CN216781140U - High-precision linear motor numerical control machine tool - Google Patents
High-precision linear motor numerical control machine tool Download PDFInfo
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- CN216781140U CN216781140U CN202123258228.5U CN202123258228U CN216781140U CN 216781140 U CN216781140 U CN 216781140U CN 202123258228 U CN202123258228 U CN 202123258228U CN 216781140 U CN216781140 U CN 216781140U
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Abstract
The utility model relates to the technical field of cutting equipment, in particular to a high-precision linear motor numerical control machine tool which comprises a machine body, a workbench arranged on the machine body, and a cutting main shaft arranged on the machine body, wherein an X-axis driving assembly for driving the main shaft to move along an X axis and a Z-axis driving assembly for driving the main shaft to move along a Z axis are arranged on the machine body, and a Y-axis driving assembly for driving the workbench to move along a Y axis is arranged on the machine body. The utility model has the effects of sensitive response and high processing quality.
Description
Technical Field
The utility model relates to the technical field of cutting equipment, in particular to a high-precision linear motor numerical control machine tool.
Background
Machine tools are machines for manufacturing machines, also called machine tools or machine tools, and are conventionally called machine tools for short. Generally, the cutting machine is classified into a metal cutting machine, a forging machine, a woodworking machine, and the like. The methods for machining mechanical parts in modern machine manufacturing are numerous: in addition to cutting, casting, forging, welding, pressing, extruding, etc., however, in general, a part requiring high precision and fine surface roughness is finished by cutting on a machine tool.
When a workpiece is cut by a machine tool, a cutter needs to change position continuously, and the existing machine tool cannot respond to a working signal well in time and quickly, so that the cutter cannot move to a specified position quickly in time, and the stock needs to be improved.
SUMMERY OF THE UTILITY MODEL
The utility model provides a high-precision linear motor numerical control machine tool aiming at the problems in the prior art and aims to solve the technical problems in the prior art.
The utility model provides a high-precision linear motor numerical control machine tool, which adopts the following technical scheme:
the utility model provides a high-accuracy linear electric motor digit control machine tool, includes the organism, set up in workstation on the organism, set up in cutting main shaft on the organism, be provided with the drive on the organism the main shaft is along the X axle drive assembly of X axle motion, with the drive the Z axle drive assembly of Z axle motion is followed to the main shaft, be provided with the drive on the organism the Y axle drive assembly of Y axle motion is followed to the workstation.
Preferably, the X-axis driving assembly includes an X-axis magnetic plate disposed on the machine body, and an X-axis mover slidably disposed on the X-axis magnetic plate, and a slide carriage is disposed on the X-axis mover; the Z-axis driving assembly comprises a Z-axis magnetic plate arranged on the slide carriage and a Z-axis rotor arranged on the Z-axis magnetic plate, a sliding plate is arranged on the Z-axis rotor, and the main shaft is arranged on the sliding plate.
Preferably, a cylinder with a lock is arranged on the slide carriage, and a piston rod of the cylinder with the lock is connected to the slide plate.
Preferably, the Y-axis driving assembly includes a Y-axis magnetic plate disposed on the machine body, and a Y-axis mover disposed on the Y-axis magnetic plate, and the worktable is disposed on the Y-axis mover.
Preferably, an X limit rubber pad is arranged on the machine body, an X collision block is arranged on the slide carriage, and the X limit rubber pad is positioned on a motion path of the X collision block; the slide carriage is provided with a Z-limit rubber pad, the slide carriage is provided with a Z collision block, and the Z-limit rubber pad is positioned on a motion path of the Z collision block; the machine body is provided with a Y-shaped limiting rubber mat which is positioned on the motion path of the workbench.
Preferably, two opposite sides of the Y-axis magnetic plate are provided with dustproof sealing strips.
In summary, the utility model includes at least one of the following beneficial technical effects:
an operator places a workpiece to be cut on the workbench, the Z-axis rotor works and drives the main shaft to move up and down, so that the workpiece is cut, the X-axis rotor motor works to drive the slide carriage to move along the X axis, the Y-axis rotor works and drives the workbench to move along the Y axis, so that the workpiece can be cut at multiple angles, and the X-axis rotor, the Z-axis rotor and the Y-axis rotor have sensitive response to electric signals, so that the cutting machine can be quickly started and stopped, and the processing quality of the workpiece is improved.
2. When accidents such as power failure occur, the cylinder with the lock automatically locks when the power is off, and the main shaft is prevented from falling.
Drawings
Fig. 1 is a schematic view of the overall structure of the present invention.
FIG. 2 is a schematic view showing the assembly relationship between the slide and the skateboard in the present invention.
In the figure: 1. a body; 11. an X-axis magnetic plate; 111. an X-axis mover; 112. an X limit rubber pad; 12. a slide carriage; 121. a Z-axis magnetic plate; 122. a Z-axis mover; 123. a cylinder with a lock; 124. a Z limit rubber pad; 13. a slide plate; 14. a Y-axis magnetic plate; 141. a Y-axis mover; 15. a Y limit rubber pad; 16. a dust seal strip; 2. a work table; 3. a main shaft.
Detailed Description
The present invention is described in further detail below with reference to FIGS. 1-2.
The embodiment of the utility model discloses a high-precision linear motor numerical control machine tool, which comprises a machine body 1, a workbench 2 connected to the machine body 1 in a sliding mode, a cutting main shaft 3 arranged on the machine body 1 along the vertical direction, wherein the workbench 2 is positioned right below the main shaft 3, the workbench 2 is used for placing a workpiece, a cutter for cutting the workpiece is arranged at the bottom end of the main shaft 3, a motor for driving the cutter to rotate is arranged in the main shaft 3, and an X-axis driving assembly for driving the main shaft 3 to move along an X axis and a Z-axis driving assembly for driving the main shaft 3 to move along a Z axis are arranged on the machine body 1.
Referring to fig. 1 and 2, specifically, the X-axis driving assembly includes an X-axis magnetic plate 11 fixedly installed on the machine body 1 along a horizontal direction, and an X-axis mover 111 slidably connected to the machine body 1, the X-axis mover 111 is located on a side surface of the X-axis magnetic plate 11, the X-axis mover 111 reciprocates along the X-axis direction under the action of a magnetic field of the X-axis magnetic plate 11 after being electrified, and a carriage 12 is fixedly installed on a side surface of the X-axis mover 111 away from the X-axis magnetic plate 11; z axle drive assembly includes that it deviates from Z axle magnetic sheet 121 on X axle rotor 111 surface to follow Z axle direction fixed mounting in slide carriage 12, slide and connect the Z axle rotor 122 on slide carriage 12, Z axle rotor 122 is located one side surface that Z axle magnetic sheet 121 deviates from slide carriage 12, Z axle rotor 122 circular telegram back is under the magnetic field effect of Z axle magnetic sheet 121, along Z axle direction reciprocating motion, Z axle rotor 122 deviates from the fixed surface mounting of slide carriage 12 and has slide 13, main shaft 3 fixed mounting is on slide 13. In addition, a Y-axis driving assembly for driving the worktable 2 to move along the Y-axis is disposed on the machine body 1, specifically, the Y-axis driving assembly includes a Y-axis magnetic plate 14 fixedly mounted on the machine body 1 along the Y-axis direction, and a Y-axis mover 141 slidably connected to the machine body 1, the Y-axis mover 141 is located right above the Y-axis magnetic plate 14, the worktable 2 is fixedly mounted on the Y-axis mover 141, and the Y-axis mover 141 reciprocates along the Y-axis direction under the magnetic field of the Y-axis magnetic plate 14 after being energized.
Referring to fig. 1 and 2, in addition, two X-limiting rubber pads 112 are fixedly mounted on the machine body 1, the two X-limiting rubber pads 112 are respectively located at the end portions of the two ends of the X-axis magnetic plate 11, the X-limiting rubber pads 112 can prevent the X-axis rotor 111 from being separated from the machine body 1, X collision blocks are fixedly mounted on the two opposite sides of the slide carriage 12, the X-limiting rubber pads 112 are located on the motion path of the X collision blocks, and the X collision blocks collide with the X-limiting rubber pads 112 to reduce the damage to the slide carriage 12; two Z-limit rubber pads 124 are fixedly arranged on the slide carriage 12, the two Z-limit rubber pads 124 are respectively positioned at the end parts of two ends of the Z-axis magnetic plate 121, the Z-limit rubber pads 124 can prevent the Z-axis rotor 122 from separating from the slide carriage 12, Z collision blocks are fixedly arranged on two opposite sides of the slide carriage 13, and the Z-limit rubber pads 124 are positioned on the motion path of the Z collision blocks; two Y-position limiting rubber pads 15 are fixedly mounted on the machine body 1, the two Y-position limiting rubber pads 15 are respectively located at the end parts of two ends of the Y-axis magnetic plate 14, the Y-position limiting rubber pads 15 are located on the motion path of the workbench 2, and the Y-position limiting rubber pads 15 can prevent the workbench 2 from being separated from the machine body 1. The slide carriage 12 is fixedly provided with a cylinder 123 with a lock, a piston rod of the cylinder 123 with the lock is connected to the slide plate 13, when an accident such as power failure occurs, the Z-axis rotor 122 can fall downwards, and the cylinder 123 with the lock is automatically locked when the power failure occurs, so that the main shaft 3 is prevented from falling. Meanwhile, the two opposite sides of the Y-axis magnetic plate 14 are fixedly provided with the dustproof sealing strips 16, the dustproof sealing strips 16 are fixedly arranged on the machine body 1, and the dustproof sealing strips 16 can reduce stains and the like from being sputtered on the Y-axis magnetic plate 14.
The implementation principle of the high-precision linear motor numerical control machine tool provided by the embodiment of the utility model is as follows: an operator places a workpiece to be cut on the workbench 2, the Z-axis rotor 122 works to drive the main shaft 3 to move up and down so as to cut the workpiece, the motor of the X-axis rotor 111 works to drive the slide carriage 12 to move along the X axis, the Y-axis rotor 141 works to drive the workbench 2 to move along the Y axis, so that the workpiece can be cut at multiple angles, and the X-axis rotor 111, the Z-axis rotor 122 and the Y-axis rotor 141 have sensitive response to electric signals, so that the cutting machine can be started and stopped quickly, and the processing quality of the workpiece is improved.
Although the present invention has been described with reference to the above preferred embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the utility model as defined by the appended claims.
Claims (6)
1. The utility model provides a high-accuracy linear electric motor digit control machine tool which characterized in that: including organism (1), set up in workstation (2) on organism (1), set up in cutting main shaft (3) on organism (1), be provided with the drive on organism (1) main shaft (3) are along the X axle drive assembly of X axle motion, with the drive main shaft (3) are along the Z axle drive assembly of Z axle motion, be provided with the drive on organism (1) workstation (2) are along the Y axle drive assembly of Y axle motion.
2. The high-precision numerical control machine tool for the linear motor according to claim 1, wherein: the X-axis driving assembly comprises an X-axis magnetic plate (11) arranged on the machine body (1) and an X-axis rotor (111) arranged on the X-axis magnetic plate (11) in a sliding mode, and a slide carriage (12) is arranged on the X-axis rotor (111);
the Z-axis driving assembly comprises a Z-axis magnetic plate (121) arranged on the slide carriage (12) and a Z-axis rotor (122) arranged on the Z-axis magnetic plate (121), a sliding plate (13) is arranged on the Z-axis rotor (122), and the main shaft (3) is arranged on the sliding plate (13).
3. A high precision linear motor numerical control machine tool according to claim 2, characterized in that: the slide carriage (12) is provided with a cylinder (123) with a lock, and a piston rod of the cylinder (123) with the lock is connected with the slide plate (13).
4. A high precision linear motor numerical control machine tool according to claim 2, characterized in that: the Y-axis driving assembly comprises a Y-axis magnetic plate (14) arranged on the machine body (1) and a Y-axis rotor (141) arranged on the Y-axis magnetic plate (14), and the workbench (2) is arranged on the Y-axis rotor (141).
5. The high-precision numerical control machine tool for the linear motor according to claim 4, wherein: an X-limiting rubber pad (112) is arranged on the machine body (1), an X-collision block is arranged on the slide carriage (12), and the X-limiting rubber pad (112) is positioned on a motion path of the X-collision block;
a Z-limiting rubber pad (124) is arranged on the slide carriage (12), a Z-bumping block is arranged on the slide carriage (13), and the Z-limiting rubber pad (124) is positioned on a motion path of the Z-bumping block;
the machine body (1) is provided with a Y-shaped limiting rubber pad (15), and the Y-shaped limiting rubber pad (15) is located on a motion path of the workbench (2).
6. The high-precision numerical control machine tool for the linear motor according to claim 5, wherein: and two opposite sides of the Y-axis magnetic plate (14) are provided with dustproof sealing strips (16).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202123258228.5U CN216781140U (en) | 2021-12-22 | 2021-12-22 | High-precision linear motor numerical control machine tool |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202123258228.5U CN216781140U (en) | 2021-12-22 | 2021-12-22 | High-precision linear motor numerical control machine tool |
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CN216781140U true CN216781140U (en) | 2022-06-21 |
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CN202123258228.5U Active CN216781140U (en) | 2021-12-22 | 2021-12-22 | High-precision linear motor numerical control machine tool |
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CN (1) | CN216781140U (en) |
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2021
- 2021-12-22 CN CN202123258228.5U patent/CN216781140U/en active Active
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