A device for intelligent self-checking of a wind power plant

The design of the intelligent self-inspection device solves the problems of wind turbine blade corrosion and low maintenance efficiency, and realizes the automatic disassembly and collection of blades, thereby improving maintenance safety and efficiency.

CN116357529BActive Publication Date: 2026-06-26SHAOXING NUOREZHI INFORMATION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SHAOXING NUOREZHI INFORMATION TECH CO LTD
Filing Date
2022-12-28
Publication Date
2026-06-26

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Abstract

The application provides a self-checking device for intelligent self-checking of wind power industry equipment damage, which is arranged on a lamp post and comprises a power generation assembly and two lighting assemblies. The power generation assembly is pivotally connected to the top of the lamp post, and the two lighting assemblies are slidingly connected to the lamp post. The self-checking device for intelligent self-checking of wind power industry equipment damage is cooperated with the movable seat, the self-checking assembly, the rotating assembly, the rotating body and the two lighting assemblies. The lamp post originally used for lighting is deformed and moved when needed, so that a recessed mesh cover is formed at the bottom of the fan, which effectively prevents the sudden drop of the broken fan blade tip during rotation, thereby preventing damage to pedestrians or objects under the street lamp. Meanwhile, the fan blade is detachable, so that the damaged fan blade can be collected and transported by using the lamp post.
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Description

Technical Field

[0001] This invention relates to the field of wind power equipment technology, specifically to a device for intelligent self-testing of wind power equipment. Background Technology

[0002] Traditional wind power generation devices for streetlights generally use turbofans to drive rotation and generate electricity by utilizing airflow. However, during the rotation process, the blades of the turbofans often come into contact with sand, gravel, acid or alkali rain and snow in the airflow, which inevitably causes corrosion. The closer to the tip of the blade, the easier it is to break. For safety reasons, personnel have to climb to a height to repair, resulting in low maintenance efficiency. Summary of the Invention

[0003] (a) Technical problems to be solved

[0004] To address the shortcomings of existing technologies, this invention provides a device for intelligent self-testing of wind power equipment.

[0005] (II) Technical Solution

[0006] To achieve the above objectives, the present invention provides the following technical solution: a device for intelligent self-testing of wind power equipment, mounted on a light pole, comprising a power generation component and two lighting components. The power generation component is pivotally connected to the top of the light pole, and the two lighting components are slidably fitted onto the light pole. The power generation component includes a movable base, a self-testing component, a rotating component, and a rotating body. The movable base is pivotally connected to the top of the light pole, and the rotating body is mounted on the movable base. The rotating component is pivotally connected to the front of the rotating body, and the self-testing component is located on the top of the rotating body. The self-testing component corresponds to the rotating component.

[0007] Preferably, the rotating assembly includes a motor, a rotating base, four fan blades, and electric snap-fit ​​slots. The rotating base is pivotally connected to the front of the rotating body, and the motor passes through the axis of the rotating base and is connected to the rotating body. The output end of the motor is connected to the rotating base, and the four electric snap-fit ​​slots are arranged at equal angles to the side of the rotating base with the motor as the center. The fan blades are detachably plugged into the electric snap-fit ​​slots.

[0008] Preferably, the lighting assembly includes a climbing machine, a rain guard, a storage box, and a light bulb. The climbing machine is slidably mounted on the light pole, and the rain guard is mounted on the climbing machine. The light bulb and the storage box are both located at the bottom of the rain guard.

[0009] Preferably, it also includes a load-bearing cover cloth, which has multiple openings, and the two ends of the load-bearing cover cloth are respectively rolled up in two storage boxes.

[0010] Preferably, the device also includes an electromagnet assembly, a convex mounting base, and four electrically operated telescopic rods. The convex mounting base is fitted onto the rotating body, and the four electrically operated telescopic rods are arranged at equal angles around the rotating body on the convex mounting base. The electromagnet assembly is located on the movable end of the electrically operated telescopic rod, and the electromagnet assembly corresponds to the inner side of the fan blade.

[0011] Preferably, the electromagnet assembly includes four electromagnets. The four electromagnets are in contact with each other and are disposed on the movable end of the electric telescopic rod.

[0012] Preferably, it also includes a convex plate and a slide rail, wherein the convex plate is disposed at the bottom of the convex mounting base, the slide rail is vertically disposed on the convex plate, and one of the electric telescopic rods is slidably engaged on the slide rail.

[0013] (III) Beneficial Effects

[0014] This invention provides a device for intelligent self-testing of wind power equipment. It has the following beneficial effects:

[0015] 1. This device for intelligent self-inspection of wind power equipment utilizes a movable base, self-inspection components, a rotating component, a rotating body, and two lighting components working in concert. This allows the streetlight support, originally intended for illumination, to deform and move when needed, forming a recessed mesh cover at the bottom of the turbine fan. This effectively prevents damaged blade tips from suddenly falling off during rotation, thus avoiding injury to pedestrians or objects under the streetlight. Furthermore, by making the blades detachable, damaged blades can be easily collected and transported using the streetlight support. Attached Figure Description

[0016] Figure 1 This is a first perspective view of the present invention;

[0017] Figure 2 This is a second perspective view of the present invention;

[0018] Figure 3 This is a third perspective view of the present invention;

[0019] Figure 4 This is the fourth perspective view of the present invention;

[0020] Figure 5 This is the fifth perspective view of the present invention;

[0021] Figure 6 This is the sixth perspective view of the present invention.

[0022] In the diagram: 1. Light pole, 2. Climbing machine, 3. Rain guard, 4. Load-bearing cover, 5. Lighting assembly, 6. Motor, 7. Power generation assembly, 8. Fan blade, 9. Rotating seat, 10. Support, 11. Self-testing assembly, 12. Rotating assembly, 13. Rotating body, 14. Storage box, 15. Light bulb, 16. Electric telescopic pole, 17. Electromagnet, 18. Electric snap-fit ​​slot seat, 19. Convex mounting seat, 20. Movable seat, 21. Electromagnet assembly, 22. Slide rail, 23. Convex plate, 24. Opening. Detailed Implementation

[0023] This invention provides a device for intelligent self-testing of wind power equipment, such as... Figure 1-6 As shown, a power generation component 7 and two lighting components 5 are mounted on the lamp post 1. The power generation component 7 is pivotally connected to the top of the lamp post 1, and the two lighting components 5 are slidably fitted onto the lamp post 1. The power generation component 7 includes a movable base 20, a self-testing component 11, a rotating component 12, and a rotating body 13. The movable base 20 is pivotally connected to the top of the lamp post 1, and the rotating body 13 is mounted on the movable base 20. The rotating component 12 is pivotally connected to the front of the rotating body 13, and the self-testing component 11 is located on the top of the rotating body 13. The self-testing component 11 corresponds to the rotating component 12.

[0024] By incorporating two movable and rotatable lighting components 5, the invention allows the bottom of the turbine fan to be covered by display cloths on the two light poles. This provides secondary protection during the automatic blade disassembly process, effectively solving the problem of blades suddenly detaching due to malfunctions during disassembly. It also greatly facilitates user operation.

[0025] The disassembled fan blades can also be placed inside before being moved to the ground, facilitating collection and indirectly reducing the possibility of personnel being scratched when handling damaged fan blades.

[0026] The rotating assembly 12 includes a motor 6, a rotating base 9, four fan blades 8, and electric snap-fit ​​slots 18. The rotating base 9 is pivotally connected to the front of the rotating body 13, and the motor 6 passes through the axis of the rotating base 9 and is connected to the rotating body 13. The output end of the motor 6 is connected to the rotating base 9, and the four electric snap-fit ​​slots 18 are arranged at equal angles to the side of the rotating base 9 with the motor 6 as the center. The fan blades 8 are detachably inserted into the electric snap-fit ​​slots 18.

[0027] The lighting assembly 5 includes a climbing machine 2, a rain guard 3, a storage box 14, and a light bulb 15. The climbing machine 2 is slidably mounted on the light pole 1, and the rain guard 3 is mounted on the climbing machine 2. The light bulb 15 and the storage box 14 are both located at the bottom of the rain guard 3.

[0028] It also includes a load-bearing cover 4, which has multiple openings 24, and the two ends of the load-bearing cover 4 are respectively rolled up in two storage boxes 14.

[0029] It also includes an electromagnet assembly 21, a convex mounting base 19, and four electric telescopic rods 16. The convex mounting base 19 is fitted onto the rotating body 13, and the four electric telescopic rods 16 are arranged at equal angles around the rotating body 13 on the convex mounting base 19. The electromagnet assembly 21 is arranged on the movable end of the electric telescopic rod 16, and the electromagnet assembly 21 corresponds to the inner side of the fan blade 8.

[0030] The electromagnet assembly 21 includes four electromagnets 17. The four electromagnets 17 are in contact with each other and are mounted on the movable end of the electric telescopic rod 16.

[0031] It also includes a convex plate 23 and a slide rail 22. The convex plate 23 is located at the bottom of the convex mounting base 19, and the slide rail 22 is vertically mounted on the convex plate 23. One of the electric telescopic rods 16 is slidably engaged with the slide rail 22.

[0032] Working principle: In use, firstly, an advertisement of the corresponding size is glued to the back of the load-bearing cover 4. Then, the climbing machine 2 is controlled to rotate the rain shield 3 at the corresponding height and angle, thus unfolding the advertising cloth.

[0033] When the self-inspection component 11 detects damage to the fan blade, it controls two climbing machines 2 to wrap the load-bearing cover 4 around the bottom of the power generation component 7. Then, it controls the motor 6 to rotate the damaged fan blade 8 directly downwards. Next, it controls the extension of the lower electric telescopic rod 16, and the electromagnet 17 engages to hold and attract the fan blade 8. Simultaneously, the lowermost electric locking slot 18 automatically disengages from the fan blade 8. The electric telescopic rod 16 then moves downwards, pulling the fan blade 8 out of the electric locking slot 18. The electric locking slot 18 then falls onto the front of the load-bearing cover 4. Simultaneously, the two climbing machines 2 move downwards, bringing the damaged fan blade to the ground.

[0034] In summary, this intelligent self-inspection device for wind power equipment utilizes the coordinated operation of a movable base 20, a self-inspection component 11, a rotating component 12, a rotating body 13, and two lighting components 5. This allows the streetlight support, originally intended for illumination, to deform and move when needed, forming a recessed mesh cover at the bottom of the turbine fan. This effectively prevents damaged blade tips from suddenly falling off during rotation, thus avoiding damage to pedestrians or objects under the streetlight. Furthermore, by making the blades detachable, damaged blades can be easily collected and transported using the streetlight support.

Claims

1. A device for intelligent self-inspection of wind power equipment, installed on a light pole (1), characterized in that: The device includes a power generation component (7) and two lighting components (5). The power generation component (7) is pivotally connected to the top of the lamp post (1), and the two lighting components (5) are slidably fitted on the lamp post (1). The power generation component (7) includes a movable seat (20), a self-test component (11), a rotating component (12), and a rotating body (13). The movable seat (20) is pivotally connected to the top of the lamp post (1), the rotating body (13) is disposed on the movable seat (20), the rotating component (12) is pivotally connected to the front of the rotating body (13), and the self-test component (11) is disposed on the top of the rotating body (13). The self-test component (11) corresponds to the rotating component (12). The rotating assembly (12) includes a motor (6), a rotating base (9), four fan blades (8), and an electric snap-fit ​​slot (18). The rotating base (9) is pivotally connected to the front of the rotating body (13). The motor (6) passes through the axis of the rotating base (9) and is connected to the rotating body (13). The output end of the motor (6) is connected to the rotating base (9). The four electric snap-fit ​​slots (18) are arranged at equal angles around the motor (6) on the side of the rotating base (9). The fan blades (8) are detachably plugged into the electric snap-fit ​​slots (18). It also includes an electromagnet assembly (21), a convex mounting base (19), and four electric telescopic rods (16). The convex mounting base (19) is fitted onto the rotating body (13). The four electric telescopic rods (16) are set at equal angles around the rotating body (13) on the convex mounting base (19). The electromagnet assembly (21) is set on the movable end of the electric telescopic rod (16). The electromagnet assembly (21) corresponds to the inner side of the fan blade (8). The electromagnet assembly (21) includes four electromagnets (17), which are in contact with each other, and the electromagnets (17) are disposed on the movable end of the electric telescopic rod (16). It also includes a convex plate (23) and a slide rail (22), the convex plate (23) being disposed at the bottom of the convex mounting base (19), and the slide rail (22) being disposed vertically on the convex plate (23), one of the electric telescopic rods (16) being slidably engaged on the slide rail (22).

2. The device for intelligent self-inspection of wind power equipment according to claim 1, characterized in that: The lighting assembly (5) includes a climbing machine (2), a rain guard (3), a storage box (14) and a light bulb (15). The climbing machine (2) is slidably fitted on the light pole (1). The rain guard (3) is set on the climbing machine (2). The light bulb (15) and the storage box (14) are both set at the bottom of the rain guard (3).

3. The device for intelligent self-inspection of wind power equipment according to claim 2, characterized in that: It also includes a load-bearing cover (4), which has multiple openings (24), and the two ends of the load-bearing cover (4) are respectively rolled up in two storage boxes (14).