CN220292757U - Large-scale photovoltaic livestock breeding house - Google Patents

Abstract

The utility model relates to the technical field of livestock breeding and discloses a large-scale photovoltaic livestock breeding house, which comprises a steel pipe net rack and a roof arranged at the top of the steel pipe net rack, wherein a photovoltaic assembly is arranged on the roof. The steel pipe net rack comprises a plurality of unit net racks and connecting rods connected among the unit net racks. The vertical pipes of the unit net rack are fixedly connected with the top beams through connectors, and the connecting rods are fixedly connected with the top beams through connecting bolts. The upper half part of the top beam is of a triangular frame structure, and the photovoltaic assembly is arranged on a slope surface at the front side of the roof. The photovoltaic assembly comprises a photovoltaic bracket and a plurality of photovoltaic panels arranged on the photovoltaic bracket. The main structure of the cultivation house is a steel pipe grid structure, the top beams of the unit grid are installed on a plurality of vertical pipes and are fixedly connected through connectors, assembly and disassembly are convenient, and the connecting rods play a role in fixing adjacent unit grids. The photovoltaic assembly is arranged on the slope surface of the front side of the roof, so that the photovoltaic assembly does not occupy the ground space and the ecological breeding purpose can be realized.

Description

Large-scale photovoltaic livestock breeding house

Technical Field

The utility model relates to the technical field of livestock breeding, in particular to a large-scale photovoltaic livestock breeding house.

Background

The current livestock breeding mostly adopts large-scale cultivation, and compared with traditional bulk farming, the large-scale cultivation has the advantages that the centralized management of feeding water and excrement cleaning is convenient, and the cultivation efficiency can be effectively improved. The heat preservation and heat dissipation scheme of the large-scale farm is planned in the construction stage, and energy consumption is compared in the aspect of heat dissipation of the colony house, along with the rapid development of the photovoltaic industry, the photovoltaic panel can be adopted to provide electric energy for the colony house, ecological cultivation can be realized, and cultivation cost can be effectively reduced. The traditional colony house is brick wall structure, and the ventilation window is installed to the colony house periphery, and the heat preservation of colony house is effectual, but is unfavorable for ventilation heat dissipation. The current colony house can adopt steel pipe grid structure, and steel pipe grid structure takes up an area of fewly, can build the colony house of large-span, and steel pipe grid structure's stability is good, long service life. However, the current steel pipe grid structure is assembled in a welding mode, so that the assembled steel pipe grid structure is high in stability, and is inconvenient to detach or detach and transfer. In order to solve the problems, the utility model discloses a large-scale photovoltaic livestock breeding house.

Disclosure of Invention

The utility model provides a large-scale photovoltaic livestock breeding house for solving the problems.

The technical scheme of the utility model is realized as follows: the large-scale photovoltaic livestock breeding house comprises a steel pipe net rack and a roof arranged at the top of the steel pipe net rack, wherein a photovoltaic assembly is arranged on the roof; the steel pipe net rack comprises a plurality of unit net racks and connecting rods connected among the plurality of unit net racks; the unit net rack comprises a plurality of risers which are arranged side by side and top beams which are arranged on the risers, the connecting rods are connected to the top beams of the adjacent unit net racks, the risers and the top beams are fixedly connected through connectors, and the connecting rods and the top beams are fixedly connected through connecting bolts; the roof comprises a heat-insulating plate arranged on the top beam and a corrugated plate paved on the top of the heat-insulating plate; the lower half part of the top beam is of a rectangular frame structure, the upper half part of the top beam is of a triangular frame structure, and the photovoltaic assembly is arranged on a slope surface on the front side of the roof; the photovoltaic assembly comprises a photovoltaic bracket and a plurality of photovoltaic panels arranged on the photovoltaic bracket.

Further, the top beam extends towards the front side to form a triangular frame, the triangular frame is paved on the heat insulation board and the corrugated board, and the photovoltaic support extends to the upper part of the triangular frame.

The photovoltaic bracket comprises a plurality of inclined rods which are arranged side by side, a plurality of cross bars are arranged on the inclined rods side by side, the inclined rods are arranged on the inclined surface of the front side of the roof, and the top ends of the inclined rods extend to the upper part of the rear side of the roof; the cross bar is provided with a clamping groove, a buckle is arranged in the clamping groove in a penetrating mode, and the photovoltaic panel is fixed on the cross bar through the buckle.

The connector comprises a first connecting buckle and a second connecting buckle, the first connecting buckle comprises a first connecting cylinder, a first supporting plate is arranged on the first connecting cylinder along the top towards the inner side, a baffle is arranged on the first connecting cylinder along the outer side of the top upwards, a transverse connecting bolt is arranged in the first connecting cylinder in a penetrating manner, the first connecting cylinder is sleeved on the vertical pipe and fixed by the connecting bolt, the first supporting plate is abutted to the bottom surface of the top beam and fixed by the connecting bolt, and the baffle is abutted to the rear side of the top beam and fixed by the connecting bolt; the second connecting buckle comprises a second connecting cylinder, second supporting plates are respectively arranged on the two sides of the second connecting cylinder along the top, and the second supporting plates are abutted to the bottom surface of the top beam and fixed by connecting bolts.

Further, a fence is movably installed between adjacent vertical pipes of the unit net rack, the front side and the rear side of each unit net rack are movably installed with fences, and movable doors are installed on the fences on the front sides of the adjacent unit net racks.

By adopting the technical scheme, the utility model has the beneficial effects that: the large-scale photovoltaic livestock breeding house comprises a steel pipe net rack and a roof arranged at the top of the steel pipe net rack, wherein a photovoltaic assembly is arranged on the roof. The steel pipe net rack comprises a plurality of unit net racks and connecting rods connected among the unit net racks. The vertical pipes of the unit net rack are fixedly connected with the top beams through connectors, and the connecting rods are fixedly connected with the top beams through connecting bolts. The upper half part of the top beam is of a triangular frame structure, and the photovoltaic assembly is arranged on a slope surface at the front side of the roof. The photovoltaic assembly comprises a photovoltaic bracket and a plurality of photovoltaic panels arranged on the photovoltaic bracket. The main structure of the cultivation house is a steel pipe grid structure, the unit grid top beams are installed on the plurality of vertical pipes and are fixedly connected through connectors, the cultivation house is convenient to assemble and disassemble, and the connecting rods play a role in reinforcing and fixing, so that the whole structure of the cultivation house is firm and stable. The photovoltaic assembly is arranged on the slope surface of the front side of the roof, so that the photovoltaic assembly does not occupy the ground space and the ecological breeding purpose can be realized.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of a split structure of the present utility model;

fig. 3 is an enlarged view of a portion a in fig. 2;

wherein: 1. a riser; 2. a top beam; 3. a connecting rod; 4. a connecting bolt; 5. a thermal insulation board; 6. corrugated board; 7. a photovoltaic panel; 8. triangle frame; 9. a diagonal rod; 10. a cross bar; 11. a clamping groove; 12. a buckle; 13. a first connecting buckle; 14. the second connecting buckle; 15. a first connecting cylinder; 16. a first support plate; 17. a baffle; 18. a second connecting cylinder; 19. a second support plate; 20. a fence; 21. a movable door.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-3, the large-scale photovoltaic livestock breeding house comprises a steel pipe net rack and a roof arranged at the top of the steel pipe net rack, wherein a photovoltaic assembly is arranged on the roof. The steel pipe net frame comprises a plurality of unit net frames and connecting rods 3 connected among the plurality of unit net frames. The unit net rack comprises a plurality of risers 1 which are arranged side by side, and top beams 2 which are arranged on the risers 1, wherein connecting rods 3 are connected to the top beams 2 of the adjacent unit net rack, the risers 1 and the top beams 2 are fixedly connected through connectors, and the connecting rods 3 and the top beams 2 are fixedly connected through connecting bolts 4. The roof comprises a heat insulation board 5 arranged on the top beam 2 and a corrugated board 6 paved on the top of the heat insulation board 5. The lower half part of the top beam 2 is of a rectangular frame structure, the upper half part of the top beam 2 is of a triangular frame structure, and the photovoltaic assembly is arranged on a slope surface on the front side of a roof. The photovoltaic assembly comprises a photovoltaic bracket and a plurality of photovoltaic panels 7 arranged on the photovoltaic bracket.

The top beam 2 of this embodiment extends toward the front side and has a triangular frame 8, the triangular frame 8 is laid on the insulation board 5 and the corrugated board 6, and the photovoltaic support extends above the triangular frame 8. The triangular frame 8 is positioned at the front side of the top beam 2, and the heat insulation board 5 and the corrugated board 6 are arranged on the triangular frame 8, so that the area of a roof can be effectively increased, and the number of photovoltaic panels 7 can be effectively increased. The triangular frame 8 extends outwards and can also play a role in shading sun and shielding rain.

The photovoltaic support of this embodiment is including a plurality of diagonal rods 9 of installing side by side, installs a plurality of horizontal poles 10 side by side on the diagonal rod 9, and diagonal rod 9 installs on the slope of roof front side, and diagonal rod 9 top extends to roof rear side top. The cross bar 10 is provided with a clamping groove 11, a buckle 12 is arranged in the clamping groove 11 in a penetrating manner, and the photovoltaic panel 7 is fixed on the cross bar 10 through the buckle 12. The top end of the diagonal rod 9 extends to the upper side of the rear side of the roof, so that the number of the photovoltaic panels 7 can be effectively increased.

The connector of this embodiment is including first connector link 13 and second connector link 14, first connector link 13 is including first connecting cylinder 15, first connecting cylinder 15 is equipped with first backup pad 16 along top inboard, first connecting cylinder 15 is equipped with baffle 17 up along the top outside, wear to be equipped with horizontal connecting bolt 4 in the first connecting cylinder 15, first connecting cylinder 15 cover is established on riser 1 and is fixed by connecting bolt 4, first backup pad 16 is contradicted in the back face of back timber 2 and is fixed by connecting bolt 4, baffle 17 is contradicted in back timber 2 rear side and is fixed by connecting bolt 4. The second connecting buckle 14 comprises a second connecting cylinder 18, the second connecting cylinder 18 is respectively provided with a second supporting plate 19 along the top towards two sides, and the second supporting plates 19 are abutted against the bottom surface of the top beam 2 and are fixed by the connecting bolts 4. The first connecting buckle 13 and the second connecting buckle 14 are movable connecting pieces, so that the assembly and the disassembly are convenient.

A fence 20 is movably arranged between adjacent risers 1 of the unit net rack of the embodiment, the front side and the rear side of each adjacent unit net rack are movably provided with the fence 20, and the fence 20 at the front side of each adjacent unit net rack is provided with a movable door 21. The fence 20 is arranged around the steel pipe net frame, the fence 20 replaces the traditional wall body, and the ventilation effect is good. A fence 20 is also arranged between the risers 1 of the unit net rack, and the fence 20 can divide the cultivation house into a plurality of cultivation areas.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (5)

1. The large-scale photovoltaic livestock breeding house is characterized by comprising a steel pipe net rack and a roof arranged at the top of the steel pipe net rack, wherein a photovoltaic assembly is arranged on the roof; the steel pipe net rack comprises a plurality of unit net racks and connecting rods (3) connected among the plurality of unit net racks; the unit net rack comprises a plurality of risers (1) which are arranged side by side and top beams (2) which are arranged on the risers (1), wherein the connecting rods (3) are connected to the top beams (2) of the adjacent unit net racks, the risers (1) are fixedly connected with the top beams (2) through connectors, and the connecting rods (3) are fixedly connected with the top beams (2) through connecting bolts (4); the roof comprises a heat insulation board (5) arranged on the top beam (2) and a corrugated board (6) paved on the top of the heat insulation board (5); the lower half part of the top beam (2) is of a rectangular frame structure, the upper half part of the top beam (2) is of a triangular frame structure, and the photovoltaic assembly is arranged on a slope surface on the front side of a roof; the photovoltaic assembly comprises a photovoltaic bracket and a plurality of photovoltaic panels (7) arranged on the photovoltaic bracket.

2. The large-scale photovoltaic livestock breeding house according to claim 1, wherein the top beam (2) extends towards the front side to form a triangular frame (8), the triangular frame (8) is laid on the heat insulation board (5) and the corrugated board (6), and the photovoltaic support extends to above the triangular frame (8).

3. The large-scale photovoltaic livestock-raising house according to claim 1, characterized in that the photovoltaic bracket comprises a plurality of diagonal rods (9) arranged side by side, wherein a plurality of cross rods (10) are arranged on the diagonal rods (9) side by side, the diagonal rods (9) are arranged on the slope surface of the front side of the roof, and the top ends of the diagonal rods (9) extend to the upper side of the rear side of the roof; the cross rod (10) is provided with a clamping groove (11), a buckle (12) is arranged in the clamping groove (11) in a penetrating mode, and the photovoltaic panel (7) is fixed on the cross rod (10) through the buckle (12).

4. The large-scale photovoltaic livestock breeding house according to claim 1, wherein the connector comprises a first connecting buckle (13) and a second connecting buckle (14), the first connecting buckle (13) comprises a first connecting cylinder (15), the first connecting cylinder (15) is provided with a first supporting plate (16) towards the inner side along the top, the first connecting cylinder (15) is provided with a baffle (17) upwards along the outer side of the top, a transverse connecting bolt (4) is penetrated in the first connecting cylinder (15), the first connecting cylinder (15) is sleeved on the vertical pipe (1) and is fixed by the connecting bolt (4), the first supporting plate (16) is abutted against the bottom surface of the top beam (2) and is fixed by the connecting bolt (4), and the baffle (17) is abutted against the rear side of the top beam (2) and is fixed by the connecting bolt (4); the second connecting buckle (14) comprises a second connecting cylinder (18), second supporting plates (19) are respectively arranged on the two sides of the second connecting cylinder (18) along the top, and the second supporting plates (19) are abutted to the bottom surface of the top beam (2) and fixed by the connecting bolts (4).

5. The large-scale photovoltaic livestock-raising house according to claim 1, wherein a fence (20) is movably installed between adjacent risers (1) of the unit net rack, the front side and the rear side of each unit net rack are movably installed with fences (20), and a movable door (21) is installed on each fence (20) adjacent to the front side of the unit net rack.