CN220822980U

CN220822980U - Photovoltaic triangular pyramid wind-resistant system

Info

Publication number: CN220822980U
Application number: CN202322524368.5U
Authority: CN
Inventors: 周明坤; 李光辉; 王琼; 秦海荣; 贺电; 邓南平; 梁朝霞; 刘化瑾; 姜文丰
Original assignee: Henan Research And Design Co ltd
Current assignee: Henan Research And Design Co ltd
Priority date: 2023-09-18
Filing date: 2023-09-18
Publication date: 2024-04-19
Anticipated expiration: 2033-09-18

Abstract

The utility model discloses a photovoltaic triangular cone wind-resistant system, which relates to the technical field of solar photovoltaic installation and comprises the following components: the triangular cone comprises a first rod piece, a second rod piece, a third rod piece, a fourth rod piece, a fifth rod piece and a sixth rod piece, wherein the first rod piece, the second rod piece and the third rod piece are connected end to form three connecting positions, one ends of the fourth rod piece, the fifth rod piece and the sixth rod piece are connected with each other to form a top point position, and the other ends of the fourth rod piece, the fifth rod piece and the sixth rod piece are respectively connected at the three connecting positions; the beneficial effects of the utility model are as follows: the steel cable and the triangular cone form a space stress system, the wind vibration action is resisted jointly, a downward pulling force is applied to the triangular cone through the load assembly, so that the solar cell panel is prevented from being greatly displaced upwards, the steel cable can be prevented from sliding to a certain extent under the action of strong wind, the damage of a protective sleeve on the surface of the steel cable can be avoided, and the triangular cone is adjustable in traction force so as to meet the requirements under different states.

Description

Photovoltaic triangular pyramid wind-resistant system

Technical Field

The utility model relates to the technical field of solar photovoltaic installation, in particular to a photovoltaic triangular pyramid wind-resistant system.

Background

When the solar cell panel is fixed, a steel bracket structure is generally adopted, and a steel structure frame is built for fixing the solar cell panel, and the solar cell panel is also a flexible bracket structure which is mainly used for mountain land blocks with complex landforms and mainly adopts a net-shaped structure formed by pulling steel ropes, and the solar cell panel is fixed on the steel ropes.

At present, after the solar panel is fixed, because the steel cable has certain deformability, in a strong wind environment, wind force acts on the solar panel, wind vibration is generated between the steel cable and the solar panel, the solar panel can shake, and once the deformation is too large, a sheath at the joint between the solar panel and the steel cable can be severely worn, so that looseness is generated between the solar panel and the steel cable.

Disclosure of utility model

The utility model aims to provide a photovoltaic triangular cone wind-resistant system which aims to solve the defects in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a photovoltaic triangular pyramid wind resistance system comprising:

The triangular cone comprises a first rod piece, a second rod piece, a third rod piece, a fourth rod piece, a fifth rod piece and a sixth rod piece, wherein the first rod piece, the second rod piece and the third rod piece are connected end to form three connecting positions, one ends of the fourth rod piece, the fifth rod piece and the sixth rod piece are connected with each other to form a top point position, and the other ends of the fourth rod piece, the fifth rod piece and the sixth rod piece are respectively connected at the three connecting positions;

The connecting pieces are connected between adjacent triangular cones through the connecting pieces, one end of each connecting piece is connected to the vertex position, and the other end of each connecting piece is connected to the connecting position;

The load assembly is arranged on the ground and is connected to the vertex position through a inhaul cable.

Preferably, the fourth rod, the fifth rod and the sixth rod are fixedly connected through a hanging screw bolt, and the hanging screw bolt is connected through a guy cable.

Preferably, the first rod, the second rod and the fourth rod are fixedly connected, the first rod, the third rod and the sixth rod are fixedly connected, and the second rod, the third rod and the fifth rod are fixedly connected.

Preferably, the load assembly comprises a foundation, a cylinder body, a lifting cylinder and a connecting column, wherein the connecting column is installed on the lifting cylinder, the lifting cylinder is in threaded connection with the cylinder body, the cylinder body is installed in the foundation, and the foundation is arranged underground.

Preferably, the connecting column is inserted in the lifting cylinder in a sliding manner, a displacement block is arranged at the lower part of the connecting column, and a spring is movably adjusted outside the connecting column.

Preferably, the upper end of the spring is abutted against the lifting cylinder, and the lower end of the spring is abutted against the displacement block.

Compared with the prior art, the utility model has the beneficial effects that: the photovoltaic triangular cone wind-resistant system comprises: the cable wire and the triangular cone form a space stress system, the wind vibration action is resisted jointly, two ground anchor cables are arranged at the top position of each triangular cone, the ground anchor cables are connected with the load assembly, the load assembly applies a downward pulling force to the triangular cones, the solar cell panel is prevented from being greatly displaced upwards, the triangular cones are connected with the cable wire through the lifting ring screws, the cable wire can be prevented from sliding to a certain extent under the action of strong wind, the damage of the protective sleeve on the surface of the cable wire can be prevented, and the triangular cones can be adjusted by traction force so as to meet the requirements under different states.

Drawings

FIG. 1 is a schematic diagram of an overall structure according to an embodiment of the present utility model;

FIG. 2 is a schematic top view of an embodiment of the present utility model;

Fig. 3 is a schematic structural diagram of a load assembly according to an embodiment of the present utility model.

In the figure: 1. a first rod member; 2. a second rod member; 3. a third lever; 4. a fourth lever; 5. a fifth lever; 6. a sixth lever; 7. a connecting piece; 10. a load assembly; 101. a foundation; 102. a cylinder; 103. a lifting cylinder; 104. a connecting column; 105. a displacement block; 106. and (3) a spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present disclosure.

Referring to fig. 1-3, the present utility model provides a technical solution: a photovoltaic triangular pyramid wind resistance system, comprising:

The triangular cone comprises a first rod piece 1, a second rod piece 2, a third rod piece 3, a fourth rod piece 4, a fifth rod piece 5 and a sixth rod piece 6, wherein the first rod piece 1, the second rod piece 2 and the third rod piece 3 are connected end to form three connecting positions, one ends of the fourth rod piece 4, the fifth rod piece 5 and the sixth rod piece 6 are connected with each other to form a top point position, and the other ends of the fourth rod piece 4, the fifth rod piece 5 and the sixth rod piece 6 are respectively connected at the three connecting positions;

The first rod piece 1, the second rod piece 2 and the third rod piece 3 are connected end to form three connecting positions, the connecting positions of the first rod piece 1, the second rod piece 2 and the third rod piece 3 are fixedly connected through a hanging screw bolt, so that the three connecting positions can be connected to steel ropes, each steel rope consists of two components, one component steel rope is connected to a solar photovoltaic panel, the bearing steel rope is further arranged, one ends of the fourth rod piece 4, the fifth rod piece 5 and the sixth rod piece 6 are connected with each other to form a top point, the top point is connected with the bearing steel rope, the other ends of the fourth rod piece 4, the fifth rod piece 5 and the sixth rod piece 6 are respectively connected at the three connecting positions, an inverted triangle structure can be formed through the first rod piece 1, the second rod piece 2, the third rod piece 3, the fourth rod piece 4, the fifth rod piece 5 and the sixth rod piece 6, and a space pyramid stress system can be formed by the steel ropes and the steel ropes, and the wind vibration resistance effect is jointly resisted;

The connecting piece 7 is connected between adjacent triangular cones through the connecting piece 7, one end of the connecting piece 7 is connected to the vertex position, and the other end of the connecting piece 7 is connected to the connecting position; thus, adjacent triangular cones can be connected together, and stability is further improved;

The load assembly 10, the load assembly 10 sets up on ground, and the load assembly 10 passes through the cable and connects in the summit position. The load exerts a downward pulling force on the triangular cone component by component, so that the solar cell panel is prevented from being greatly displaced upwards, the triangular cone is connected with the steel cable through the lifting ring screw, the steel cable can be guaranteed to have certain sliding under the action of strong wind, and the damage of the protective sleeve on the surface of the steel cable can be avoided.

Preferably, the fourth rod 4, the fifth rod 5 and the sixth rod 6 are fixedly connected through a hanging screw bolt, and the hanging screw bolt is connected through a stay rope.

Preferably, the first rod piece 1, the second rod piece 2 and the fourth rod piece 4 are fixedly connected, the first rod piece 1, the third rod piece 3 and the sixth rod piece 6 are fixedly connected, and the second rod piece 2, the third rod piece 3 and the fifth rod piece 5 are fixedly connected.

The load assembly 10 includes a foundation 101, a cylinder 102, a lifting cylinder 103, and a connecting column 104, the connecting column 104 is mounted on the lifting cylinder 103, the lifting cylinder 103 is screwed into the cylinder 102, the cylinder 102 is mounted in the foundation 101, and the foundation 101 is disposed underground. The upper end of the spring 106 is abutted against the lifting cylinder 103, and the lower end of the spring 106 is abutted against the displacement block 105 to apply a downward pulling force to the triangular cone through the load assembly 10 so as to prevent the steel cable connected with the triangular cone from moving upwards greatly, so that the solar cell panel is prevented from moving upwards greatly, the triangular cone is connected with the steel cable through the lifting ring screw, the steel cable can be prevented from sliding to a certain extent under the action of strong wind, and the damage of the protective sleeve on the surface of the steel cable can be prevented.

The connecting column 104 is slidably inserted into the lifting cylinder 103, a displacement block 105 is arranged at the lower part of the connecting column 104, a spring 106 is movably adjusted outside the connecting column 104, and the triangular cone can be adjusted by traction force so as to meet the requirements under different states. The lifting cylinder 103 is changed in height relative to the cylinder 102 by rotating the lifting cylinder 103, so that when the height of the lifting cylinder 103 is lowered, the springs 106 are compressed synchronously, the stress of the inhaul cable is increased, the pulling force exerted by the inhaul cable on the triangular pyramid is increased, and the upward amplitude of the solar cell panel is reduced.

The utility model is implemented in particular: the flexible support adopted at present in solar energy installation comprises two kinds of component steel ropes, wherein the component steel ropes are connected to a solar photovoltaic panel and also comprise a bearing steel rope, in the utility model, a top point position is connected with the bearing steel rope, a connecting position is connected with the component steel rope, an inverted triangle structure can be formed through a first rod piece 1, a second rod piece 2, a third rod piece 3, a fourth rod piece 4, a fifth rod piece 5 and a sixth rod piece 6, the steel rope and the triangle cone form a space stress system to jointly resist wind vibration, and a downward pulling force is applied to the triangle cone through a load component 10, so that the steel rope connected with the triangle cone is prevented from greatly moving upwards, the solar cell panel is prevented from greatly upwards moving, the triangle cone is connected with the steel rope through a lifting ring screw, a certain sliding of the steel rope under the action of high wind is prevented, the damage of a surface protection sleeve of the steel rope is prevented, the adjustment mode is as follows, the lifting drum 103 is enabled to be relatively to be changed in height 103 by rotating the lifting drum 103, and accordingly, when the lifting drum is lowered, the tension spring 106 is also enabled to be compressed, and the upward pulling force is also increased, and the pulling force is also applied to the triangle cone is prevented from being greatly moved upwards.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims

1. A photovoltaic triangular pyramid wind resistance system, comprising:

The triangular cone comprises a first rod piece (1), a second rod piece (2), a third rod piece (3), a fourth rod piece (4), a fifth rod piece (5) and a sixth rod piece (6), wherein the first rod piece (1), the second rod piece (2) and the third rod piece (3) are connected end to form three connecting positions, one ends of the fourth rod piece (4), the fifth rod piece (5) and the sixth rod piece (6) are connected with each other to form a top point, and the other ends of the fourth rod piece (4), the fifth rod piece (5) and the sixth rod piece (6) are respectively connected at the three connecting positions;

The connecting pieces (7) are connected between adjacent triangular cones through the connecting pieces (7), one end of each connecting piece (7) is connected to the vertex position, and the other end of each connecting piece (7) is connected to the connecting position;

the load assembly (10), load assembly (10) sets up subaerial, load assembly (10) are connected at the summit position through the cable.

2. The photovoltaic triangular pyramid wind resistance system according to claim 1, wherein: the fourth rod piece (4), the fifth rod piece (5) and the sixth rod piece (6) are fixedly connected through a hanging screw bolt, and the hanging screw bolt is connected through a inhaul cable.

3. The photovoltaic triangular pyramid wind resistance system according to claim 1, wherein: the novel structure comprises a first rod piece (1), a second rod piece (2) and a fourth rod piece (4), wherein the first rod piece (1), the third rod piece (3) and the sixth rod piece (6) are fixedly connected, and the second rod piece (2), the third rod piece (3) and the fifth rod piece (5) are fixedly connected.

4. A photovoltaic triangular pyramid wind resistance system according to claim 3, wherein: the load assembly (10) comprises a foundation (101), a cylinder body (102), a lifting cylinder (103) and a connecting column (104), wherein the connecting column (104) is installed on the lifting cylinder (103), the lifting cylinder (103) is in threaded connection with the cylinder body (102), the cylinder body (102) is installed in the foundation (101), and the foundation (101) is arranged underground.

5. The photovoltaic triangular pyramid wind resistance system according to claim 4, wherein: the connecting column (104) is inserted into the lifting cylinder (103) in a sliding mode, a displacement block (105) is arranged at the lower portion of the connecting column (104), and a spring (106) is movably adjusted outside the connecting column (104).

6. The photovoltaic triangular pyramid wind resistance system according to claim 5, wherein: the upper end of the spring (106) is abutted against the lifting cylinder (103), and the lower end of the spring (106) is abutted against the displacement block (105).