CN213646814U

CN213646814U - Z-axis balance structure for direct-drive machine tool

Info

Publication number: CN213646814U
Application number: CN202022267754.7U
Authority: CN
Inventors: 罗超; 陈军; 孙旭龙
Original assignee: Apas Precision Machinery Shanghai Co Ltd
Current assignee: Apas Cnc Machine Tool Manufacturing Shanghai Co ltd
Priority date: 2020-10-13
Filing date: 2020-10-13
Publication date: 2021-07-09
Anticipated expiration: 2030-10-13

Abstract

The utility model discloses a Z-axis balance structure for a direct-drive machine tool, which comprises a main shaft, wherein the main shaft is arranged and installed below a ram; the ram is connected with a sliding seat, and linear guide rails are arranged on two sides of the ram and one side close to the sliding seat; the guide rails are provided with sliding blocks; a grating ruler and a nut mounting seat are mounted on the rear side of the ram; a positioning key groove is formed in the middle of the ram and nut mounting seat; positioning keys are connected in positioning key grooves on the ram and nut mounting seat; the grating ruler is connected with the slide seat screw; the middle parts of the two sides of the ram are respectively provided with a linear motor stator; mounting plates are mounted on two sides of the inner side of the sliding seat, and a motor support is mounted at the upper end of the sliding seat; a servo motor is arranged on the motor support; a screw rod nut is arranged on the nut mounting seat; the screw rod nut and the nut mounting seat are fixedly connected through a screw; the screw rod nut is connected with a screw rod; the lead screw is fixed on the sliding seat and the motor support. This patent utilizes the gravity of Z axle part is offset to the last thrust of lead screw motion for linear electric motor can the up-and-down motion at drive Z axle part.

Description

Z-axis balance structure for direct-drive machine tool

Technical Field

The utility model relates to a Z axle balanced structure for directly driving lathe belongs to motor technical field.

Background

With the wide application of linear motor in various industries, the linear motor has the direct transmission characteristic of non-contact and non-abrasion, and the speed, precision, service life and other aspects are obviously improved compared with the traditional transmission modes such as screw rods, gears and the like.

Along with the increasing appearance of direct-drive machine tools in the machine tool manufacturing industry, solutions for direct-drive application are increasing; most of traditional Z-axis balance schemes of machine tools use a nitrogen balance system, an oil pressure balance system and a counterweight balance system, but most of the balance systems cannot be accurately controlled, so that the speed and the acceleration of the machine tool are low, and the high precision is difficult to realize; compared with the Z-axis balance scheme of the traditional machine tool, the Z-axis of the direct-drive machine tool needs higher speed and acceleration and higher precision, so that a new balance solution is needed to solve the problem that the traditional balance application scheme is not matched with the direct-drive machine tool.

SUMMERY OF THE UTILITY MODEL

To the problem that above-mentioned prior art exists, the utility model provides a Z axle balanced structure for directly driving the lathe to solve above-mentioned technical problem.

In order to realize the purpose, the utility model discloses a technical scheme is: a Z-axis balance structure for a direct-drive machine tool comprises a main shaft, a sliding seat and a ram; the main shaft is arranged and installed below the ram; one side of the ram is connected with a sliding seat, and the left side and the right side of the ram and one side close to the sliding seat are provided with linear guide rails; the linear guide rail and the ram are fixed by screws; each guide rail is provided with a sliding block;

a grating ruler and a nut mounting seat are mounted on the rear side of the ram; positioning key grooves are formed in the middle positions of the ram and the nut mounting seat; positioning keys are connected in positioning key grooves on the ram and nut mounting seats; the grating ruler is fixedly connected with the sliding seat screw; a group of linear motor stators are respectively arranged in the middle positions of the left side and the right side of the ram;

mounting plates for arranging linear motor rotors are mounted on the left side and the right side of the inner side of the sliding seat, and a motor support is mounted at the upper end of the sliding seat; a servo motor is arranged on the motor support;

a screw rod nut is arranged above the nut mounting seat; the screw rod nut and the nut mounting seat are fixedly connected through a screw; the lead screw nut is connected with a lead screw; the lead screw is fixed on the sliding seat and the motor support.

Furthermore, the slide seat is installed on one side of the ram, and the slide seat is fixedly connected with the slide block through screws.

Furthermore, the linear motor stator and the ram are fixed in a screw connection mode.

Further, the slide seat is fixedly connected with a mounting plate of the linear motor rotor through screws; the mounting plate is fixedly connected with the linear motor rotor through screws.

Furthermore, an upper limiting block and a lower limiting block are arranged above and below the inner side of the sliding seat; the upper limiting block and the motor support are fixed in a screw connection mode; and the lower limiting block is fixed at the position below the screw rod.

The utility model has the advantages that: compare with current traditional Z axle balance scheme, the utility model discloses: the gravity of the Z-axis component is counteracted by utilizing the upward thrust of the motion of the screw rod, so that when the linear motor drives the Z-axis component to move up and down, the current of the linear motor cannot generate rapid change due to the self weight of the Z axis, and the results of poor dynamic response, uneven thrust, overlarge speed fluctuation, larger motion following error change and the like of the linear motor are avoided; meanwhile, the problem that the Z axis cannot be self-locked when the Z axis part is driven by a linear motor is avoided, the position of the Z axis can be locked by the servo motor and the lead screw nut after the linear motor stops working, and the danger of falling and impact is avoided; on the other hand, the gravity of the Z-axis part is balanced by utilizing the upper thrust generated by the screw rod, compared with the traditional nitrogen balance, oil pressure balance and counterweight balance, the screw rod has strong motion controllability and strong external adjustability, and the technical intervention is simple, direct, effective and controllable.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic front view of the present invention;

FIG. 3 is a schematic side sectional view of the present invention;

FIG. 4 is an enlarged schematic view of the structure A of FIG. 3;

fig. 5 is a schematic plan view of the structure of the present invention.

In the figure: 1. the device comprises a main shaft, 2, a sliding seat, 21, an upper limiting block, 22, a lower limiting block, 3, a ram, 31, a grating ruler, 32, a nut mounting seat, 33, a positioning key groove, 34, a positioning key, 4, a guide rail, 5, a sliding block, 6, a linear motor stator, 7, a linear motor rotor, 71, a mounting plate, 8, a motor support, 81, a servo motor, 9, a screw nut, 91 and a screw rod.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clear, the present invention is further described in detail through the accompanying drawings and embodiments. It should be understood, however, that the description herein of specific embodiments is only intended to illustrate the invention and not to limit the scope of the invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the terms used herein in the specification of the present invention are for the purpose of describing particular embodiments only and are not intended to limit the present invention.

As shown in fig. 1, 2 and 3, a Z-axis balance structure for a direct-drive machine tool comprises a main shaft 1, a sliding seat 2 and a ram 3; the main shaft 1 is arranged below the ram 3; one side of the ram 3 is connected with a sliding seat 2, and the left side and the right side of the ram 3 and one side close to the sliding seat 2 are both provided with a linear guide rail 4; the linear guide rail 4 and the ram 3 are fixed by screws; each guide rail 4 is provided with a slide block 5; the sliding seat 2 is arranged on one side of the ram 3, and the sliding seat 2 is fixedly connected with the sliding block 5 through screws.

Referring to fig. 3 and 4, a grating ruler 31 and a nut mounting seat 32 are mounted on the rear side of the ram 3; positioning key grooves 33 are formed in the middle positions of the ram 3 and the nut mounting seat 32; a positioning key 34 is connected in the positioning key groove 33 on the ram 3 and the nut mounting seat 32; the grating ruler 31 is fixedly connected with the sliding seat 2 through screws; a group of linear motor stators 6 are respectively arranged in the middle positions of the left side and the right side of the ram 3; the linear motor stator 6 and the ram 3 are fixed in a screw connection mode.

Referring to fig. 5, mounting plates 71 for arranging linear motor movers 7 are mounted on the left and right sides of the inner side of the sliding seat 2, and a motor support 8 is mounted at the upper end of the sliding seat 2; a servo motor 81 is arranged on the motor support 8; the slide seat 2 is fixedly connected with the mounting plate 71 of the linear motor rotor 7 by screws; the mounting plate 71 is fixedly connected with the linear motor mover 7 through screws.

An upper limit block 21 and a lower limit block 22 are arranged above and below the inner side of the sliding seat 2; the upper limiting block 21 and the motor support 8 are fixed in a screw connection mode; the lower stopper 22 is fixed to a position below the screw 91.

A screw rod nut 9 is arranged above the nut mounting seat 32; the screw rod nut 9 and the nut mounting seat 32 are fixedly connected through a screw; the lead screw nut 9 is connected with a lead screw 91; the screw 91 is fixed on the sliding seat 2 and the motor support 8.

The working principle is as follows:

and meanwhile, a servo motor and a linear motor which are connected with the lead screw are started, the servo motor drives the lead screw nut system to enable the Z shaft part to move, upward thrust generated by the lead screw nut system is balanced and offset with gravity generated by the Z shaft part, and therefore when the linear motor drives the Z shaft part to do high-speed and high-precision movement, no gravity influences are involved in a dynamic control system.

The utility model discloses: the gravity of the Z-axis component is counteracted by utilizing the upward thrust of the motion of the screw rod, so that when the linear motor drives the Z-axis component to move up and down, the current of the linear motor cannot be changed rapidly due to the self weight of the Z axis, and the results of poor dynamic response, large change of motion following errors and the like of the linear motor are avoided; meanwhile, the problem that the Z axis cannot be self-locked when the Z axis part is driven by a linear motor is avoided, the position of the Z axis can be locked by the servo motor and the lead screw nut after the linear motor stops working, and the danger of falling and impact is avoided; on the other hand, the gravity of the Z-axis part is balanced by utilizing the upper thrust generated by the screw rod, compared with the traditional nitrogen balance, oil pressure balance and counterweight balance, the screw rod has strong motion controllability and strong external adjustability, and the technical intervention is simple, direct, effective and controllable.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modification, equivalent replacement or improvement made within the spirit and principle of the present invention should be included in the present invention.

Claims

1. A Z-axis balance structure for a direct-drive machine tool comprises a main shaft (1), a sliding seat (2) and a ram (3); the main shaft (1) is arranged and installed below the ram (3); one side of the ram (3) is connected with a sliding seat (2), and the linear guide rail mechanism is characterized in that the left side and the right side of the ram (3) and one side close to the sliding seat (2) are provided with linear guide rails (4); the linear guide rail (4) and the ram (3) are fixed by screws; each guide rail (4) is provided with a sliding block (5);

a grating ruler (31) and a nut mounting seat (32) are mounted on the rear side of the ram (3); positioning key grooves (33) are formed in the middle positions of the ram (3) and the nut mounting seat (32); a positioning key (34) is connected in the ram (3) and a positioning key groove (33) on the nut mounting seat (32); the grating ruler (31) is fixedly connected with the sliding seat (2) through a screw; a group of linear motor stators (6) are respectively arranged in the middle positions of the left side and the right side of the ram (3);

mounting plates (71) for arranging linear motor rotors (7) are mounted on the left side and the right side of the inner side of the sliding seat (2), and a motor support (8) is mounted at the upper end of the sliding seat (2); a servo motor (81) is arranged on the motor support (8);

a screw rod nut (9) is arranged above the nut mounting seat (32); the screw rod nut (9) and the nut mounting seat (32) are fixedly connected through a screw; the lead screw nut (9) is connected with a lead screw (91); and the screw rod (91) is fixed on the sliding seat (2) and the motor support (8).

2. The Z-axis balance structure for the direct-drive machine tool is characterized in that the sliding seat (2) is installed on one side of the ram (3), and the sliding seat (2) is fixedly connected with the sliding block (5) through a screw.

3. The Z-axis balance structure for the direct-drive machine tool is characterized in that the linear motor stator (6) and the ram (3) are fixed in a screw connection mode.

4. The Z-axis balance structure for the direct-drive machine tool is characterized in that the sliding seat (2) is fixedly connected with a mounting plate (71) of a linear motor rotor (7) through screws; the mounting plate (71) is fixedly connected with the linear motor rotor (7) through screws.

5. The Z-axis balance structure for the direct-drive machine tool is characterized in that an upper limiting block (21) and a lower limiting block (22) are arranged above and below the inner side of the sliding seat (2); the upper limiting block (21) and the motor support (8) are fixed in a screw connection mode; the lower limiting block (22) is fixed at the position below the screw rod (91).