CN210615249U - Milling machine for machining bottom plate of part in wind power magnetic pole module - Google Patents

Abstract

The utility model provides a milling machine is used in processing of spare part bottom plate among wind-powered electricity generation magnetic pole module, include: a base; a Y-axis drive assembly; the supporting seat is arranged on the upper surface of the Y-axis sliding seat; the X-axis driving assembly is arranged on the upper surface of the supporting seat; the bottom surface of the workbench is erected on the upper surface of the X-axis sliding seat; the magnetic sucker is arranged on the inner wall of the working surface; the upright post is vertically arranged on the upper surface of the base; the Z-axis driving component is arranged on the upright post; the tool apron is arranged on the Z-axis sliding seat, and the bottom surface of the tool apron is connected with a milling cutter; and a controller. The milling machine can be once only processed spare part bottom plate among 30 wind-powered electricity generation magnetic pole modules, and the stability management and control of quality is relatively good to can follow X, Y, Z three directions and adjust milling cutter cutting angle, guarantee the processing success rate, promote the yield.

Description

Milling machine for machining bottom plate of part in wind power magnetic pole module

Technical Field

The utility model belongs to the technical field of spare part bottom plate processing in the wind-powered electricity generation magnetic pole module, specifically, relate to a milling machine is used in processing of spare part bottom plate in wind-powered electricity generation magnetic pole module.

Background

Wind power generation refers to converting kinetic energy of wind into electric energy. Wind energy is a clean and pollution-free renewable energy source, and is used by people for a long time, mainly for pumping water, grinding surfaces and the like through windmills, and at present, people are interested in how to use wind to generate electricity.

The wind power generation is very environment-friendly, and the wind energy is huge, so that the wind power generation is increasingly paid attention by various countries in the world.

A capacitor is an element that stores electricity and electric energy (potential energy). One conductor is surrounded by another conductor or the electric field lines emanating from one conductor all terminate in the conductor system of the other conductor, called a capacitor.

And the capacitor bank used for storing wind power is the wind power module, and at present, the existing processing technology of the bottom plate of the wind power module is that 4 products are processed, so that the efficiency is lower, and the quality of the whole batch of products can not be controlled.

For milling machines, chinese patent publication No. CN102145456B provides a table top milling machine, a gantry table top milling machine, and a combined motion platform. The table top milling machine comprises: the X-axis motion platform, the Y-axis motion platform and the Z-axis motion platform; the X-axis and Y-axis motion platforms respectively comprise a sliding platform and a sliding base, and the sliding base of the Y-axis motion platform is fixed above the sliding platform of the X-axis motion platform; the sliding base comprises air floatation guide rails formed on two sides and a first groove formed in the middle part; the X-axis motion platform and the Y-axis motion platform respectively comprise linear motors, each linear motor comprises a stator and a rotor, the stators are fixed to the bottom of the corresponding first groove, and the rotors are fixed to the bottom of the sliding platform and arranged opposite to the stators. However, although the milling machine provided by the patent can realize the feeding motion in three directions of the X axis, the Y axis and the Z axis, the milling machine is not suitable for processing the bottom plates of the parts in the multi-piece wind power magnetic pole module, and the number of the processed pieces at one time is not 4 in the prior art.

SUMMERY OF THE UTILITY MODEL

For solving the problem that exists, an object of the utility model is to provide a milling machine is used in processing of spare part bottom plate in wind-powered electricity generation magnetic pole module, the milling machine can once only process the spare part bottom plate in 30 wind-powered electricity generation magnetic pole modules, and the stability management and control of quality is better to can follow X, Y, Z three directions and adjust milling cutter cutting angle, guarantee the processing success rate, promote the yield.

In order to achieve the above purpose, the technical scheme of the utility model is that:

the utility model provides a milling machine is used in processing of spare part bottom plate among wind-powered electricity generation magnetic pole module, the milling machine includes: a base placed horizontally; the Y-axis driving assembly comprises a Y-axis lead screw arranged in the middle of the upper surface of the base along the length direction of the upper surface of the base, a Y-axis servo motor in transmission connection with the Y-axis lead screw is erected on the upper surface of the base at one end of the Y-axis lead screw, a Y-axis sliding seat is sleeved on the Y-axis lead screw in a sliding manner, Y-axis sliding rails are respectively arranged on the upper surfaces of the base at two sides of the Y-axis lead screw along the length direction of the base, at least one Y-axis sliding block is arranged on each Y-axis sliding rail in a sliding manner, and the Y-axis sliding seats are erected on the two; the supporting seat is horizontally arranged on the upper surface of the Y-axis sliding seat, and the supporting seat and the base are in a cross structure; the X-axis driving assembly comprises an X-axis lead screw arranged in the middle of the upper surface of a supporting seat along the length direction of the upper surface of the supporting seat, an X-axis servo motor in transmission connection with the X-axis lead screw is erected on the upper surface of the supporting seat at one end of the X-axis lead screw, an X-axis sliding seat is sleeved on the X-axis lead screw in a sliding manner, X-axis sliding rails are respectively arranged on the upper surfaces of the supporting seats at two sides of the X-axis lead screw along the length direction of the supporting seat, at least one X-axis sliding block is arranged on each X-axis sliding rail in a sliding manner, and the X-axis sliding seat is erected; the workbench is a box body, the length direction of the workbench is parallel to the length direction of the supporting seat, the bottom surface of the workbench is erected on the upper surface of the X-axis sliding seat, and the upper surface of the workbench is a working surface; the magnetic sucker is arranged on the inner wall of the working surface of the workbench, the magnetic sucker forms adsorption on a plurality of component bottom plates arranged on the working surface of the workbench, and one end of the workbench is provided with a control button in communication connection with the magnetic sucker to form control on the opening and closing of the magnetic sucker; the stand column is vertically arranged on the upper surface of the base positioned on the outer side of the Y-axis servo motor; the Z-axis driving assembly comprises a Z-axis lead screw vertically arranged in the middle of one surface, facing the Y-axis servo motor, of the stand column, the upper end of the Z-axis lead screw is connected with the Z-axis servo motor, a Z-axis sliding seat is slidably sleeved on the Z-axis lead screw, Z-axis sliding rails are vertically arranged on the surfaces of the stand columns on two sides of the Z-axis lead screw respectively, at least one Z-axis sliding block is slidably arranged on each Z-axis sliding rail, and the Z-axis sliding seats are arranged on the two Z-axis sliding blocks; the tool apron is arranged on the Z-axis sliding seat, a milling cutter is vertically connected to the bottom surface of the tool apron, and the end surface of the milling cutter faces to the working surface of the workbench; and the Y-axis servo motor, the X-axis servo motor and the Z-axis servo motor are respectively in communication connection with the controller.

Furthermore, the number of Y-axis sliding blocks on each Y-axis sliding rail is 2, and the Y-axis sliding blocks are arranged at intervals along the length direction of the Y-axis sliding rail.

Furthermore, the number of the X-axis sliding blocks on each X-axis sliding rail is 2, and the X-axis sliding blocks are arranged at intervals along the length direction of the X-axis sliding rail.

Furthermore, the number of the Z-axis sliding blocks on each Z-axis sliding rail is 2, and the Z-axis sliding blocks are arranged at intervals along the length direction of the Z-axis sliding rail.

Furthermore, a Y-axis fixing seat is arranged on the base, located at one end, far away from the Y-axis servo motor, of the Y-axis lead screw, and the Y-axis lead screw is inserted into the Y-axis fixing seat in a rotating mode.

Furthermore, an X-axis fixing seat is arranged on a supporting seat located at one end, far away from the X-axis servo motor, of the X-axis lead screw, and the X-axis lead screw is inserted into the X-axis fixing seat in a rotating mode.

Furthermore, a Z-axis fixing seat is convexly arranged on the surface of the upright column positioned at the lower end of the Z-axis lead screw, and the Z-axis lead screw is rotatably inserted into the Z-axis fixing seat.

Furthermore, a magnetic conductive coating is coated on the working surface of the workbench.

Further, the milling cutter is a face milling cutter.

The beneficial effects of the utility model reside in that:

milling machine is used in processing of spare part bottom plate in the wind-powered electricity generation magnetic pole module, structural design is ingenious, through set up magnetic chuck in the workstation, carry out the magnetism absorption to spare part bottom plate in the wind-powered electricity generation magnetic pole module of placing on the working face of workstation to can once only process 30 spare part bottom plates in the wind-powered electricity generation magnetic pole module, the stability management and control of quality is relatively better, and can follow X, Y, Z three directions and adjust milling cutter cutting angle, guarantee the processing success rate, promote the yield.

Drawings

Fig. 1 is the utility model provides a spare part bottom plate processing sets up the structural schematic diagram of first recess one side with the milling machine among wind-powered electricity generation magnetic pole module.

Detailed Description

Referring to fig. 1, a milling machine is used in processing of spare part bottom plate among wind-powered electricity generation magnetic pole module, milling machine includes: a base 1, horizontally placed; the Y-axis driving assembly 2 comprises a Y-axis lead screw 21 arranged in the middle of the upper surface of the base 1 along the length direction of the upper surface of the base 1, a Y-axis servo motor 22 in transmission connection with the Y-axis lead screw 21 is erected on the upper surface of the base 1 at one end of the Y-axis lead screw 21, a Y-axis sliding seat 23 is sleeved on the Y-axis lead screw 21 in a sliding manner, Y-axis sliding rails 24 are respectively arranged on the upper surfaces of the bases 1 at two sides of the Y-axis lead screw 21 along the length direction of the base 1, at least one Y-axis sliding block 25 is arranged on each Y-axis sliding rail 24 in a sliding manner, and the Y-axis sliding seat 23 is erected on; the supporting seat 3 is horizontally arranged on the upper surface of the Y-axis sliding seat 23, and the supporting seat 3 and the base 1 are in a cross structure; the X-axis driving assembly 4 comprises an X-axis lead screw 41 arranged in the middle of the upper surface of the supporting seat 3 along the length direction of the upper surface of the supporting seat 3, an X-axis servo motor (not shown) in transmission connection with the X-axis lead screw 41 is erected on the upper surface of the supporting seat 3 at one end of the X-axis lead screw 41, an X-axis sliding seat 42 is slidably sleeved on the X-axis lead screw 41, X-axis sliding rails 43 are respectively arranged on the upper surfaces of the supporting seats 3 at two sides of the X-axis lead screw 41 along the length direction of the supporting seat 3, at least one X-axis sliding block 44 is slidably arranged on each X-axis sliding rail 43, and the X-axis sliding seat 42 is erected on the two X-; the workbench 5 is a box body, the length direction of the workbench 5 is parallel to the length direction of the supporting seat 3, the bottom surface of the workbench 5 is erected on the upper surface of the X-axis sliding seat 42, and the upper surface of the workbench 5 is a working surface 51; a magnetic suction cup 6 installed on the inner wall 51 of the working surface of the table 5, wherein the magnetic suction cup 6 forms an adsorption to a plurality of component bottom plates (not shown) installed on the working surface 51 of the table 5, and a control button 52 connected to the magnetic suction cup 6 in a communication manner is provided at one end of the table 5 to control the opening and closing of the magnetic suction cup 6; the upright post 7 is vertically arranged on the upper surface of the base 1 positioned outside the Y-axis servo motor 22; the Z-axis driving assembly 8 comprises a Z-axis lead screw 81 vertically arranged in the middle of one surface of the upright post 7 facing the Y-axis servo motor 22, the upper end of the Z-axis lead screw 81 is connected with a Z-axis servo motor 82, a Z-axis sliding seat 83 is slidably sleeved on the Z-axis lead screw 81, Z-axis sliding rails 84 are vertically arranged on the surfaces of the upright posts 7 positioned on two sides of the Z-axis lead screw 81 respectively, at least one Z-axis sliding block 85 is slidably arranged on each Z-axis sliding rail 84, and the Z-axis sliding seat 83 is arranged on the two Z-axis sliding blocks 85; the tool apron 9 is arranged on the Z-axis sliding seat 85, a milling cutter 91 is vertically connected to the bottom surface of the tool apron 9, and the end surface of the milling cutter 91 faces the working surface 51 of the workbench 5; and a controller (not shown), wherein the Y-axis servo motor 22, the X-axis servo motor and the Z-axis servo motor 82 are respectively connected with the controller in a communication way.

Furthermore, the number of the Y-axis sliders 24 on each Y-axis slide rail 24 is 2, and the Y-axis sliders 24 are arranged at intervals along the length direction of the Y-axis slide rail 24.

Further, the number of the X-axis sliders 44 on each X-axis slide rail 43 is 2, and the X-axis sliders are arranged at intervals along the length direction of the X-axis slide rail 43.

Further, the number of the Z-axis sliding blocks 85 on each Z-axis sliding rail 84 is 2, and the Z-axis sliding blocks are arranged at intervals along the length direction of the Z-axis sliding rail 84.

Further, a Y-axis fixing seat 26 is arranged on the base 1 at one end of the Y-axis lead screw 21 far away from the Y-axis servo motor 22, and the Y-axis lead screw 21 is rotatably inserted into the Y-axis fixing seat 26.

Further, an X-axis fixing seat 45 is arranged on the supporting seat at one end, away from the X-axis servo motor, of the X-axis lead screw 41, and the X-axis lead screw 41 is rotatably inserted into the X-axis fixing seat 45.

Further, a Z-axis fixing seat 86 is convexly arranged on the surface of the upright post 7 at the lower end of the Z-axis lead screw 81, and the Z-axis lead screw 81 is rotatably inserted into the Z-axis fixing seat 86.

Further, a magnetic conductive coating (not shown) is applied to the working surface 51 of the table 5.

Further, the milling cutter 91 is a face milling cutter.

And simultaneously, the utility model also provides a spare part bottom plate processing is with under the process flow of milling machine among wind-powered electricity generation magnetic pole module:

processing a plurality of spare part bottom plates and loading in the working face 51 of workstation 5, press control button 52, open the magnetic circuit in magnetic chuck 6, open magnetic chuck 6, magnetic chuck 6 adsorbs a plurality of spare part bottom plates on working face 51, controller control Z axle servo motor 82, drive milling cutter 91 processes the cutting to the spare part bottom plate on the workstation 5, controller control Y axle servo motor 22 and X axle servo motor and, drive workstation 5 horizontal longitudinal movement, cooperate milling cutter 91 to process the cutting to the spare part bottom plate on the workstation 5.

Milling machine is used in processing of spare part bottom plate in the wind-powered electricity generation magnetic pole module, structural design is ingenious, through set up magnetic chuck 6 in workstation 5, carry out the magnetism absorption to spare part bottom plate in the wind-powered electricity generation magnetic pole module of placing on workstation 5's working face 51, thereby can once only process 30 spare part bottom plates in the wind-powered electricity generation magnetic pole module, the stability management and control of quality is comparatively good, and can follow X, Y, Z three directions and adjust milling cutter cutting angle, guarantee the processing success rate, promote the yield.

It should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and are not limited. Although the present invention has been described in detail with reference to the preferred embodiments, those skilled in the art will appreciate that various modifications and equivalent arrangements can be made without departing from the scope of the present invention, which is intended to be covered by the appended claims.

Claims (9)

1. The utility model provides a milling machine is used in processing of spare part bottom plate among wind-powered electricity generation magnetic pole module which characterized in that, the milling machine includes:

a base placed horizontally;

the Y-axis driving assembly comprises a Y-axis lead screw arranged in the middle of the upper surface of the base along the length direction of the upper surface of the base, a Y-axis servo motor in transmission connection with the Y-axis lead screw is erected on the upper surface of the base at one end of the Y-axis lead screw, a Y-axis sliding seat is sleeved on the Y-axis lead screw in a sliding manner, Y-axis sliding rails are respectively arranged on the upper surfaces of the base at two sides of the Y-axis lead screw along the length direction of the base, at least one Y-axis sliding block is arranged on each Y-axis sliding rail in a sliding manner, and the Y-axis sliding seats are erected on the two;

the supporting seat is horizontally arranged on the upper surface of the Y-axis sliding seat, and the supporting seat and the base are in a cross structure;

the X-axis driving assembly comprises an X-axis lead screw arranged in the middle of the upper surface of a supporting seat along the length direction of the upper surface of the supporting seat, an X-axis servo motor in transmission connection with the X-axis lead screw is erected on the upper surface of the supporting seat at one end of the X-axis lead screw, an X-axis sliding seat is sleeved on the X-axis lead screw in a sliding manner, X-axis sliding rails are respectively arranged on the upper surfaces of the supporting seats at two sides of the X-axis lead screw along the length direction of the supporting seat, at least one X-axis sliding block is arranged on each X-axis sliding rail in a sliding manner, and the X-axis sliding seat is erected;

the workbench is a box body, the length direction of the workbench is parallel to the length direction of the supporting seat, the bottom surface of the workbench is erected on the upper surface of the X-axis sliding seat, and the upper surface of the workbench is a working surface;

the magnetic sucker is arranged on the inner wall of the working surface of the workbench, the magnetic sucker forms adsorption on a plurality of component bottom plates arranged on the working surface of the workbench, and one end of the workbench is provided with a control button in communication connection with the magnetic sucker to form control on the opening and closing of the magnetic sucker;

the stand column is vertically arranged on the upper surface of the base positioned on the outer side of the Y-axis servo motor;

the Z-axis driving assembly comprises a Z-axis lead screw vertically arranged in the middle of one surface, facing the Y-axis servo motor, of the stand column, the upper end of the Z-axis lead screw is connected with the Z-axis servo motor, a Z-axis sliding seat is slidably sleeved on the Z-axis lead screw, Z-axis sliding rails are vertically arranged on the surfaces of the stand columns on two sides of the Z-axis lead screw respectively, at least one Z-axis sliding block is slidably arranged on each Z-axis sliding rail, and the Z-axis sliding seats are arranged on the two Z-axis sliding blocks;

the tool apron is arranged on the Z-axis sliding seat, a milling cutter is vertically connected to the bottom surface of the tool apron, and the end surface of the milling cutter faces to the working surface of the workbench;

and the Y-axis servo motor, the X-axis servo motor and the Z-axis servo motor are respectively in communication connection with the controller.

2. The milling machine for machining the bottom plate of the part in the wind power magnetic pole module according to claim 1, wherein the number of the Y-axis sliding blocks on each Y-axis sliding rail is 2, and the Y-axis sliding blocks are arranged at intervals along the length direction of the Y-axis sliding rail.

3. The milling machine for machining the bottom plate of the part in the wind power magnetic pole module according to claim 1, wherein the number of the X-axis slide blocks on each X-axis slide rail is 2, and the X-axis slide blocks are arranged at intervals along the length direction of the X-axis slide rail.

4. The milling machine for machining the bottom plate of the part in the wind power magnetic pole module according to claim 1, wherein the number of the Z-axis sliding blocks on each Z-axis sliding rail is 2, and the Z-axis sliding blocks are arranged at intervals along the length direction of the Z-axis sliding rail.

5. The milling machine for machining bottom plates of parts in wind power magnetic pole modules according to claim 1, wherein a Y-axis fixing seat is arranged on a base located at one end, away from a Y-axis servo motor, of the Y-axis lead screw, and the Y-axis lead screw is rotatably inserted into the Y-axis fixing seat.

6. The milling machine for machining bottom plates of parts in wind power magnetic pole modules according to claim 1, wherein an X-axis fixing seat is arranged on a supporting seat at one end of the X-axis lead screw, which is far away from the X-axis servo motor, and the X-axis lead screw is rotatably inserted into the X-axis fixing seat.

7. The milling machine for machining bottom plates of parts in wind power magnetic pole modules according to claim 1, wherein a Z-axis fixing seat is convexly arranged on the surface of the upright column at the lower end of the Z-axis lead screw, and the Z-axis lead screw is rotatably inserted into the Z-axis fixing seat.

8. The milling machine for machining the bottom plate of the part in the wind power magnetic pole module as claimed in claim 1, wherein the working surface of the workbench is coated with a magnetically conductive coating.

9. The milling machine for machining the bottom plate of the part in the wind power magnetic pole module according to claim 1, wherein the milling cutter is a face milling cutter.

Images