CN213626333U - Building integrated photovoltaic roof with wind-proof, water-proof and disaster-proof functions - Google Patents

Abstract

The utility model relates to a building integration photovoltaic roof with prevent wind, it is waterproof, the disaster prevention function, its characteristics lie in including a plurality of photovoltaic power generation board groups, a plurality of tile group, the roof support body, photovoltaic power generation board group includes a plurality of photovoltaic power generation boards, each photovoltaic power generation board transversely arranges together side by side, each tile group includes a plurality of tiles, each tile transversely arranges together side by side, each photovoltaic power generation board group sets up on the top surface of roof support body side by side with each tile group from top to bottom in turn, and make each photovoltaic power generation board fix on the roof support body with each tile group can dismantle, still make the lower side overlap joint of photovoltaic power generation board group at the last side that corresponds tile group, and the lower side overlap joint that makes tile group at the last side that corresponds photovoltaic power generation board group, the top surface of each tile group constitutes water guide inclined plane with each photovoltaic power generation board group's top surface jointly. The utility model has the advantages of simple structure, high construction efficiency, low construction cost, convenient maintenance, good wind-resistant, waterproof and disaster-proof performance, good heat dissipation effect and the like.

Description

Building integrated photovoltaic roof with wind-proof, water-proof and disaster-proof functions

Technical Field

The utility model relates to the technical field of power generation, especially a photovoltaic roof.

Background

At present, many photovoltaic roofs have solar panels fixed on the roofs through support frames. When the solar panel is placed on the roof of a shingle, the solar panel is positioned over the shingle and the support bracket is attached to the beam. In this case, the support frame and the tile need to be tightly sealed to prevent water leakage from the roof. The installation structure is very complex, the wiring is also very inconvenient, the building efficiency of the solar power generation roof is greatly influenced, and the building cost is also high. And when the tiles below the solar power generation panel are damaged, the tiles are very inconvenient to replace, so that the maintenance efficiency of the solar power generation roof is greatly influenced. In addition, the solar power generation panel has poor wind resistance and is easy to damage under strong wind. Meanwhile, each power generation assembly of the existing solar power generation panel is too concentrated, so that when heat is generated on the solar power generation panel, the solar power generation panel is difficult to rapidly dissipate heat, the house is easy to heat up, and the comfort of the house is easy to reduce in summer.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to solve above-mentioned problem and not enough, provide a building integration photovoltaic roof with prevent wind, waterproof, disaster prevention function, this building integration photovoltaic roof has simple structure, building efficiency height, construction cost low, maintain advantages such as convenient, the waterproof disaster prevention performance of anti-wind is good, the radiating effect is good.

The technical scheme of the utility model is realized like this:

a building integrated photovoltaic roof with wind-proof, water-proof and disaster-proof functions is characterized by comprising a plurality of photovoltaic power generation plate groups, a plurality of tile plate groups and a roof frame body, wherein the photovoltaic power generation panel group comprises a plurality of photovoltaic power generation panels which are arranged together in parallel in the transverse direction, the side edges of two adjacent photovoltaic power generation plates are overlapped together, the tile plate group comprises a plurality of tile plates which are transversely arranged side by side together, the side edges of two adjacent tile plates are overlapped together, each photovoltaic power generation plate group and each tile plate group are alternately arranged on the top surface of the roof frame body side by side from top to bottom, and each photovoltaic power generation board and each tile board can be detachably fixed on the roof frame body, the lower side edge of each photovoltaic power generation board group is lapped on the upper side edge of the corresponding tile board group, and the lower side edges of the tile plate groups are lapped on the upper side edges of the corresponding photovoltaic power generation plate groups, and the top surfaces of the tile plate groups and the top surfaces of the photovoltaic power generation plate groups form a water guide inclined plane together.

Preferably, a first diversion trench is formed in the left side edge of the top surface of the photovoltaic power generation plate, the first diversion trench is extended to the lower end face of the photovoltaic power generation plate, a first lap joint wing is arranged on the right side edge of the photovoltaic power generation plate, and the first lap joint wing is lapped on a notch of the first diversion trench in the adjacent photovoltaic power generation plate.

Preferably, a water-proof groove extending transversely is formed in the upper end of the top surface of the photovoltaic power generation panel, and the water-proof groove is communicated with the first diversion trench.

Preferably, the bottom surface lower side edge of tile board is equipped with first spacing sand grip, first spacing sand grip inlays the dress and separates in the basin on corresponding photovoltaic power generation board.

Preferably, two first through holes penetrating through the lower surface of the photovoltaic power generation panel are formed in the upper surface of the photovoltaic power generation panel, each first through hole is located on the upper side of the water separation groove, a first locking screw penetrates through each first through hole, and the threaded end of each first locking screw penetrates through the first through hole and then is screwed with the roof frame body.

Preferably, the bottom surface of the photovoltaic power generation panel is provided with a first hanging convex part.

Preferably, the upper edge of the bottom surface of the tile plate is provided with a second hanging convex part.

Preferably, the second guiding gutter has been seted up on the top surface left side edge of tile board to make the second guiding gutter extend to on the lower extreme terminal surface of tile board, the right side edge of tile board is equipped with the second overlap joint wing, the overlap joint of second overlap joint wing is on the notch of the second guiding gutter on corresponding tile board.

Preferably, be equipped with the manger plate sand grip of horizontal extension on the top surface of tile board, the buckler has still been seted up on the top surface of tile board to make the buckler be located the upside of manger plate sand grip, still make the buckler be linked together with the second guiding gutter, photovoltaic power generation board is pressed on the manger plate sand grip.

Preferably, the bottom surface lower side edge of the photovoltaic power generation panel is provided with a second limiting protruding strip, and the second limiting protruding strip is located on the lower side of the water retaining protruding strip.

The utility model has the advantages that: the utility model discloses an among the building integration photovoltaic roof, can be without the use of support frame with the reduction shingle, the construction cost on this building integration photovoltaic roof is lower like this. Because each photovoltaic power generation board group and each tile board group are laid together, the structure of the building integrated photovoltaic roof is very simple, the structure is very convenient to build, and the building efficiency of the building integrated photovoltaic roof is very high. And each photovoltaic power generation board upper surface is the face of receiving the luminous energy, and the wire on the photovoltaic power generation board is located its lower surface to and make a plurality of photovoltaic power generation boards arrange side by side, the wire just directly is located the inboard on roof like this, and this can improve the convenience of walking the line greatly. And when photovoltaic power generation board or tile board appear damaging, only need like the conventional change tile board change can, such change mode is very convenient, this building integration photovoltaic roof's maintenance efficiency is very high. Because each photovoltaic power generation board and each tile board are laminated together side by side, the building integrated photovoltaic roof has good wind resistance, and is not easy to be damaged under general strong wind; the water guide performance is good, and the leakage probability can be greatly avoided; the building integrated photovoltaic roof has good disaster prevention performance. Through making each photovoltaic power generation board group and each shingle group arrange together side by side in turn, the too concentrated condition can not appear in the heat that each photovoltaic power generation board group produced like this, and this can accelerate thermal giving off, avoids the overheated condition to appear locally to reduce its influence to house travelling comfort in summer, this building integration photovoltaic roof suitability is very good.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of a part of the structure of the present invention.

Fig. 3 is one of the structural schematic diagrams of the middle photovoltaic power generation panel of the present invention.

Fig. 4 is a second schematic structural view of the photovoltaic power generation panel of the present invention.

Fig. 5 is one of the structural schematic diagrams of the middle shingle of the present invention.

Fig. 6 is a second schematic structural view of the middle tile of the present invention.

Detailed Description

As shown in FIGS. 1 and 2, the building integrated photovoltaic roof with wind-proof, waterproof and disaster-proof functions of the present invention comprises a plurality of photovoltaic power generation panels 1, a plurality of tile groups 2 and a roof frame body 3, wherein the photovoltaic power generation panels 1 comprise a plurality of photovoltaic power generation panels 11, each photovoltaic power generation panel 11 is arranged laterally side by side, and the side edges of two adjacent photovoltaic power generation panels 11 are lapped, the tile groups 2 comprise a plurality of tiles 21, each tile 21 is arranged laterally side by side, and the side edges of two adjacent tiles 21 are lapped, each photovoltaic power generation panel 1 and each tile group 2 are alternately arranged side by side from top to bottom on the top surface of the roof frame body 3, and each photovoltaic power generation panel 11 and each tile 21 are detachably fixed on the roof frame body 3, and the lower side edge of the photovoltaic power generation panel 1 is lapped on the upper side of the corresponding tile group 2, and the lower side edges of the tile plate groups 2 are lapped on the upper side edges of the corresponding photovoltaic power generation plate groups 1, and the top surfaces of the tile plate groups 2 and the top surfaces of the photovoltaic power generation plate groups 1 jointly form a water guide inclined surface 10. The utility model discloses an among the building integration photovoltaic roof, can be without the use of support frame with the reduction shingle, the construction cost on this building integration photovoltaic roof is lower like this. Because each photovoltaic power generation board group 1 and each tile board group 2 are laid together, the structure of the building integrated photovoltaic roof is very simple, the structure is very convenient to build, and the building efficiency of the building integrated photovoltaic roof is very high. And each photovoltaic power generation board 11 upper surface is the face of receiving the luminous energy, and the wire on the photovoltaic power generation board 11 is located its lower surface to and make a plurality of photovoltaic power generation boards 11 arrange side by side, the wire just directly is located the inboard on roof like this, and this can improve the convenience of walking the line greatly. When the photovoltaic power generation panel 11 or the tile panel 21 is damaged, the replacement is only needed to be carried out like the conventional replacement of the tile panel, the replacement mode is very convenient, and the maintenance efficiency of the building integrated photovoltaic roof is very high. Because each photovoltaic power generation board 11 and each tile board 21 are laminated together side by side, the building integrated photovoltaic roof has good wind resistance, and is not easy to be damaged under general strong wind; the water guide performance is good, and the leakage probability can be greatly avoided; the building integrated photovoltaic roof has good disaster prevention performance. Through making each photovoltaic power generation board group 1 and each shingle group 2 arrange side by side in turn together, the too concentrated condition can not appear in the heat that each photovoltaic power generation board group 1 produced like this, and this can accelerate thermal giving off, avoids the overheated condition to appear locally to reduce its influence to house travelling comfort summer, this building integration photovoltaic roof suitability is very good.

As shown in fig. 4, the electrical connection wires 101 on the photovoltaic power generation panel 11 are arranged on the bottom surface of the photovoltaic power generation panel 11.

As shown in fig. 6, a plurality of ribs 201 are provided on the bottom surface of the tile 21. This helps to enhance the structural strength of the shingle 21.

As shown in fig. 2, a plurality of positioning bars 31 are transversely arranged on the top surface of the roof frame body 3, the positioning bars 31 are arranged side by side from top to bottom, and each photovoltaic power generation panel 11 and each tile panel 21 are detachably fixed on the corresponding positioning bar 31. Therefore, the photovoltaic power generation plates 11 and the tile plates 21 can be conveniently positioned, the building difficulty and the overall weight of the roof frame body 3 can be controlled, and the aim of conveniently manufacturing the roof frame body 3 can be achieved.

The roof frame body 3 and the positioning bars 31 are made of steel. This enables them to have high structural strength, which contributes to the longevity and safety of the building integrated photovoltaic roof.

As shown in fig. 1 to 4, a first guiding gutter 111 is provided on the left side edge of the top surface of the photovoltaic power generation panel 11, and the first guiding gutter 111 extends to the lower end face of the photovoltaic power generation panel 11, a first overlapping wing 112 is provided on the right side edge of the photovoltaic power generation panel 11, and the first overlapping wing 112 overlaps the notch of the first guiding gutter 111 on the adjacent photovoltaic power generation panel 11. Through making such mosaic structure of two adjacent photovoltaic power generation boards 11 adoption, can not only reliably, stably be in the same place two 11 concatenations of photovoltaic power generation board, can also play the effect of water guide through first guiding gutter 111, avoid the condition that the concatenation department appears leaking.

As shown in fig. 1 and 4, the first overlapping wing 112 is provided with a first positioning protruding strip 102, and the first positioning protruding strip 102 is embedded in the first guiding groove 111, which helps to further improve the accuracy and stability of splicing between the photovoltaic power generation panels 11.

As shown in fig. 3, a water-proof groove 113 extending transversely is formed in the upper end of the top surface of the photovoltaic power generation panel 11, and the water-proof groove 113 is communicated with the first diversion trench 111. By the arrangement of the water-isolating groove 113, rainwater can be prevented from overflowing or permeating upwards, which helps to further improve the waterproof performance of the building integrated photovoltaic roof with the functions of wind prevention, water prevention and disaster prevention.

As shown in fig. 3, in an actual manufacturing process, two water separation grooves 113 may be formed in the photovoltaic power generation panel 11 side by side, and two first channels 111 may be formed in the photovoltaic power generation panel 11 side by side. The waterproof performance of the building integrated photovoltaic roof with the wind-proof, waterproof and disaster-proof functions is further improved.

As shown in fig. 3, the power generation module 103 on the photovoltaic power generation panel 11 is located on the lower side of the water-separating tank 113. Thus, the requirement of power generation can be well met.

As shown in fig. 1 and 6, a first limiting convex strip 211 is provided on the lower side edge of the bottom surface of the tile 21, and the first limiting convex strip 211 is embedded in the water separation groove 113 on the corresponding photovoltaic power generation panel 11. Through inlaying first spacing sand grip 211 in the water proof slot 113 that corresponds, can not only play the effect that prevents tile 21 gliding like this, can also improve tile 21 installation positioning's accuracy, stability and reliability.

As shown in fig. 2 to 4, two first through holes 114 penetrating through the lower surface of the photovoltaic power generation panel 11 are formed in the upper surface of the photovoltaic power generation panel 11, each first through hole 114 is located on the upper side of the water-blocking groove 113, a first locking screw 20 is inserted into each first through hole 114, and a threaded end of the first locking screw 20 is screwed to the roof frame body 3 after passing through the first through hole 114. The photovoltaic power generation panel 11 is fixed by the opening of the first through hole 114 and the first locking screw 20, which contributes to improvement of convenience and reliability of installation and fixation of the photovoltaic power generation panel 11.

As shown in fig. 2, the first locking screw 20 is screwed on the corresponding positioning bar 31. The fixing structure is very simple and convenient.

As shown in fig. 4, a first hanging projection 115 is provided on the bottom surface of the photovoltaic power generation panel 11. Can conveniently hang photovoltaic power generation board 11 on the purlin like this, this can play the condition that prevents gliding to appear in photovoltaic power generation board 11 well, and this can further improve the stability of photovoltaic power generation board 11 installation location.

As shown in fig. 6, a second hanging protrusion 212 is provided on the upper edge of the bottom surface of the tile 21. Therefore, the tile plate 21 can be conveniently hung on the purline, the situation that the tile plate 21 slides downwards can be well prevented, and the stability of mounting and positioning of the tile plate 21 can be further improved.

As shown in fig. 1, 5 and 6, a second guiding groove 213 is formed on the left side edge of the top surface of the tile 21, the second guiding groove 213 extends to the lower end surface of the tile 21, a second overlapping wing 214 is disposed on the right side edge of the tile 21, and the second overlapping wing 214 overlaps the notch of the second guiding groove 213 on the corresponding tile 21. By adopting the splicing structure, two adjacent tile plates 21 can be spliced together reliably and stably, and the water guide effect can be achieved through the second guide groove 213, so that the water leakage at the splicing part is avoided.

As shown in fig. 1 and fig. 6, the second overlapping wing 214 is provided with a second positioning rib 202, and the second positioning rib 202 is embedded in the second guiding groove 213, which helps to further improve the accuracy and stability of splicing between the shingles 21.

As shown in fig. 1 and fig. 5, a water retaining rib 215 extending transversely is disposed on the top surface of the tile 21, a water-proof groove 216 is further disposed on the top surface of the tile 21, the water-proof groove 216 is located on the upper side of the water retaining rib 215, the water-proof groove 216 is further communicated with the second guiding groove 213, and the photovoltaic power generation panel 11 is pressed on the water retaining rib 215. Through the arrangement of the water retaining convex strip 215 and the waterproof groove 216, rainwater can be prevented from overflowing upwards or permeating, which is beneficial to further improving the waterproof performance of the building integrated photovoltaic roof with the wind-proof, waterproof and disaster-proof functions.

As shown in fig. 5 and 6, two second through holes 203 vertically penetrating are formed in the upper side of the tile 21, the second through holes 203 are located on the upper side of the waterproof groove 216, a second locking screw 30 is inserted into the second through holes 203, and a threaded end of the second locking screw 30 is screwed to the roof frame body 3 after passing through the second through holes 203. The tile 21 is fixed by the opening of the second through hole 203 and the second locking screw 30, which helps to improve the convenience and reliability of the installation and fixation of the tile 21.

As shown in fig. 2, the second locking screw 30 is screwed on the corresponding positioning bar 31. The fixing structure is very simple and convenient.

As shown in fig. 1 and 4, the lower side edge of the bottom surface of the photovoltaic panel 11 is provided with a second limiting protruding strip 116, and the second limiting protruding strip 116 is located below the water blocking protruding strip 215. Therefore, the waterproof performance of the building integrated photovoltaic roof with the wind-proof, waterproof and disaster-proof functions can be further improved, the second limiting convex strips 116 can also play a certain limiting role in the tile plates 21 to prevent the tile plates 21 from sliding downwards, and the reliability of the building integrated photovoltaic roof with the wind-proof, waterproof and disaster-proof functions can be further improved.

The above-mentioned embodiment is the preferred embodiment of the present invention, all with the similar structure of the present invention and the equivalent changes made all should belong to the protection category of the present invention.

Claims (10)

1. The utility model provides a building integration photovoltaic roof with prevent wind, waterproof, disaster prevention function which characterized in that: comprises a plurality of photovoltaic power generation board groups (1), a plurality of tile group groups (2) and a roof frame body (3), wherein the photovoltaic power generation board groups (1) comprise a plurality of photovoltaic power generation boards (11), each photovoltaic power generation board (11) is transversely arranged side by side, the side edges of two adjacent photovoltaic power generation boards (11) are lapped together, each tile group (2) comprises a plurality of tile plates (21), each tile plate (21) is transversely arranged side by side, the side edges of two adjacent tile plates (21) are lapped together, each photovoltaic power generation board group (1) and each tile group (2) are alternately arranged on the top surface of the roof frame body (3) side by side from top to bottom, each photovoltaic power generation board (11) and each tile plate (21) can be detachably fixed on the roof frame body (3), the lower side edge of each photovoltaic power generation board group (1) is lapped on the upper side edge of the corresponding tile group (2), and the lower side edge of the tile group (2) is lapped on the upper side edge of the corresponding photovoltaic power generation board group (1), the top surface of each tile group (2) and the top surface of each photovoltaic power generation panel group (1) jointly form a water guide inclined surface (10).

2. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 1, wherein: first guiding gutter (111) have been seted up to the top surface left side edge of photovoltaic power generation board (11) to make first guiding gutter (111) extend to on the lower extreme terminal surface of photovoltaic power generation board (11), the right side edge of photovoltaic power generation board (11) is equipped with first overlap joint wing (112), first overlap joint wing (112) overlap joint is on the notch of first guiding gutter (111) on adjacent photovoltaic power generation board (11).

3. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 2, wherein: the photovoltaic power generation panel is characterized in that a water isolating groove (113) which extends transversely is formed in the upper end of the top surface of the photovoltaic power generation panel (11), and the water isolating groove (113) is communicated with the first diversion groove (111).

4. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 3, wherein: the solar photovoltaic tile is characterized in that a first limiting convex strip (211) is arranged on the lower side edge of the bottom surface of the tile plate (21), and the first limiting convex strip (211) is embedded in a water separation groove (113) on the corresponding photovoltaic power generation plate (11).

5. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 3, wherein: two first through holes (114) penetrating through the lower surface of the photovoltaic power generation panel (11) are formed in the upper surface of the photovoltaic power generation panel (11), each first through hole (114) is located on the upper side of the water separation groove (113), a first locking screw (20) penetrates through the first through holes (114), and the threaded end of the first locking screw (20) penetrates through the first through holes (114) and then is screwed on the roof frame body (3).

6. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in any one of claims 1 to 5, wherein: a first hanging convex part (115) is arranged on the bottom surface of the photovoltaic power generation panel (11).

7. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 1, wherein: and a second hanging convex part (212) is arranged on the upper edge of the bottom surface of the tile plate (21).

8. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 1, wherein: second guiding gutter (213) have been seted up on the top surface left side edge of tile board (21) to make second guiding gutter (213) extend to on the lower extreme terminal surface of tile board (21), the right side edge of tile board (21) is equipped with second overlap joint wing (214), second overlap joint wing (214) overlap joint is on the notch of second guiding gutter (213) on corresponding tile board (21).

9. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 8, wherein: be equipped with horizontal extension's manger plate sand grip (215) on the top surface of tile board (21), waterproof groove (216) have still been seted up on the top surface of tile board (21) to make waterproof groove (216) be located the upside of manger plate sand grip (215), still make waterproof groove (216) and second guiding gutter (213) be linked together, photovoltaic power generation board (11) press on manger plate sand grip (215).

10. The building-integrated photovoltaic roof with wind, water and disaster prevention functions as claimed in claim 9, wherein: the lower side edge of the bottom surface of the photovoltaic power generation panel (11) is provided with a second limiting convex strip (116), and the second limiting convex strip (116) is located on the lower side of the water retaining convex strip (215).

Images