A type of pile support for floating photovoltaic panels

By designing an adjustable pile support for floating photovoltaic panels, the problem of misalignment caused by pile connection deviation was solved, enabling rapid construction and efficient pole connection.

CN224459692UActive Publication Date: 2026-07-03SHENZHEN SEG LONGYAN ENERGY TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN SEG LONGYAN ENERGY TECH CO LTD
Filing Date
2025-08-06
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

During the installation of floating photovoltaic panels, misalignment caused by hoisting deviations during pile connection affects the assembly of the support frame, resulting in slow construction progress.

Method used

A pile support for floating photovoltaic panels was designed, including a support bracket, a limiting pressure member, and multiple docking components. These components are fixed to the pile with bolts to form an adjustable closed-loop slot structure. A rotatable pull ring is used for multi-directional adjustment to overcome pile deviation.

Benefits of technology

It enables rapid connection and assembly, simplifies the construction process, improves construction efficiency, adapts to pile hoisting deviations, and ensures the alignment of the support pole connections.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model provides a pile support for a floating photovoltaic panel, including a support bracket, a limiting pressure member, and multiple docking components. The support bracket is sleeved on the pile and fixed to the embedded part of the pile by bolts. The limiting pressure member is installed on the top of the support bracket, and the two form a closed-loop groove around the axis of the support bracket. Multiple docking components are slidably locked in the groove, and the docking components abut each other end to end to form a closed-loop profile. The docking components are provided with rotatable pull rings that extend out of the grooves. Its structure is novel, and the connecting components can be shifted and adjusted to adapt to the hoisting deviation of the pile, which facilitates the subsequent connection and construction of the support poles and the overall construction operation.
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Description

Technical Field

[0001] This utility model relates to the field of photovoltaic panel installation structures, and more specifically, to a pile support for a floating photovoltaic panel. Background Technology

[0002] Pile support is also a commonly used support method in the installation of photovoltaic panels, especially in the field of floating photovoltaic. Its bottom is fixed by concrete foundation or deep insertion into the ground, and the piles are then connected and fixed by scaffolding.

[0003] However, in the actual hoisting process, deviations may occur, resulting in misalignment of the connection parts between subsequent piles, which affects the connection and assembly of subsequent support poles. In some cases, intermediate connectors may be required for assembly, which is troublesome and affects the construction progress, and needs to be improved. Utility Model Content

[0004] In order to overcome the shortcomings of the existing technology, the technical problem to be solved by this utility model is to propose a pile support for floating photovoltaic panels. The structure is novel and the connecting parts can be shifted and adjusted to adapt to the hoisting deviation of the pile, which facilitates the subsequent connection and construction of the support poles and the overall construction operation.

[0005] To achieve this objective, the present invention adopts the following technical solution:

[0006] This utility model provides a pile support for a floating photovoltaic panel, including a support bracket, a limiting pressure member, and multiple docking components; the support bracket is sleeved on the pile and fixed to the embedded part of the pile by bolts; the limiting pressure member is installed on the top of the support bracket, and the two form a closed-loop groove around the axis of the support bracket; the multiple docking components are slidably locked in the groove, and the docking components abut each other end to end and combine to form a closed-loop profile; the docking components are provided with a rotatable pull ring, which extends out of the groove and outwards.

[0007] In a preferred embodiment of this invention, the support member includes a support tube, a first support ring is fixedly provided on the outer wall of the support tube, and a first limiting ring is fixedly provided on the top edge of the first support ring; the limiting pressure member includes a sleeve, a first pressure ring is fixedly provided on the bottom of the outer wall of the sleeve, and a second limiting ring is fixedly provided on the bottom edge of the first pressure ring, the inner diameter of the second limiting ring being the same as the inner diameter of the first limiting ring; the sleeve is sleeved on the top of the support tube and fixedly connected by bolts; a groove with a narrowed opening is formed between the first pressure ring, the second limiting ring, the first support ring, and the first limiting ring; the docking assembly is slidably engaged and installed in the groove.

[0008] In a preferred embodiment of this invention, the top of the support tube has a first cutting surface on both sides, forming a stepped portion; the inner wall of the sleeve has a corresponding limiting block, the shape of which is adapted to the shape of the first cutting surface; the top of the sleeve has a second cutting surface on both outer sides, the center line connecting the two second cutting surfaces is perpendicular to the center line connecting the two limiting blocks; a first threaded hole is provided on the second cutting surface; the top of the support tube has a corresponding second threaded hole; the sleeve is fitted onto the top of the support tube, the bottom surface of the limiting block abuts against the stepped portion, and is fixed by bolts passing through the first and second threaded holes.

[0009] In a preferred embodiment of this invention, the docking assembly includes a pull ring, a support block, and a shaft. The support block has an arc-shaped block structure, with the inner arc diameter of the support block matching the outer wall diameter of the support tube, and the outer wall diameter of the support block matching the inner diameters of the first and second limiting rings. The vertical height of the support block matches the distance between the bottom surface of the first pressure ring and the top surface of the first support ring. The support block is slidably disposed in the slot. Rubber pads are fixedly provided on both ends of the support block, and the rubber pads of two adjacent docking assemblies abut against each other. A countersunk hole is provided in the middle of the support block, and the shaft rotates through the countersunk hole. The pull ring is installed at the end of the shaft that protrudes from the support block.

[0010] In a preferred embodiment of this invention, a threaded post is fixedly provided on the shaft, protruding from the outer wall of the support block; a second threaded hole is provided radially on the threaded post; a sleeve is fixedly provided on the side wall of the pull ring, the inner diameter of the sleeve is adapted to the diameter of the protruding end of the shaft, the inner wall of the sleeve is threaded, and a through hole is provided on the sleeve corresponding to the second threaded hole; the sleeve is threadedly connected to the threaded post and fixedly connected by bolts passing through the through hole and the second threaded hole.

[0011] The beneficial effects of this utility model are as follows:

[0012] This utility model provides a pile support for a floating photovoltaic panel, including a support bracket, a limiting pressure member, and multiple docking components. The support bracket is sleeved on the pile and fixed to the embedded part of the pile by bolts, providing basic assembly and support. The limiting pressure member is installed on the top of the support bracket, and the two form a closed-loop groove around the axis of the support bracket. Multiple docking components are slidably locked in the groove, and the docking components abut each other end to end, forming a closed-loop profile. This allows the docking components to be rotatably adjustable in the circumferential direction of the pile. The docking components are provided with a rotatable pull ring, which extends out of the groove and outward. This design also allows the pull ring to rotate in another direction. Thus, the pull ring can be adjusted and changed in multiple directions, which can effectively overcome the problem of misalignment caused by pile deviation, thereby enabling the frame pole to be quickly connected and erected, facilitating the overall construction operation. Attached Figure Description

[0013] Figure 1 This is a three-dimensional structural schematic diagram of a pile support for a floating photovoltaic panel provided in a specific embodiment of this utility model;

[0014] Figure 2 This is a first-view three-dimensional unfolded structural diagram of a pile support for a floating photovoltaic panel provided in a specific embodiment of this utility model;

[0015] Figure 3 This is a schematic diagram of the second perspective of the three-dimensional unfolded structure of a pile support for a floating photovoltaic panel provided in a specific embodiment of this utility model;

[0016] Figure 4 This is a cross-sectional view of the support bracket and the limiting ring provided in a specific embodiment of this utility model;

[0017] Figure 5 This is a three-dimensional structural diagram of the docking component provided in a specific embodiment of the present utility model;

[0018] Figure 6 This is a three-dimensional unfolded structural diagram of the docking component provided in a specific embodiment of this utility model.

[0019] In the picture:

[0020] 100. Support bracket; 110. Support tube; 111. First cutting surface; 112. Second threaded hole; 120. First support ring; 130. First limiting ring;

[0021] 200. Limiting pressure component; 210. Sleeve; 211. Limiting block; 212. Second cutting surface; 213. First threaded hole; 220. First pressure ring; 230. Second limiting ring;

[0022] 300. Connecting assembly; 310. Pull ring; 311. Sleeve; 312. Through hole; 320. Support block; 321. Countersunk hole; 330. Shaft; 331. Threaded post; 332. Second threaded hole; 340. Rubber pad; 400. Slot. Detailed Implementation

[0023] The technical solution of this utility model will be further described below with reference to the accompanying drawings and specific embodiments.

[0024] like Figures 1 to 4As shown in the figure, a specific embodiment of this utility model discloses a pile support for a floating photovoltaic panel, including a support bracket 100, a limiting pressure member 200, and multiple docking components 300; the support bracket 100 is sleeved on the pile and fixedly installed on the embedded part of the pile by bolts; the limiting pressure member 200 is installed on the top of the support bracket 100, and the two form a closed-loop groove 400 around the axis of the support bracket; the multiple docking components 300 are slidably locked in the groove 400, and the docking components abut each other end to end and combine to form a closed-loop profile; the docking components 300 are provided with a rotatable pull ring 310, which extends out of the groove.

[0025] The aforementioned type of floating photovoltaic panel pile support includes a support bracket sleeved on the pile and fixed to the embedded part of the pile by bolts, providing basic assembly and support; a limiting pressure member is installed on the top of the support bracket, forming a closed-loop groove around the axis of the support bracket; multiple docking components are slidably locked in the groove, allowing the docking components to be rotatably adjustable in the circumferential direction of the pile; the docking components are equipped with rotatable pull rings, which also allow the pull rings to rotate in another direction; thus, the pull rings can be adjusted and changed in multiple directions, effectively overcoming the misalignment problem caused by pile deviation, thereby enabling the frame poles to be quickly connected and erected, facilitating the overall construction operation.

[0026] Furthermore, such as Figure 3 , Figure 4 As shown, the support member 100 includes a support tube 110, a first support ring 120 fixedly mounted on the outer wall of the support tube 110, and a first limiting ring 130 fixedly mounted on the top edge of the first support ring 120; the limiting pressure member 200 includes a sleeve 210, a first pressure ring 220 fixedly mounted on the bottom of the outer wall of the sleeve 210, and a second limiting ring 230 fixedly mounted on the bottom edge of the first pressure ring 220, the inner diameter of the second limiting ring 230 being the same as the inner diameter of the first limiting ring 130; the sleeve 210 is fitted onto the top of the support tube 110 and fixedly connected by bolts; the first A narrowed groove 400 is formed between the pressure ring 220, the second limiting ring 230, the first support ring 120, and the first limiting ring 130; the docking component 300 is slidably mounted in the groove 400; the limiting pressure component and the support support component are assembled, which facilitates the individual production and processing of each component, and the assembly is relatively simple and convenient to use; in addition, the setting of the first limiting ring and the second limiting ring can limit the groove opening, making the opening smaller, thereby blocking and limiting the internal docking component and providing sufficient force support.

[0027] Furthermore, the top of the support tube 110 has first cutting surfaces 111 on opposite sides, forming a stepped portion; the inner wall of the sleeve 210 has corresponding limiting blocks 211, the shape of which matches the shape of the first cutting surfaces 111; the top of the sleeve 210 has second cutting surfaces 212 on opposite outer sides, the center line connecting the two second cutting surfaces is perpendicular to the center line connecting the two limiting blocks; the second cutting surfaces 212 have first threaded holes 213; the top of the support tube 110 has corresponding second threaded holes 112; the sleeve is fitted onto the top of the support tube, the bottom surface of the limiting blocks abuts against the stepped portion, and is fixed by bolts passing through the first and second threaded holes; this structural design facilitates the alignment and installation between the sleeve and the support tube, and makes it easier to insert and fix the bolts; on the other hand, it effectively prevents rotation between the sleeve and the support tube, so that the force is transmitted to the support tube body through the limiting block, reducing the damage to the bolts.

[0028] Furthermore, such as Figure 5 , Figure 6 As shown, the docking assembly 300 includes a pull ring 310, a support block 320, and a shaft 330. The support block 320 has an arc-shaped block structure. The diameter of the inner arc surface of the support block 320 is adapted to the outer wall diameter of the support tube 110, and the outer wall diameter of the support block 320 is adapted to the inner diameter of the first limiting ring 130 and the second limiting ring 230. The vertical height of the support block 320 is adapted to the distance from the bottom surface of the first pressure ring 220 to the top surface of the first support ring 120, which limits the shape and size of the support block so that it can be slidably placed in the slot, effectively preventing it from falling off, and also smoothly transferring the force to the support support and the limiting pressure member.

[0029] Rubber pads 340 are fixedly provided on both ends of the support block 320. The rubber pads of two adjacent mating components abut against each other. By setting the rubber pads, there is room for deformation and movement between the support blocks, which not only meets the required compression deformation requirements, but also ensures the connection strength of the mating components. The support block 320 has a countersunk hole 321 in the middle. The shaft 330 is rotatably inserted into the countersunk hole 321. The pull ring 310 is installed at the end of the shaft 330 that protrudes from the support block 320. With this structure, the rotation requirements of the shaft can be met, and the force can be effectively transferred to the support block, and then to the support bracket and the limiting pressure member. Furthermore, the end of the shaft is recessed into the countersunk hole, and the inner wall of the support block abuts against the inner wall of the support tube, which effectively prevents the shaft from disengaging and maintains the required connection and fit. Further, the two ends of the support block have embedded grooves, and the rubber pads are correspondingly provided with embedded blocks. The embedded blocks are stuck in the embedded grooves and reinforced by adhesive.

[0030] Furthermore, a threaded post 331 is fixedly provided on the shaft 330, protruding from the outer wall of the support block 320; the threaded post 331 is provided with a radially arranged second threaded hole 332; a sleeve 311 is fixedly provided on the side wall of the pull ring 310, the inner diameter of the sleeve is adapted to the diameter of the protruding end of the shaft, the inner wall of the sleeve is provided with threads, and the sleeve 311 is provided with a through hole 312 corresponding to the second threaded hole; the sleeve is threadedly connected to the threaded post and fixedly connected by bolts passing through the through hole and the second threaded hole; the threaded connection provides sufficient connection strength and effectively prevents loosening; in addition, the sleeve and the threaded post are also reinforced by bolts in the radial direction, which effectively prevents the pull ring from loosening from the threaded post during rotation.

[0031] This utility model has been described through preferred embodiments. Those skilled in the art will understand that various changes or equivalent substitutions can be made to these features and embodiments without departing from the spirit and scope of this utility model. This utility model is not limited to the specific embodiments disclosed herein; other embodiments falling within the scope of the claims of this application are all within the protection scope of this utility model.

Claims

1. A pile support for floating photovoltaic panels, characterized in that: Includes support brackets, limit clamps, and multiple docking components; The support bracket is sleeved on the pile and fixed to the embedded part of the pile by bolts; The limiting pressure component is installed on the top of the support bracket, and the two form a closed-loop groove around the axis of the support bracket; Multiple docking components are slidably locked in the slots, and the docking components abut each other end to end and combine to form a closed-loop profile. The docking assembly is equipped with a rotatable pull ring that extends out of the slot.

2. The pile support for a floating photovoltaic panel according to claim 1, characterized in that: The support bracket includes a support tube, a first support ring is fixedly provided on the outer wall of the support tube, and a first limiting ring is fixedly provided on the top edge of the first support ring; The limiting pressure component includes a sleeve, a first pressure ring is fixedly provided at the bottom of the outer wall of the sleeve, and a second limiting ring is fixedly provided at the bottom edge of the first pressure ring. The inner diameter of the second limiting ring is the same as the inner diameter of the first limiting ring. The sleeve is fitted onto the top of the support tube and fixedly connected by bolts; a groove with a narrowed opening is formed between the first pressure ring, the second limiting ring, the first support ring, and the first limiting ring; The docking component is slidably installed in the slot.

3. The pile support for a floating photovoltaic panel according to claim 2, characterized in that: The top of the support tube has first cutting surfaces on both sides, forming a stepped section; The inner wall of the sleeve is provided with a limiting block, the shape of which is adapted to the shape of the first cutting surface; the top of the sleeve is provided with a second cutting surface on both outer sides, and the center line connecting the two second cutting surfaces is perpendicular to the center line connecting the two limiting blocks; a first threaded hole is provided on the second cutting surface. The top of the support tube is provided with a second threaded hole; The sleeve is fitted onto the top of the support tube, the bottom surface of the limiting block abuts against the stepped part, and is fixed by bolts passing through the first threaded hole and the second threaded hole.

4. The pile support for a floating photovoltaic panel according to claim 3, characterized in that: The docking components include pull rings, support blocks, and shafts; The support block has an arc-shaped block structure. The diameter of the inner arc surface of the support block is adapted to the outer wall diameter of the support tube. The outer wall diameter of the support block is adapted to the inner diameter of the first limiting ring and the second limiting ring. The vertical height of the support block is adapted to the distance from the bottom surface of the first pressure ring to the top surface of the first support ring. The support block is slidably disposed in the slot. Rubber pads are fixedly provided on both ends of the support block, and the rubber pads of two adjacent mating components abut against each other; The support block has a countersunk hole in the middle, and the shaft is rotated through the countersunk hole. The pull ring is installed at the end of the shaft that passes through the support block.

5. A pile support for a floating photovoltaic panel according to claim 4, characterized in that: A threaded post is fixedly provided on the shaft, and the threaded post protrudes from the outer wall of the support block; the threaded post is provided with a radially arranged second threaded hole. A sleeve is fixedly provided on the side wall of the pull ring. The inner diameter of the sleeve is adapted to the diameter of the protruding end of the shaft. The inner wall of the sleeve is threaded, and a through hole is provided on the sleeve corresponding to the second threaded hole. The sleeve threaded connection is installed on the threaded post and fixedly connected by bolts passing through the through hole and the second threaded hole.