between the battery plate subsection 100 and the inner wall of the mounting groove to seal a gap between the battery plate subsection 100 and the mounting groove. Similarly, the bearing plate 601 and the buckle 602 are arranged side by side on the side of the second side plate 1021 near the first side plate 1011.

Similarly, a side of the third side plate 1031 close to the fourth side plate 1041 and a side of the fourth side plate 1041 close to the third side plate 1031 may be respectively provided with a carrier plate 601 and a clip 602. When the first frame 101, the second frame 102, the third frame 103 and the fourth frame 104 are sequentially connected at first to form the frame sections, the cell sections 100 are mounted in the mounting grooves, and the cell sections 100 can be fixed on the inner sides of the frame sections to form the photovoltaic module.

Optionally, a bearing plate 601 is disposed on one side of the first frame 101 close to the second frame 102 and one side of the second frame 102 close to the first frame 101. The bearing plate 601 is used for bearing the battery plate subsection 100, one side of the battery plate subsection 100 departing from the bearing plate 601 is flush with the first frame 101 and the second frame 102 respectively, and sealant layers are arranged between the battery plate subsection 100 and the first frame 101 and between the battery plate subsection 100 and the second frame 102 respectively.

For example, as shown in fig. 11, fig. 11 shows an assembly schematic diagram of a first frame and a second frame in another embodiment of the present invention, the carrying mechanism may only include a carrying plate 601, one side of the first side plate 1011 away from the second side plate 1021 and one side of the second side plate 1021 away from the first side plate 1011, only the carrying plate 601 may be provided, and the battery plate subsection 100 is mounted on the carrying plate 601, so that the light-facing side of the battery plate subsection 100 (the side of the battery plate subsection departing from the carrying plate 601) is flush with one end of the first side plate 1011 located on the upper surface of the photovoltaic module, and the light-facing side of the battery plate subsection 100 is flush with one end of the second side plate 1021 located on the upper surface of the photovoltaic module, that is, as shown in fig. 11, the light-facing side of the battery plate subsection 100 is flush with the first bridging plate.

In this embodiment, a support 701 may be disposed between the battery piece subsection 100 and the carrier plate 601, and the support 701 is, for example, an epdm rubber strip, and the light-facing side of the battery piece subsection 100 is flush with the first side plate 1011 and the second side plate 1021 through the support 701. Also, a connection 702 may be provided between the battery plate subsection 100 and the carrier plate 601, the connection 702 being for example a structural glue, fixedly connecting the battery plate subsection 100 and the carrier plate 601 via the connection 702. Further, a sealant layer 703 may be disposed between the battery piece subsection 100 and the first side plate 1011, and between the battery piece subsection 100 and the second side plate 1021 to seal the battery piece subsection 100 and the first side plate 1011 and the second side plate 1021. The connection mode between the battery plate subsection 100 and the carrier plate 601 can be set according to the requirement, and this embodiment does not limit this.

When the connecting member 702 is a structural adhesive, a spacer 704 may be disposed between the structural adhesive and the sealant, and the spacer 704 may be a foam rod, so as to separate the structural adhesive and the sealant through the spacer 704, thereby avoiding the reaction between the structural adhesive and the sealant and affecting the connection effect of the structural adhesive and the sealing effect of the sealant.

Optionally, a bearing plate 601 is disposed on one side of the third frame 103 close to the fourth frame 104 and one side of the fourth frame 104 close to the third frame 103. One side of the cell subsection 100 departing from the loading plate 601 is flush with the third frame 103 and the fourth frame 104, and a sealant layer is disposed between the cell subsection 100 and the third frame 103 and between the cell subsection 100 and the fourth frame 104.

For example, as shown in fig. 12, fig. 12 shows another assembly schematic diagram of a third frame and a fourth frame in the embodiment of the present invention, a side of the third side plate 1031 close to the fourth side plate 1041 and a side of the fourth side plate 1041 close to the third side plate 1031 are respectively provided with a loading plate 601, and the loading plate 601 extends toward the direction close to the battery plate subsection 100. The cell subsection 100 is mounted on the carrier plate 601, one side of the cell subsection 100 facing away from the carrier plate 601 is flush with the third and

fourth side plates

1031, 1041, and sealant layers 703 are respectively disposed between the cell subsection 100 and the third side plate 1031 and between the cell subsection 100 and the fourth side plate 1041.

In practical application, when the battery plate subsection 100 is flush with the first side plate 1011, the second side plate 1021, the third side plate 1031 and the fourth side plate 1041, the surface of the whole photovoltaic array can be smooth, and dust deposition on the surface of the photovoltaic module is avoided, so that the situation that the photovoltaic module is shielded by the dust deposition and the power generation efficiency of the photovoltaic module is influenced is avoided.

In this embodiment, the first frame 101, the second frame 102, the third frame 103, and the fourth frame 104 may be respectively connected to the support 200 through the fixing plate 603, so as to fix the photovoltaic module on the support.

For example, as shown in fig. 3, a fixing plate 603 may be disposed on a side of the first side plate 1011 close to the second side plate 1021, and the fixing plate 603 extends away from the first side plate 1011. The fixing plate 603 is fixedly connected to the first side plate 1011, and the fixing plate 603 can be fixed to the bracket 200 by bolts, thereby fixing the first frame 101 to the bracket. Similarly, a fixing plate 603 may be disposed on a side of the second side plate 1021 near the first side plate 1011, and the fixing plate 603 extends in a direction away from the second side plate 1021. A fixing plate 603 may be disposed on a side of the third side plate 1031 close to the fourth side plate 1041, and the fixing plate 603 extends away from the third side plate 1031. A fixing plate 603 may be disposed on a side of the fourth side plate 1041 close to the third side plate 1031, and the fixing plate 603 extends away from the fourth side plate 1041.

Alternatively, as shown in fig. 3, a second supporting plate 604 may be disposed between the fixing plate 603 and the loading plate 601 to support the loading plate 601 and the fixing plate 603, thereby improving the strength of the first frame 101. The specific structure of the second supporting plate 604 can be set according to the requirement, and this embodiment does not limit this.

Alternatively, a plurality of protrusions 605 may be disposed at intervals on one side of the fixing plate 603 close to the bearing plate 601, and a plurality of protrusions 605 may be disposed at intervals on one side of the bearing plate 601 close to the fixing plate 603, where the protrusions 605 are used to cooperate with the connecting member to fix two frames, such as the first frame 101 and the third frame 103, that are connected to each other. The bump 605 can be used in the prior art, but the embodiment is not limited thereto.

The present embodiment provides a photovoltaic module including the BIPV waterproofing member according to the previous embodiment.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, frame section, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, frame section, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, border element, article, or apparatus that comprises the element.

While the embodiments of the present invention have been described with reference to the accompanying drawings, the present invention is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many modifications may be made by one skilled in the art without departing from the spirit and scope of the present invention as defined in the appended claims.

Claims

1. A BIPV waterproof component is characterized by comprising a frame subsection and an overlap subsection, wherein the frame subsection comprises a first frame and a second frame which are oppositely arranged, and the overlap subsection comprises a first overlap plate and a first water chute;

2. The BIPV waterproof component of claim 1, wherein a side of the first water chute facing away from the second rim is matched in shape to a side of the first rim facing away from the second rim, and wherein when the first rim is assembled with the second rim, the side of the first water chute facing away from the second rim abuts against the first rim, or the side of the first water chute facing away from the second rim is spaced from the first rim by a first predetermined distance.

3. The BIPV waterproof structure of claim 2, wherein a side of the first water chute opposite to the second bezel is provided with a second strap extending in a direction close to the second bezel, the second strap abutting against the first strap in a state where the first bezel is assembled with the second bezel, or the second strap being spaced apart from the first strap by a second predetermined distance.

4. The BIPV waterproofing member according to claim 1 wherein a side of the first strap adjacent to the first gutter is provided with a barb structure, and a part or all of the barb structure is located in the first gutter in a state where the first rim is assembled with the second rim.

5. The BIPV waterproofing member according to any one of claims 1 to 4 wherein said border section further comprises third and fourth oppositely disposed borders, said lap section further comprising third and fourth lap panels;

6. The BIPV waterproofing member according to claim 5 wherein said lap joint section further comprises a seal disposed between said third lap plate and said fourth lap plate when said third rim is assembled with said fourth rim.

7. The BIPV waterproofing member according to claim 6 wherein the third strap and/or the fourth strap is provided with a groove, and the sealing member comprises a first section and a second section, the first section being fixed in the groove, one side of the second section being fixedly connected to the first section, and the other side of the second section abutting against the third strap or the fourth strap when the third rim and the fourth rim are assembled.

8. The BIPV waterproofing member according to claim 5 wherein said lap subsection further comprises a second gutter;

9. The BIPV waterproofing member according to claim 8 wherein a side of the fourth rim facing away from the third rim is provided with a fifth strap extending in a direction away from the third rim, and the fifth strap blocks a notch of the second water guiding gutter in a length direction when the third rim is assembled with the fourth rim.

10. The BIPV waterproofing member according to claim 8 wherein a side of the second gutter facing away from the third rim matches in shape with a side of the fourth rim facing away from the third rim, and wherein the side of the second gutter facing away from the third rim abuts against the fourth rim when the third rim and the fourth rim are assembled.

11. The BIPV waterproof component of claim 1, wherein a side of the first rim adjacent to the second rim and a side of the second rim adjacent to the first rim are provided with a bearing plate; the loading board is used for bearing battery plate subsections in the photovoltaic assembly, one side of each battery plate subsection deviating from the loading board is flush with the first frame and the second frame respectively, and sealing glue layers are arranged between the battery plate subsections and the first frames and between the battery plate subsections and the second frames respectively.

12. The BIPV waterproofing member according to claim 5 wherein a side of said third rim near said fourth rim and a side of said fourth rim near said third rim are provided with a loading plate; the loading board is used for bearing the battery piece subsection in the photovoltaic module, the battery piece subsection deviates from one side of the loading board respectively with the third frame with the fourth frame parallel and level, the battery piece subsection with between the third frame and the battery piece subsection with be provided with sealing glue layer between the fourth frame respectively.

13. A photovoltaic module comprising a BIPV waterproofing member according to any one of claims 1 to 12.