CN210188826U

CN210188826U - High-precision small laser engraving machine

Info

Publication number: CN210188826U
Application number: CN201921236237.4U
Authority: CN
Inventors: Yifeng Miao; 缪逸峰
Original assignee: Ma'anshan Pearl Electronic Technology Co Ltd
Current assignee: Ma'anshan Pearl Electronic Technology Co Ltd
Priority date: 2019-08-01
Filing date: 2019-08-01
Publication date: 2020-03-27
Anticipated expiration: 2029-08-01

Abstract

The utility model discloses a small-size laser engraving machine of high accuracy, including workstation, Y to displacement subassembly, X to displacement subassembly, base, Z to displacement subassembly, through treating machined part fixed mounting back on the workstation, drive the screw rod through step motor and rotate to make the laser instrument at X, Y, Z triaxial direction motion, adjust the laser instrument of laser engraving machine and the relative position of treating the machined part, make this laser engraving machine's location more accurate. Meanwhile, by adopting a simple and efficient mechanical structure design, the device occupies a small space, is suitable for processing small-sized products, is simple to operate, and has high processing precision and high processing speed.

Description

High-precision small laser engraving machine

Technical Field

The utility model belongs to the laser engraving field specifically is a small-size laser engraving machine of high accuracy.

Background

With the innovation and rapid development of electronic technology, the application of laser engraving technology as a typical optical, mechanical and electrical integrated machining is more and more extensive, and the demand of many industries, especially the workpiece machining industry, on laser engraving machines is more essential. Although laser engraving machines are widely applied to the die industry, the advertising industry and other industries needing to process fine and complex parts, the existing laser engraving machines in the market are large in size and high in price and cannot meet the requirements of small and medium workshops and households, the low-price and small laser engraving machines do not have products corresponding to the laser engraving machines in the existing market, and the laser engraving machines handed to large laser engraving manufacturers are high in cost and time-consuming and bring inconvenience to numerous middle and small industry practitioners.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a small-size laser engraving machine of high accuracy to solve the technical problem who proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a high-precision small-sized laser engraving machine comprises a workbench, a Y-direction displacement assembly, an X-direction displacement assembly, a base and a Z-direction displacement assembly, wherein the Y-direction displacement assembly comprises a first stepping motor arranged on the side surface of the base, the output end of the first stepping motor is connected with a first screw rod, the other end of the first screw rod is connected onto the base through a first flange, a first nut matched with the first screw rod for transmission is arranged on the first screw rod, the first nut is fixedly connected onto a supporting plate through a bolt, the supporting plate is fixedly connected onto a first sliding block through a bolt, the first sliding block is arranged on a first linear guide rail, and the first linear guide rail is fixedly connected onto a side plate on the base through a bolt; supporting plates are welded at two end parts of the supporting plate and fixedly connected with a first mounting plate through bolts;

the X-direction displacement assembly comprises a second stepping motor, the second stepping motor is fixedly connected to the left supporting plate through bolts, the output end of the second stepping motor is connected with a second screw rod, the other end of the second screw rod is connected to the right supporting plate through a second flange, the second screw rod is connected with a second screw rod which is in matched transmission with the second screw rod, the second screw rod is fixedly connected to a sliding block supporting plate, the sliding block supporting plate is fixedly connected to a second sliding block through bolts, and the second sliding block is arranged on a second linear guide rail; the second linear guide rail is fixedly connected to the first mounting plate through a bolt, the slider supporting plate is fixedly connected to the second mounting plate through a bolt, the upper end of the second mounting plate is in threaded connection with the motor mounting plate, and the lower end of the second mounting plate is provided with a limiting plate;

the Z-direction displacement assembly comprises a third stepping motor installed on a motor installation plate, the output end of the third stepping motor is connected with a third screw, one end, close to the third stepping motor, of the third screw is provided with a first screw fixing seat, the other end of the third screw is provided with a second screw fixing seat, the first screw fixing seat and the second screw fixing seat are fixedly connected onto a second installation plate through bolts, a third nut matched with and driven by the third screw is arranged on the third screw, the third nut is fixedly connected onto a laser supporting plate through bolts, the laser supporting plate is installed on a third sliding block, the third sliding block is slidably connected onto a third linear guide rail, the third linear guide rail is fixedly connected onto the second installation plate through bolts, and a laser is fixedly connected onto the laser supporting plate through threads.

Preferably, be close to screw rod fixing base two on the third screw rod and be equipped with the crash pad, the material of crash pad is rubber, avoids third nut and the collision of screw rod fixing base two, prolongs the life of third nut.

Preferably, the first sliding block, the second sliding block and the third sliding block are at least four, and at least four sliding blocks are adopted, so that the movement is more stable.

Compared with the prior art, the beneficial effects of the utility model are that: after the workpiece to be machined is fixedly arranged on the workbench, the screw rod is driven to rotate through the stepping motor, so that the laser moves in the direction of X, Y, Z three axes, the relative position of the laser engraving machine and the workpiece to be machined is adjusted, and the laser engraving machine is more accurate in positioning. Meanwhile, by adopting a simple and efficient mechanical structure design, the device occupies a small space, is suitable for processing small-sized products, is simple to operate, has high processing precision and high processing speed, and is favorable for popularization.

Drawings

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

fig. 2 is a bottom view of the present invention;

FIG. 3 is a schematic structural view of the X-direction displacement assembly and the Z-direction displacement assembly of the present invention;

fig. 4 is a front view of the X-direction displacement assembly and the Z-direction displacement assembly of the present invention.

In the figure:

1. a work table; 2. a Y-direction displacement assembly; 3. an X-direction displacement assembly; 4. a base; 5. a Z-direction displacement assembly;

201: a first stepper motor; 202. a support plate; 203. a first linear guide rail; 204. a support plate; 205. A first mounting plate; 206. a first nut; 207. a first screw; 208. a first flange; 209. a first slider;

301. a second stepping motor; 302. a second slider; 303. a second linear guide; 304. a second nut; 305. a second screw; 306. a slider pallet; 307. a second mounting plate; 308. a second flange; 309. A limiting plate; 310. a motor mounting plate;

501. a third step motor; 502. a third slider; 503. a first screw fixing seat; 504. a laser mount; 505. a third screw; 506. a third nut; 507. an anti-collision pad; 509. a third linear guide rail; 510. a screw rod fixing seat II; 511. a laser.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a high-precision small-sized laser engraving machine comprises a workbench 100, a Y-direction displacement assembly 200, an X-direction displacement assembly 300, a base 400 and a Z-direction displacement assembly 500, wherein the Y-direction displacement assembly 200 comprises a first stepping motor 201 installed on the side surface of the base, the output end of the first stepping motor 201 is connected with a first screw 207, the other end of the first screw 207 is connected to the base 400 through a first flange 208, a first nut 206 matched with and driven by the first screw 207 is arranged on the first screw 207, the first nut 206 is fixedly connected to a supporting plate 202 through a bolt, the supporting plate 202 is fixedly connected to a first sliding block 209 through a bolt, the first sliding block 209 is arranged on a first linear guide rail 203, and the first linear guide rail 203 is fixedly connected to a side plate on the base 400 through a bolt; support plates 204 are welded at two end parts of the supporting plate 202, and the support plates 204 are fixedly connected with a first mounting plate 205 through bolts;

the X-direction displacement assembly 300 comprises a second stepping motor 301, the second stepping motor 301 is fixedly connected to the left supporting plate 204 through bolts, the output end of the second stepping motor 301 is connected with a second screw 305, the other end of the second screw 305 is connected to the right supporting plate 204 through a second flange 308, the second screw 305 is connected with a second screw 305 which is in matched transmission with the second screw 305, the second screw 305 is fixedly connected to a sliding block supporting plate 306, the sliding block supporting plate 306 is fixedly connected to a second sliding block 302 through bolts, and the second sliding block 302 is arranged on a second linear guide rail 303; the second linear guide rail 303 is fixedly connected to the first mounting plate 205 through a bolt, the slider supporting plate 306 is fixedly connected to the second mounting plate 307 through a bolt, the upper end of the second mounting plate 307 is in threaded connection with a motor mounting plate 310, and the lower end of the second mounting plate 307 is provided with a limiting plate 309;

the Z-direction displacement assembly 500 comprises a third stepping motor 501 mounted on the motor mounting plate 310, an output end of the third stepping motor 501 is connected with a third screw 505, one end of the third screw 505, which is close to the third stepping motor 501, is provided with a first screw fixing seat 503, the other end of the third screw 505 is provided with a second screw fixing seat 510, the third screw 505, which is close to the second screw fixing seat 510, is provided with a crash pad 507, and the crash pad 507 is made of rubber. The first screw fixing seat 503 and the second screw fixing seat 510 are fixedly connected to the second mounting plate 307 through bolts, a third nut 506 matched with and driven by the third screw 505 is arranged on the third screw 505, the third nut 506 is fixedly connected to the laser supporting plate 504 through bolts, the laser supporting plate 504 is installed on the third slider 502, the third slider 502 is slidably connected to a third linear guide rail 509, the third linear guide rail 509 is fixedly connected to the second mounting plate 307 through bolts, and a laser 511 is fixedly connected to the laser supporting plate 504 through threads. Four first sliders 209, four second sliders 302 and four third sliders 502 are provided.

The working principle is as follows: firstly, a workpiece to be processed is fixed on a workbench 100, a first step motor 201 is electrified, an X-direction displacement assembly 300 and a Z-direction displacement assembly 500 on a first sliding block 209 are driven to move along the Y direction through the rotation of a first screw rod 207 and a first nut 206, the Y-direction positions of a laser 511 and the workpiece to be processed are adjusted, the first step motor 201 is powered off after the Y-direction position is fixed, at the moment, a second step motor 301 is electrified, the Z-direction displacement assembly 500 is driven to move along the X direction on a second sliding block 302 along a second linear guide rail 303 through the rotation of a second screw rod 305 and a second nut 304, the X-direction positions of the laser 511 and the workpiece to be processed are adjusted, the second step motor 301 is powered off after the X-direction position is fixed, then the third step motor 501 is powered on, the laser 511 on a laser supporting plate 504 is driven to move along the Z-axis direction through the rotation of a third screw rod 505 and a third nut 506, and adjusting the Z-direction position of the laser 511 and the workpiece to be machined, powering off the third stepping motor 501 after the Z-direction position is fixed, and finally powering on the laser 511 to machine the workpiece to be machined on the workbench.

The utility model discloses a to treat machined part fixed mounting back on the workstation, drive the screw rod through step motor and rotate to make the laser instrument at X, Y, Z triaxial direction motion, adjust the laser instrument of laser engraving machine and treat the relative position of machined part, make this laser engraving machine's location more accurate. Meanwhile, by adopting a simple and efficient mechanical structure design, the device occupies a small space, is suitable for processing small-sized products, is simple to operate, has high processing precision and high processing speed, and is favorable for popularization.

It should be finally noted that the above only serves to illustrate the technical solution of the present invention, and not to limit the scope of the present invention, and that simple modifications or equivalent replacements performed by those skilled in the art to the technical solution of the present invention do not depart from the spirit and scope of the technical solution of the present invention.

Claims

1. The utility model provides a small-size laser engraving machine of high accuracy, includes workstation (100), Y to displacement subassembly (200), X to displacement subassembly (300), base (400), Z to displacement subassembly (500), its characterized in that: the Y-direction displacement assembly (200) comprises a first stepping motor (201) installed on the side face of the base, the output end of the first stepping motor (201) is connected with a first screw rod (207), the other end of the first screw rod (207) is connected to the base (400) through a first flange (208), a first nut (206) in matched transmission with the first screw rod (207) is arranged on the first screw rod (207), the first nut (206) is fixedly connected to a supporting plate (202) through a bolt, the supporting plate (202) is fixedly connected to a first sliding block (209) through a bolt, the first sliding block (209) is arranged on a first linear guide rail (203), and the first linear guide rail (203) is fixedly connected to a side plate on the base (400) through a bolt; supporting plates (204) are welded at two end parts of the supporting plate (202), and the supporting plates (204) are fixedly connected with first mounting plates (205) through bolts;

the X-direction displacement assembly (300) comprises a second stepping motor (301), the second stepping motor (301) is fixedly connected to the left supporting plate (204) through bolts, the output end of the second stepping motor (301) is connected with a second screw (305), the other end of the second screw (305) is connected to the right supporting plate (204) through a second flange (308), the second screw (305) is connected with a second screw (305) in matched transmission with the second screw (305), the second screw (305) is fixedly connected to a sliding block supporting plate (306), the sliding block supporting plate (306) is fixedly connected to a second sliding block (302) through bolts, and the second sliding block (302) is arranged on a second linear guide rail (303); the second linear guide rail (303) is fixedly connected to the first mounting plate (205) through a bolt, the slider supporting plate (306) is fixedly connected to the second mounting plate (307) through a bolt, the upper end of the second mounting plate (307) is in threaded connection with a motor mounting plate (310), and the lower end of the second mounting plate (307) is provided with a limiting plate (309);

the Z-direction displacement assembly (500) comprises a third stepping motor (501) arranged on a motor mounting plate (310), the output end of the third stepping motor (501) is connected with a third screw rod (505), one end, close to the third stepping motor (501), of the third screw rod (505) is provided with a first screw rod fixing seat (503), the other end of the third screw rod (505) is provided with a second screw rod fixing seat (510), the first screw rod fixing seat (503) and the second screw rod fixing seat (510) are fixedly connected onto a second mounting plate (307) through bolts, a third nut (506) matched with the third screw rod (505) for transmission is arranged on the third screw rod (505), the third nut (506) is fixedly connected onto a laser supporting plate (504) through bolts, the laser supporting plate (504) is arranged on a third sliding block (502), and the third sliding block (502) is slidably connected onto a third linear guide rail (509), the third linear guide rail (509) is fixedly connected to the second mounting plate (307) through bolts, and the laser supporting plate (504) is fixedly connected with a laser (511) through threads.

2. A high precision small laser engraving machine as claimed in claim 1, characterized in that: and an anti-collision pad (507) is arranged on the third screw (505) close to the second screw fixing seat (510), and the anti-collision pad (507) is made of rubber.

3. A high precision small laser engraving machine as claimed in claim 1, characterized in that: the number of the first sliding block (209), the number of the second sliding block (302) and the number of the third sliding block (502) are at least four.