CN220288600U - Wind-powered electricity generation flange plane degree detects structure - Google Patents

Abstract

The utility model discloses a wind power flange flatness detection structure in the technical field of wind power generation, which comprises a mounting plate, wherein clamps are arranged on two sides of the top of the mounting plate, and two groups of clamps are connected with a wind power flange; the detection assembly comprises a controller, the top of controller is connected with the display screen, the bottom of controller evenly is provided with the urceolus, rotates through rotating the subassembly drive connecting rod for the probe can be on wind-powered electricity generation flange along circumference rotation, when the probe reciprocates, through the first flexible of spring, make pressure sensor can record pressure, in transmitting the controller, through controller analysis pressure variation, obtain the altitude variation of each point, thereby simulate out wind-powered electricity generation flange's surface model, calculate the planarization, the result shows through the display screen, and is easy operation, the device is with low costs.

Description

Wind-powered electricity generation flange plane degree detects structure

Technical Field

The utility model relates to the technical field of wind power generation, in particular to a wind power flange flatness detection structure.

Background

Wind power flange is a part of the professional wind power generation. Which are used for the connection between towers, typically have diameters varying between 2 meters and 5 meters.

The flatness is the deviation of the macroscopic concave-convex height of the substrate relative to an ideal plane, the tolerance zone is the area between two parallel planes with the distance of the tolerance value t, the flatness belongs to the shape error among the shape and position errors, the flatness detection of the wind power flange is generally carried out by adopting a laser detection mode at present, the detection equipment is expensive, the cost is high, and in order to save the cost and reduce the pressure of enterprises, therefore, the wind power flange flatness detection structure is provided.

Disclosure of Invention

The utility model aims to provide a wind power flange flatness detection structure for solving the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a wind-powered electricity generation flange flatness detection structure, includes the mounting panel, the top both sides of mounting panel all are provided with anchor clamps, and two sets of anchor clamps are all connected with wind-powered electricity generation flange;

the detection assembly comprises a controller, wherein the top of the controller is connected with a display screen, the bottom of the controller is uniformly provided with an outer cylinder, the inside of the outer cylinder is provided with pressure sensors electrically connected with the controller, the pressure sensors are provided with springs I, the pressure sensors are connected with probes through the springs I, the bottoms of the probes are contacted with a wind power flange, the controller is fixedly connected with the output end of an electric telescopic rod, and the electric telescopic rod is arranged on a connecting rod;

the connecting rod is connected with the rotating assembly.

As a preferable scheme of the wind power flange flatness detection structure, the utility model comprises the following steps: the rotating assembly comprises a gear, the inner wall of the gear is connected to a fixed rod through a bearing, the top of the fixed rod is connected to a mounting plate, a base is arranged at the bottom of the fixed rod, an electric guide rail is arranged on the base, a toothed bar meshed with the gear is arranged at the output end of the electric guide rail, and the top of the gear is connected with a connecting rod.

As a preferable scheme of the wind power flange flatness detection structure, the utility model comprises the following steps: the mounting plate is circular structure, and the outside and the connecting rod laminating of mounting plate are connected, the top of base is provided with the deflector that is annular structure, and the inner wall and the connecting rod laminating of deflector are connected.

As a preferable scheme of the wind power flange flatness detection structure, the utility model comprises the following steps: the output end of the electric telescopic rod is sleeved with a supporting plate in a sliding manner.

As a preferable scheme of the wind power flange flatness detection structure, the utility model comprises the following steps: be provided with the horizontal pole that runs through the connecting rod in the backup pad, be provided with the installation piece on the horizontal pole.

As a preferable scheme of the wind power flange flatness detection structure, the utility model comprises the following steps: and a second spring is connected between the mounting block and the connecting rod.

Compared with the prior art, the utility model has the beneficial effects that:

1. the connecting rod is driven to rotate through the rotating component, so that the probe can rotate circumferentially on the wind power flange, when the probe moves up and down, the pressure sensor can record the pressure through the first expansion and contraction of the spring and transmit the pressure to the controller, the controller analyzes the pressure change to obtain the height change of each point, the surface model of the wind power flange is simulated, the flatness is calculated, the result is displayed through the display screen, the operation is simple, and the device cost is low;

2. the gear passes through the bearing setting in the outside of dead lever, and rethread electric guide rail drive rack bar removes and drives the gear and rotate for the connecting rod is not hindered when rotating.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a wind power flange flatness detection structure;

FIG. 2 is a schematic diagram of a rotating assembly according to the wind power flange flatness detection structure of the present utility model;

FIG. 3 is a schematic diagram of a partial structure of a wind power flange flatness detection structure according to the present utility model;

fig. 4 is a schematic diagram of the internal structure of the outer cylinder of the wind power flange flatness detection structure.

In the figure: 1. a mounting plate; 2. a clamp; 3. wind power flange; 4. a controller; 5. a display screen; 6. an outer cylinder; 7. a pressure sensor; 8. a first spring; 9. a probe; 10. an electric telescopic rod; 11. a connecting rod; 12. a gear; 13. a fixed rod; 14. a toothed bar; 15. an electric guide rail; 16. a base; 17. a guide plate; 18. a support plate; 19. a cross bar; 20. a mounting block; 21. and a second spring.

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.

Example 1

Referring to fig. 1 to 4, a wind power flange flatness detection structure includes a mounting plate 1, two sides of the top of the mounting plate 1 are provided with clamps 2, two groups of clamps 2 are connected with a wind power flange 3, and the clamps 2 are used for fixing the wind power flange 3;

the detection assembly comprises a controller 4, the top of the controller 4 is connected with a display screen 5, the bottom of the controller 4 is uniformly provided with an outer cylinder 6, the inside of the outer cylinder 6 is provided with pressure sensors 7 electrically connected with the controller 4, the pressure sensors 7 are provided with springs I8, the pressure sensors 7 are connected with probes 9 through the springs I8, the bottoms of the probes 9 are contacted with a wind power flange 3, in order to facilitate the probes 9 to move transversely from the top of the wind power flange 3, the controller 4 is fixedly connected with the output end of an electric telescopic rod 10, the electric telescopic rod 10 is arranged on a connecting rod 11, and thus the electric telescopic rod 10 drives the output end of the electric telescopic rod to move transversely, and the probes 9 can be driven to move at the top of the wind power flange 3;

in order to enable the probe 9 to rotate circumferentially on the wind flange 3, a connecting rod 11 is connected to the rotating assembly.

The rotating assembly comprises a gear 12, the inner wall of the gear 12 is connected to a fixed rod 13 through a bearing, the gear 12 can rotate on the fixed rod 13 through the bearing, the top of the fixed rod 13 is connected to a mounting plate 1, a base 16 is arranged at the bottom of the fixed rod 13, the mounting plate 1 can be fixed through the base 16 and the fixed rod 13, an electric guide rail 15 is arranged on the base 16, the output end of the electric guide rail 15 is provided with a toothed bar 14 meshed with the gear 12, the top of the gear 12 is connected with a connecting rod 11, the toothed bar 14 is driven to transversely move through the electric guide rail 15, and the gear 12 can rotate so as to drive the connecting rod 11 to rotate.

The power supply of the electrical components herein is prior art.

In order to make the connecting rod 11 can be more stable when rotating, make mounting panel 1 be circular structure, and the outside of mounting panel 1 is connected with connecting rod 11 laminating, and the top of base 16 is provided with the deflector 17 that is annular structure, and the inner wall of deflector 17 is connected with connecting rod 11 laminating.

Example 2

Referring to fig. 1 and 3, the output end of the electric telescopic rod 10 is slidably sleeved with the support plate 18, so that the output end of the electric telescopic rod 10 can be supported, the electric telescopic rod is prevented from being easily damaged due to stress in suspension, the support plate 18 is provided with the cross rod 19 penetrating through the connecting rod 11, the cross rod 19 is provided with the mounting block 20, the spring two 21 is connected between the mounting block 20 and the connecting rod 11, and the support plate 18 can be automatically reset when not extruded through the spring two 21.

The rest of the structure is the same as in embodiment 1.

Working principle: the electric guide rail 15 drives the toothed bar 14 to transversely move, the gear 12 drives the connecting rod 11 to rotate, the probe 9 is further enabled to rotate along the circumference on the wind power flange 3 to be detected, when the probe 9 moves up and down, the first spring 8 stretches out and draws back, the pressure sensor 7 can record pressure and transmit the pressure to the controller 4, the pressure change is analyzed through the controller 4, the height change of each point is obtained, the surface model of the wind power flange 3 is simulated, flatness is calculated, the result is displayed through the display screen 5, after detection, the controller 4 is driven to move through the electric telescopic rod 10, the probe 9 can be separated from the wind power flange 3, so that the wind power flange 3 can be taken out, when the controller 4 moves towards the direction of the connecting rod 11, the controller 4 can squeeze the supporting plate 18, the second spring 21 is enabled to be compressed, the controller 4 does not squeeze the supporting plate 18 any more when the next detection is carried out, the supporting plate 18 can be reset through the elasticity of the second spring 21, and the output end of the electric telescopic rod 10 is supported.

Although embodiments of the present utility model 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 therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A wind-powered electricity generation flange plane degree detects structure, its characterized in that: comprising the steps of (a) a step of,

the wind power generation device comprises a mounting plate (1), wherein clamps (2) are arranged on two sides of the top of the mounting plate (1), and two groups of clamps (2) are connected with a wind power flange (3);

the detection assembly comprises a controller (4), the top of the controller (4) is connected with a display screen (5), the bottom of the controller (4) is uniformly provided with an outer cylinder (6), the inside of the outer cylinder (6) is provided with pressure sensors (7) electrically connected with the controller (4), the pressure sensors (7) are provided with springs I (8), the pressure sensors (7) are connected with probes (9) through the springs I (8), the bottoms of the probes (9) are contacted with a wind power flange (3), the controller (4) is fixedly connected with the output end of an electric telescopic rod (10), and the electric telescopic rod (10) is installed on a connecting rod (11);

the connecting rod (11) is connected with the rotating component.

2. The wind power flange flatness detection structure according to claim 1, characterized in that: the rotating assembly comprises a gear (12), the inner wall of the gear (12) is connected to a fixed rod (13) through a bearing, the top of the fixed rod (13) is connected to a mounting plate (1), a base (16) is arranged at the bottom of the fixed rod (13), an electric guide rail (15) is arranged on the base (16), a toothed bar (14) meshed with the gear (12) is arranged at the output end of the electric guide rail (15), and the top of the gear (12) is connected with a connecting rod (11).

3. The wind power flange flatness detection structure according to claim 2, characterized in that: the mounting plate (1) is of a circular structure, the outer side of the mounting plate (1) is connected with the connecting rod (11) in a fitting mode, a guide plate (17) of an annular structure is arranged at the top of the base (16), and the inner wall of the guide plate (17) is connected with the connecting rod (11) in a fitting mode.

4. The wind power flange flatness detection structure according to claim 1, characterized in that: the output end of the electric telescopic rod (10) is sheathed with a supporting plate (18) in a sliding way.

5. The wind power flange flatness detection structure of claim 4, wherein: the support plate (18) is provided with a cross rod (19) penetrating through the connecting rod (11), and the cross rod (19) is provided with a mounting block (20).

6. The wind power flange flatness detection structure of claim 5, wherein: and a second spring (21) is connected between the mounting block (20) and the connecting rod (11).