CN223326243U - A wind power bearing processing tool - Google Patents

Abstract

The utility model relates to the technical field of wind power equipment, in particular to a wind power bearing machining tool which comprises a horizontal driving assembly, wherein adjusting blocks are slidably arranged on two sides of the top of the horizontal driving assembly, the horizontal driving assembly comprises a shell, a clamping screw rod is rotatably arranged in the shell, the clamping screw rod is divided into two sections with opposite threads, a first screw rod sliding block is rotatably arranged on each section, grooves are formed in the side surfaces, close to each other, of the two adjusting blocks, an adjusting screw rod is rotatably arranged in each groove, a second screw rod sliding block is rotatably arranged on each of the two adjusting screw rods, and clamping blocks are rotatably arranged on the end parts, close to each other, of the two second screw rod sliding blocks. According to the utility model, by utilizing the cooperation of the clamping screw rod and the first screw rod sliding block and the linkage of the adjusting screw rod and the second screw rod sliding block, the tool can flexibly adapt to wind power bearings with different sizes, and the adaptability and the flexibility of processing are greatly improved.

Description

Wind power bearing processing tool

Technical Field

The utility model relates to the technical field of wind power equipment, in particular to a wind power bearing machining tool.

Background

In the manufacturing process of wind power equipment, a wind power bearing is used as a key component, and the machining precision and efficiency of the wind power bearing directly influence the performance and service life of the whole wind power equipment.

Because wind power bearings are large in size and heavy in weight, and accurate clamping and positioning are required in the machining process. The traditional processing tool often has the problems of unstable clamping, inconvenient adjustment and the like, so that the processing efficiency is low, and the requirement of high-precision processing is difficult to meet. Therefore, it is particularly important to design a wind power bearing machining tool.

Disclosure of utility model

The utility model aims to provide a wind power bearing machining tool to solve the problems that the traditional machining tool provided in the background art is unstable in clamping, inconvenient to adjust and the like, so that machining efficiency is low, and the requirement of high-precision machining is difficult to meet.

In order to achieve the above purpose, the utility model provides a wind power bearing machining tool, which comprises a horizontal driving assembly, wherein adjusting blocks are slidably arranged on two sides of the top of the horizontal driving assembly, the horizontal driving assembly comprises a shell, a clamping screw rod is rotatably arranged in the shell, the clamping screw rod is divided into two sections with opposite threads, first screw rod sliding blocks are arranged on each section in a threaded manner, the tops of the two first screw rod sliding blocks extend to the outer side of the shell in a sliding and penetrating manner and are connected with the adjusting blocks, grooves are formed in the side surfaces, close to each other, of the two adjusting blocks, an adjusting screw rod is rotatably arranged in each groove, a second screw rod sliding block is rotatably arranged on each adjusting screw rod, and clamping blocks are rotatably arranged on the end parts, close to each other, of the two second screw rod sliding blocks.

Preferably, one end of the clamping screw rod is driven to rotate through a first screw rod motor, and the top end of the adjusting screw rod is driven to rotate through a second screw rod motor.

Preferably, the bottom of the horizontal driving assembly is provided with a plurality of supporting feet.

Preferably, the top of the shell is provided with an opening, and the tops of the two first screw rod sliding blocks slide through the opening to extend to the outer side and are fixedly connected with an adjusting block.

Preferably, a through threaded hole is formed in the inner end of the second screw rod sliding block, and an end thread of the adjusting screw rod penetrates through the threaded hole.

Preferably, the outer end of the clamping block is internally provided with a transverse rotating shaft in a rotating mode, a second bevel gear is arranged on the transverse rotating shaft, the top of the inner portion of the outer end of the clamping block is provided with a vertical rotating shaft in a rotating mode, the bottom end of the vertical rotating shaft is provided with a first bevel gear, the first bevel gear is meshed with the second bevel gear, the top of the clamping block is provided with an adjusting motor, and the top of the vertical rotating shaft is rotatably connected with the outer side of the top of the clamping block in a penetrating mode and fixedly connected with an output shaft of the adjusting motor.

Preferably, the two clamping blocks are provided with clamping grooves on the side surfaces close to each other, and the two clamping grooves are used for matching the side surfaces of the bearing workpiece, so that the bearing workpiece is clamped and fixed.

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

In this wind-powered electricity generation bearing processing frock, through ingenious design horizontal drive assembly and regulating block's combination, realized high-efficient, stable centre gripping and the accurate positioning to wind-powered electricity generation bearing. Utilize the cooperation of centre gripping lead screw and first lead screw slider to and accommodate the linkage of lead screw and second lead screw slider for the frock can adapt to the wind-powered electricity generation bearing of equidimension in a flexible way, has promoted the adaptability and the flexibility of processing greatly.

Meanwhile, through the driving of the first screw motor and the second screw motor, the accurate control on the clamping and adjusting process is realized, and the machining precision and efficiency are remarkably improved. In addition, the bevel gear transmission mechanism inside the clamping block further enhances the stability and reliability of clamping and ensures firm clamping of the wind power bearing in the processing process.

In conclusion, the wind power bearing machining tool effectively solves the problems of unstable clamping, inconvenient adjustment and the like of the traditional tool, meets the requirements of the wind power equipment manufacturing industry on high-precision and high-efficiency machining tools, and has remarkable technical effects and practical values.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of a horizontal driving assembly according to the present utility model;

FIG. 3 is a schematic view of a second lead screw slider according to the present utility model;

The meaning of each reference sign in the figure is:

1. Horizontal driving components, 11, support legs, 12, a shell, 121, an opening, 13, a clamping screw rod, 14, a first screw rod sliding block, 15, a first screw rod motor, 2, an adjusting block, 21, a groove, 22, an adjusting screw rod, 23, a second screw rod motor, 24, a second screw rod sliding block, 241, a threaded hole, 242, a vertical rotating shaft, 243, a first bevel gear, 244, a clamping block, 2441, a transverse rotating shaft, 245, a second bevel gear, 246 and an adjusting motor.

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.

The utility model provides a wind power bearing machining tool, which comprises a horizontal driving assembly 1, wherein adjusting blocks 2 are slidably arranged on two sides of the top of the horizontal driving assembly 1, the horizontal driving assembly 1 comprises a shell 12, a clamping screw rod 13 is rotatably arranged in the shell 12, the clamping screw rod 13 is divided into two sections with opposite threads, first screw rod sliding blocks 14 are arranged on each section in a threaded manner, the two first screw rod sliding blocks are in limited sliding manner in the shell, the tops of the two first screw rod sliding blocks extend to the outer side of the shell in a sliding manner and are connected with the adjusting blocks, grooves 21 are formed in the side surfaces of the two adjusting blocks 2, which are close to each other, an adjusting screw rod 22 is rotatably arranged in each groove 21, second screw rod sliding blocks 24 are rotatably arranged on the two adjusting screw rods 22, and clamping blocks 244 are rotatably arranged on the end parts of the two second screw rod sliding blocks 24, which are close to each other.

During the use, through the regulating block 2 of horizontal drive subassembly 1 top both sides installation to and shell 12 internally mounted's centre gripping lead screw 13, realized the high-efficient centre gripping to wind-powered electricity generation bearing. The clamping screw rod 13 is divided into two sections with opposite threads, and the two first screw rod sliding blocks 14 are matched, so that balance and stability in the clamping process can be ensured, and movement or shaking of the bearing in the processing process can be effectively prevented.

In addition, an adjusting screw 22 is installed in a groove 21 formed on one side of the adjusting block 2, and a second screw sliding block 24 on the adjusting screw 22 can accurately adjust the height position of the clamping block 244 in the vertical direction. The design enables the processing tool to be flexibly suitable for wind power bearings with different sizes and shapes, and improves the accuracy and adaptability of processing.

In conclusion, through ingenious mechanical structure design, the wind power bearing machining tool disclosed by the utility model realizes efficient and accurate clamping and positioning of a wind power bearing. The method not only improves the processing precision, but also greatly simplifies the adjustment step in the processing process, saves the time and labor cost, and improves the overall processing efficiency.

In this embodiment, one end of the clamping screw 13 is driven to rotate by the first screw motor 15, and the top end of the adjusting screw 22 is driven to rotate by the second screw motor 23. The design realizes the automatic control of the clamping screw rod 13, so that the clamping process is faster and more accurate. Through motor drive, the rotation speed and the rotation quantity of the clamping screw rod 13 can be accurately controlled, so that the wind power bearing is accurately clamped, and the degree of automation and the precision of machining are improved.

Specifically, the bottom of the horizontal driving assembly 1 is provided with a plurality of legs 11. This design has strengthened the stability and the bearing capacity of processing frock. The stabilizer blade 11 can evenly disperse the weight of processing frock and bearing, prevents that the frock from taking place to incline or remove in the use, has ensured the stability and the security of processing.

Further, an opening 121 is formed in the top of the housing 12, and the top of each of the two first screw sliders 14 extends to the outside through the opening 121 in a sliding manner and is fixedly connected with the adjusting block 2. This design enables the first screw slider 14 to slide stably within the housing 12 while facilitating maintenance and repair of the first screw slider 14 and the clamping screw 13.

Further, a through threaded hole 241 is formed in the inner end of the second screw slider 24, and an end thread of the adjusting screw 22 passes through the threaded hole 241. This design achieves a secure connection and precise transmission between the second screw slider 24 and the adjusting screw 22. Through threaded connection, the second screw slider 24 can be ensured to stably move on the adjusting screw 22, meanwhile, the accurate adjustment of the position of the second screw slider 24 is facilitated, and the machining precision and efficiency are improved.

Further, the outer end of the clamping block 244 is internally provided with a transverse rotating shaft 2441 in a rotating mode, a second bevel gear 245 is arranged on the transverse rotating shaft 2441, the top of the inner portion of the outer end of the clamping block 244 is provided with a vertical rotating shaft 242 in a rotating mode, the bottom end of the vertical rotating shaft 242 is provided with a first bevel gear 243, the first bevel gear 243 is meshed with the second bevel gear 245, the top of the clamping block 244 is provided with an adjusting motor 246, and the top of the vertical rotating shaft 242 is rotatably and penetratingly extended to the outer side of the top of the clamping block 244 and fixedly connected with an output shaft of the adjusting motor 246. This design enables multi-angle adjustment of the clamp block 244. The vertical rotating shaft 242 is driven to rotate by the adjusting motor 246, so that the first bevel gear 243 and the second bevel gear 245 can be driven to rotate, and the rotation adjustment of the clamping block 244 is realized. The design enables the processing tool to be flexibly suitable for wind power bearings with different shapes and sizes, and improves the adaptability and the flexibility of processing.

Further, the side surfaces of the two clamping blocks 244, which are close to each other, are provided with clamping grooves, and the two clamping grooves are used for matching the side surfaces of the bearing workpiece, so that the bearing workpiece is clamped and fixed. The design realizes stable clamping and accurate positioning of the wind power bearing. The design of the clamping groove can ensure that the bearing workpiece cannot move or shake in the machining process, and meanwhile, the position of the bearing workpiece can be accurately adjusted and centered conveniently. The design improves the machining precision and efficiency and ensures the stability of the machining quality.

When the wind power bearing processing tool is used, the tool is in a standby state, the horizontal driving assembly 1 is stably placed, and the support legs 11 at the bottom of the horizontal driving assembly ensure that the tool is stable and does not shake. The clamping screw rod 13 is static, and the two first screw rod sliding blocks 14 are respectively positioned at two ends of the clamping screw rod 13, so that a certain initial distance is kept. The adjusting screw 22 is also stationary, the second screw slider 24 is located at a position of the adjusting screw 22, and the clamping block 244 is in a state to be clamped.

And then placing the wind power bearing at a preset processing position to ensure that the center of the bearing is aligned with the clamping center of the tool. The first screw motor 15 and the second screw motor 23 are started to prepare for the clamping operation.

The first screw motor 15 drives the clamping screw 13 to rotate. Because the clamping screw rod 13 is divided into two sections with opposite threads, the two first screw rod sliding blocks 14 can move towards the center at the same time and gradually approach to the two sides of the wind power bearing. The movement of the first screw slider 14 drives the adjusting block 2 to approach the bearing until the clamping block 244 contacts the side of the bearing.

At the same time or later, the second screw motor 23 drives the adjusting screw 22 to rotate. The second screw slider 24 moves up and down along the groove 21 under the action of the threads of the adjusting screw 22, so that the height position of the clamping block 244 is further adjusted, and the clamping block 244 can accurately and stably clamp the wind power bearing. If desired, the vertical shaft 242 may also be driven to rotate by an adjustment motor 246. The first bevel gear 243 at the bottom end of the vertical rotating shaft 242 is meshed with the second bevel gear 245 on the transverse rotating shaft 2441, so that the transverse rotating shaft 2441 and the clamping block 244 are driven to rotate, and precise adjustment of multiple angles is realized. After the clamping block 244 firmly clamps the wind power bearing, the motor stops driving and the clamping process is completed. At this time, the wind power bearing is accurately fixed at a predetermined machining position, and is ready for a subsequent machining operation.

After the wind power bearing is firmly clamped, various machining operations such as turning, grinding, drilling and the like can be performed. In the processing process, the tool is kept stable, and the processing precision and efficiency are ensured. After the machining is completed, the first screw motor 15 and the second screw motor 23 are reversely started, so that the clamping screw 13 and the adjusting screw 22 reversely rotate, and the clamping force on the wind power bearing is released. And taking the processed wind power bearing out of the tool, and preparing for the next treatment or quality inspection.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a wind-powered electricity generation bearing processing frock, includes horizontal drive subassembly (1), its characterized in that, equal slidable mounting in top both sides of horizontal drive subassembly (1) has regulating block (2), horizontal drive subassembly (1) include shell (12), clamping screw (13) are installed in the inside rotation of shell (12), clamping screw (13) divide into two sections opposite screw thread, and first lead screw slider (14) are installed to equal screw thread on every section, and the top of two first lead screw sliders (14) all slides and runs through and extend to shell (12) outside and be connected with regulating block (2), two regulating block (2) all set up fluted (21) in the side that is close to each other, every regulating block (21) are all rotated in inside and are installed regulating screw (22), two equal screw thread installs second lead screw slider (24) on regulating screw (22), two clamping block (244) are installed in the equal rotation on the tip that second lead screw slider (24) are close to each other.

2. The wind power bearing machining tool according to claim 1, wherein one end of the clamping screw rod (13) is driven to rotate through a first screw rod motor (15), and the top end of the adjusting screw rod (22) is driven to rotate through a second screw rod motor (23).

3. The wind power bearing machining tool according to claim 1, wherein a plurality of supporting legs (11) are arranged at the bottom of the horizontal driving assembly (1).

4. The wind power bearing machining tool according to claim 1, wherein an opening (121) is formed in the top of the shell (12), and the tops of the two first screw rod sliding blocks (14) slide through the opening (121) to extend to the outer side and are fixedly connected with an adjusting block (2).

5. The wind power bearing machining tool according to claim 1, wherein a through threaded hole (241) is formed in the inner end of the second screw rod sliding block (24), and an end thread of the adjusting screw rod (22) penetrates through the threaded hole (241).

6. The wind power bearing machining tool according to claim 1, wherein the transverse rotating shaft (2441) is rotatably arranged in the outer end of the clamping block (244), the second bevel gear (245) is arranged on the transverse rotating shaft (2441), the vertical rotating shaft (242) is rotatably arranged at the top of the inner part of the outer end of the clamping block (244), the first bevel gear (243) is arranged at the bottom end of the vertical rotating shaft (242), the first bevel gear (243) is meshed with the second bevel gear (245), the adjusting motor (246) is arranged at the top of the clamping block (244), and the top end of the vertical rotating shaft (242) rotatably penetrates through the outer side of the top of the clamping block (244) and is fixedly connected with an output shaft of the adjusting motor (246).

7. The wind power bearing machining tool of claim 1, wherein the two clamping blocks (244) are provided with clamping grooves on the side surfaces close to each other, and the two clamping grooves are used for matching the side surfaces of the bearing workpiece so as to clamp and fix the bearing workpiece.