A large-span flexible support anti-typhoon system based on fish-light complementation
By installing wear-resistant bearings on the inner wall of the connection hole and designing a cross "+" shaped structure, the wear problem of flexible fasteners was solved, and the stability and wind resistance of the support system were improved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHINA CONSTR EIGHTH BUREAU SOUTHEAST CONSTR CO LTD
- Filing Date
- 2025-06-11
- Publication Date
- 2026-06-05
AI Technical Summary
The flexible fasteners of traditional flexible typhoon-resistant supports suffer increased wear on the surface of steel wire ropes or strands due to direct friction, affecting the stability and safety of the support system.
Wear-resistant bearings are used to contact the inner wall of the connecting hole with the outer wall of the wire rope, reducing direct friction between the wire rope and the connecting hole port. The wear-resistant bearings protect the wire rope, and the design is a cross-shaped structure to disperse typhoon force and enhance the overall strength of the connecting block.
It effectively protects the wire rope from excessive wear, improves the stability and reliability of the support system, and enhances the wind resistance of the overall structure.
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Figure CN224325907U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of wind-resistant support technology, specifically a large-span flexible support typhoon-resistant system based on fishery-solar complementary integration. Background Technology
[0002] Flexible typhoon-resistant supports, through the use of large-span design and flexible materials, effectively reduce the direct impact of strong winds on photovoltaic or fishery facilities. This ensures the efficiency of photovoltaic power generation without affecting fishery production, greatly improving economic and environmental benefits. It not only reduces economic losses caused by typhoons but also provides a reliable solution for the development of new energy sources in coastal areas.
[0003] In existing technologies, traditional flexible typhoon-resistant supports mainly consist of wind-resistant supports, flexible fasteners, support frames, and connectors. The wind-resistant supports are used to bear the main wind loads, and the flexible fasteners are used to firmly install photovoltaic panels or other facilities on the supports. The support frames play a role in enhancing the overall structural stability and distributing the stress. The connectors are usually made of high-strength materials, which can reduce rigid impacts under extreme weather conditions such as typhoons, while allowing a certain degree of elastic deformation to protect the overall system.
[0004] However, in the use of traditional flexible typhoon-resistant supports, the flexible fixing components mainly function through steel wire ropes or steel strands. However, the flexible fixing components come into direct contact with the connecting components, resulting in direct friction. This causes accelerated wear on the surface of the steel wire ropes or steel strands, reducing their service life. Long-term use may lead to excessive wear of the flexible fixing components, thereby affecting the stability and safety of the entire support system. To address this issue, this utility model proposes a large-span flexible typhoon-resistant support system based on fishery-solar integration to solve the above problems. Utility Model Content
[0005] The purpose of this invention is to provide a large-span flexible support system for typhoon resistance based on solar-aquaculture integration, in order to solve the problems mentioned in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a large-span flexible support typhoon-resistant system based on fishery-solar integration, comprising: a wind-resistant support, a connecting block fixedly installed at the lower end of the wind-resistant support, a plurality of anti-wear bearings installed in the connecting block, an installation plate installed above the wind-resistant support, a connecting hole opened in the connecting block, anti-wear bearings fixedly installed at both ends of the connecting hole, and a steel wire rope installed in the connecting hole;
[0007] The mounting bracket contains several connecting plates.
[0008] Preferably, the fixing frame is equipped with a plurality of connecting plates, and an mounting plate is fixedly installed on the upper end of the fixing frame. A plurality of photovoltaic panels arranged linearly and equidistantly are fixedly installed on the surface of the mounting plate.
[0009] Preferably, the wind-resistant brackets are arranged linearly on the lower surfaces of two adjacent sets of mounting plates, and the wind-resistant brackets are in the form of a four-sided pyramid structure, with connecting blocks fixedly installed on the lower surface of the wind-resistant brackets.
[0010] Preferably, the connecting block has a rectangular parallelepiped structure, and a connecting hole is provided inside the connecting block. The connecting hole includes an upper connecting hole and a lower connecting hole, which form a cross shape. Mounting grooves are provided at both ends of the connecting hole. The inner wall of the mounting groove is fixedly connected to the outer ring surface of the wear-resistant bearing. A steel wire rope passes through the connecting hole.
[0011] Preferably, the surface of the connecting plate has several fixing holes, and a clamping tube is fixedly installed directly below the fixing holes. A clamping groove is opened on the side wall of the end of the clamping tube away from the wind-resistant support. Mounting holes are opened on both sides of the fixing holes. A clamping frame is fitted outside the clamping tube. Holes are opened on the surface of both ends of the clamping frame. Mounting screws are installed in the holes. The mounting screws pass through the mounting holes and are fixedly installed on the lower surface of the connecting plate. A reinforcement hole is opened on the side wall of the clamping frame near the clamping groove of the clamping tube.
[0012] Preferably, the steel wire rope is fixedly installed with reinforcing plates at both ends, and the two ends of the steel wire rope are clamped in the grooves of the clamping tube. Holes are opened at both ends of the surface of the reinforcing plate, and fastening screws are installed in the holes. The fastening screws are threadedly connected to the reinforcing holes.
[0013] Compared with the prior art, the beneficial effects of this utility model are:
[0014] This invention proposes a large-span flexible support system for typhoon resistance based on solar-aquaculture integration. In use, a steel wire rope is passed through the connecting hole located at the lower end of the support block. The two ends of the wire rope are then fixed to the connecting plate. Wear-resistant bearings are fixedly installed at both ends of the connecting hole's inner wall. During a typhoon, the steel wire rope rubs against the two ends of the connecting hole. At this time, the inner wall of the wear-resistant bearings at both ends contacts the outer wall of the steel wire rope. Due to the presence of the wear-resistant bearings, the direct friction between the steel wire rope and the two ends of the connecting hole is greatly reduced, effectively protecting the steel wire rope and preventing excessive wear from occurring during prolonged use. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the structure of this utility model;
[0016] Figure 2 This is a bottom view of the structure of this utility model;
[0017] Figure 3 This is a schematic diagram of the wind-resistant support structure of this utility model;
[0018] Figure 4 This is an exploded view of the structural components of this utility model.
[0019] Figure 5 This is a schematic diagram of the steel wire rope structure of this utility model;
[0020] Figure 6 This is a schematic cross-sectional view of the structure of this utility model;
[0021] Figure 7 for Figure 4 Enlarged structural diagram at point A in the middle.
[0022] In the diagram: 1. Wind-resistant support; 2. Connecting block; 3. Wear-resistant bearing; 4. Mounting plate; 5. Connecting hole; 6. Fixing frame; 7. Connecting plate; 8. Steel wire rope; 9. Photovoltaic panel; 10. Upper connecting hole; 11. Lower connecting hole; 12. Pipe clamp; 13. Reinforcing plate; 14. Clip frame; 15. Mounting screw; 16. Reinforcing hole; 17. Fixing hole. Detailed Implementation
[0023] To make the objectives, technical solutions, and advantages of this utility model clear and complete, the embodiments of this utility model will be further described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are only some, not all, embodiments of this utility model, and are merely used to explain the embodiments of this utility model. They are not intended to limit the embodiments of this utility model. All other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.
[0024] Example 1: Please refer to Figures 1 to 7 This utility model provides a technical solution: a large-span flexible support typhoon-resistant system based on fishery-solar complementary integration, comprising: a wind-resistant support 1, a connecting block 2 fixedly installed at the lower end of the wind-resistant support 1, a plurality of anti-wear bearings 3 installed in the connecting block 2, an installation plate 4 installed above the wind-resistant support 1, a connecting hole 5 opened in the connecting block 2, anti-wear bearings 3 fixedly installed at both ends of the connecting hole 5, and a steel wire rope 8 installed in the connecting hole 5;
[0025] The fixing frame 6 has several connecting plates 7 inside it;
[0026] In use, the wire rope 8 can be passed through the connecting hole 5 of the connecting block 2 at the lower end of the wind-resistant support 1, and then the two ends of the wire rope 8 passing through the connecting block 2 can be fixed to the connecting plate 7. Wear-resistant bearings 3 are fixedly installed at both ends of the inner wall of the connecting hole 5. During the typhoon, the wire rope 8 will rub against the two ends of the connecting hole 5. At this time, the inner wall of the wear-resistant bearings 3 at both ends will contact the outer wall of the wire rope 8. Due to the presence of the wear-resistant bearings 3, the direct friction between the wire rope 8 and the two ends of the connecting hole 5 is greatly reduced, thereby effectively protecting the wire rope 8 and avoiding the problem of excessive wear of the wire rope 8 after long-term use.
[0027] Example 2: Based on Example 1, to improve the overall wind resistance performance, a wind-resistant support 1 is installed in a linear arrangement on the lower surface of two adjacent sets of mounting plates 4. The wind-resistant support 1 has a quadrangular pyramidal structure, and a connecting block 2 is fixedly installed on the lower surface of the wind-resistant support 1. The connecting block 2 has a cuboid structure and a connecting hole 5 is provided inside the connecting block 2. The connecting hole 5 includes an upper connecting hole 10 and a lower connecting hole 11, which form a cross shape. The two ends of the connecting hole 5 have mounting grooves, and the inner wall of the mounting groove is fixedly connected to the outer ring surface of the anti-wear bearing 3. A steel wire rope 8 passes through the connecting hole 5. A reinforcing plate 13 is fixedly installed at both ends of the steel wire rope 8. The two ends of the steel wire rope 8 are clamped in the groove of the clamp tube 12. The surface of the reinforcing plate 13 has holes at both ends, and fastening screws are provided in the holes. The fastening screws are threadedly connected to the reinforcing hole 16.
[0028] To improve the overall wind resistance performance, a connecting block 2 is fixedly installed at the lower end of the wind-resistant support 1. The connecting block 2 has an upper connecting hole 10 and a lower connecting hole 11, which form a cross shape. This structure, by distributing the steel wire ropes 8 in both vertical and horizontal directions, forms a mesh-like force-bearing system, enabling the entire support to better disperse and absorb the multi-directional forces brought by the typhoon, thereby effectively reducing the risk of excessive force in one direction. At the same time, the cross shape design also enhances the overall strength of the connecting block 2, avoiding structural damage caused by uneven local force, further improving the stability and reliability of the system, and ultimately achieving a significant improvement in the overall wind resistance performance.
[0029] Example 3: Based on Example 2, a connecting plate 7 is provided to facilitate component installation. The surface of the connecting plate 7 has several fixing holes 17. A clamping tube 12 is fixedly installed directly below the fixing holes 17. The side wall of the clamping tube 12 away from the wind-resistant bracket 1 has a clamping groove. Mounting holes are provided on both sides of the fixing holes 17. A clamping frame 14 is fitted over the clamping tube 12. Holes are provided on both ends of the clamping frame 14. Mounting screws 15 are installed in the holes. The mounting screws 15 pass through the mounting holes and are fixedly installed on the lower surface of the connecting plate 7. A reinforcement hole 16 is provided on the side wall of the clamping frame 14 near the clamping groove of the clamping tube 12. Several connecting plates 7 are installed inside the fixing frame 6. An mounting plate 4 is fixedly installed on the upper end of the fixing frame 6. Several photovoltaic panels 9 are linearly and equidistantly arranged on the surface of the mounting plate 4.
[0030] To facilitate installation, during installation, the reinforcing plates 13 at both ends of the wire rope 8 can be passed through two sets of opposing clamping tubes 12 and clamped in the clamping slots. Then, the clamping frame 14 is put on the clamping tubes 12 to prevent one end of the wire rope 8 from slipping out of the clamping tubes 12. At the same time, the clamping frame 14 is used in conjunction with the mounting screws 15 to fix it as a whole on the connecting plate 7, thereby completing the fixed installation of the wire rope 8 and facilitating the overall installation.
[0031] Working principle: In actual use, the wire rope 8 can be passed through the connecting hole 5 of the connecting block 2 at the lower end of the wind-resistant support 1, and then the two ends of the wire rope 8 passing through the connecting block 2 are fixed to the connecting plate 7. Wear-resistant bearings 3 are fixedly installed at both ends of the inner wall of the connecting hole 5. During the typhoon, the wire rope 8 will rub against the two ends of the connecting hole 5. At this time, the inner wall of the wear-resistant bearings 3 at both ends contacts the outer wall of the wire rope 8. Due to the presence of the wear-resistant bearings 3, the direct friction between the wire rope 8 and the two ends of the connecting hole 5 is greatly reduced, thereby effectively protecting the wire rope 8 and avoiding the problem of excessive wear of the wire rope 8 after long-term use.
[0032] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A typhoon-resistant system with a large-span flexible support structure based on solar-aquaculture integration, comprising: A wind-resistant support (1) is provided with a connecting block (2) fixedly installed at the lower end of the wind-resistant support (1), and a plurality of anti-wear bearings (3) are installed in the connecting block (2). The wind-resistant support (1) is characterized by having an mounting plate (4) installed above it, a connecting hole (5) being provided in the connecting block (2), and anti-wear bearings (3) being fixedly installed at both ends of the connecting hole (5), and a steel wire rope (8) being provided in the connecting hole (5). The fixing frame (6) has several connecting plates (7) inside.
2. The typhoon-resistant system for a large-span flexible support structure based on solar-aquaculture integration as described in claim 1, characterized in that: The fixing frame (6) is equipped with several connecting plates (7), and the upper end of the fixing frame (6) is fixedly installed with an mounting plate (4). Several photovoltaic panels (9) arranged linearly and equally spaced are fixedly installed on the surface of the mounting plate (4).
3. The typhoon-resistant system for a large-span flexible support structure based on solar-aquaculture integration as described in claim 2, characterized in that: The wind-resistant support (1) is installed in a linear arrangement on the lower surface of two adjacent sets of mounting plates (4). The wind-resistant support (1) has a quadrangular pyramid structure, and a connecting block (2) is fixedly installed on the lower surface of the wind-resistant support (1).
4. The typhoon-resistant system for a large-span flexible support structure based on solar-aquaculture integration as described in claim 3, characterized in that: The connecting block (2) is in the shape of a cuboid. A connecting hole (5) is provided in the connecting block (2). The connecting hole (5) includes an upper connecting hole (10) and a lower connecting hole (11). The upper connecting hole (10) and the lower connecting hole (11) are in a cross shape. Mounting grooves are provided at both ends of the connecting hole (5). The inner wall of the mounting groove is fixedly connected to the outer ring surface of the wear-resistant bearing (3). A steel wire rope (8) passes through the connecting hole (5).
5. A large-span flexible support typhoon-resistant system based on solar-aquaculture integration as described in claim 4, characterized in that: The connecting plate (7) has several fixing holes (17) on its surface. A clamping tube (12) is fixedly installed directly below the fixing hole (17). A clamping groove is provided on the side wall of the clamping tube (12) away from the wind-resistant support (1). Mounting holes are provided on both sides of the fixing hole (17). A clamping frame (14) is fitted on the outside of the clamping tube (12). Holes are provided on the surface of both ends of the clamping frame (14). Mounting screws (15) are provided in the holes. The mounting screws (15) pass through the mounting holes and are fixedly installed on the lower surface of the connecting plate (7). A reinforcement hole (16) is provided on the side wall of the clamping frame (14) near the clamping groove of the clamping tube (12).
6. The typhoon-resistant system for a large-span flexible support structure based on solar-aquaculture integration according to claim 5, characterized in that: The steel wire rope (8) is fixedly installed with a reinforcing plate (13) at both ends. The two ends of the steel wire rope (8) are clamped in the groove of the clamp tube (12). The reinforcing plate (13) has holes at both ends on its surface. Fastening screws are installed in the holes and are threadedly connected to the reinforcing holes (16).