CN210498825U - Novel frame construction's laser engraving machine - Google Patents
Novel frame construction's laser engraving machine Download PDFInfo
- Publication number
- CN210498825U CN210498825U CN201921556281.3U CN201921556281U CN210498825U CN 210498825 U CN210498825 U CN 210498825U CN 201921556281 U CN201921556281 U CN 201921556281U CN 210498825 U CN210498825 U CN 210498825U
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- guide rail
- synchronous belt
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- wheel
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Abstract
The utility model discloses a novel frame construction's laser engraving machine mainly relates to the laser engraving field. Comprises an X-axis device assembly and a Y-axis device assembly; the X-axis device assembly comprises an X-axis stepping motor, an X-axis cantilever guide rail, an X-axis synchronous belt transmission device and a bracket sliding block; the Y-axis device assembly comprises a Y-axis stepping motor, a Y-axis guide rail and a Y-axis synchronous belt transmission device. The beneficial effects of the utility model reside in that: adopt open one-armed structure, removed the unstability of frame from, can make printing precision and stability higher.
Description
Technical Field
The utility model relates to a laser engraving field specifically is a novel frame construction's laser engraving machine.
Background
The laser engraving machine controls the movement of a mechanical structure to drive a laser to move, so that the laser prints a specific pattern on the surface of an object. The existing engraving machine adopts a frame type structure, so that the machine is complex to mount, errors are easy to occur in structural mounting, the engraving precision is not very high, and the engraved patterns are large in errors and are not clear in bending.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a novel frame construction's laser engraving machine, it adopts open one-armed structure, has removed the unstability of frame from, can make printing precision and stability higher.
The utility model discloses a realize above-mentioned purpose, realize through following technical scheme:
a laser engraving machine with a novel frame structure comprises an X-axis device assembly and a Y-axis device assembly;
x axle device assembly:
the X-axis device assembly comprises an X-axis stepping motor, an X-axis cantilever guide rail, an X-axis synchronous belt transmission device and a bracket sliding block; the X-axis stepping motor is in transmission connection with an X-axis synchronous belt transmission device, the support sliding block is connected to an X-axis cantilever guide rail in a sliding manner, the support sliding block is connected to an X-axis synchronous belt body of the X-axis synchronous belt transmission device, the movement of the X-axis synchronous belt body drives the movement of the support sliding block, and a laser is arranged on the support sliding block;
the X-axis stepping motor, the X-axis cantilever guide rail and the X-axis synchronous belt transmission device are all arranged on the acrylic plate; an X-axis synchronous wheel of the X-axis synchronous belt transmission device is arranged on the acrylic plate on one side, and an X-axis driven wheel of the X-axis synchronous belt transmission device is arranged on the acrylic plate on the other side;
y axle device assembly:
the Y-axis device assembly comprises a Y-axis stepping motor, a Y-axis guide rail and a Y-axis synchronous belt transmission device; the Y-axis synchronous belt transmission device comprises a Y-axis synchronous wheel, a Y-axis guide wheel and Y-axis synchronous belt bodies, wherein two ends of the Y-axis synchronous belt bodies are fixedly arranged on two sides of the Y-axis guide rail; when the Y axis moves, the Y axis synchronous belt body does not move, the Y axis synchronous wheel moves on the Y axis synchronous belt body, so that the Y axis stepping motor is driven to move, the Y axis overall motion is driven, meanwhile, the Y axis guide wheel close to one side of the Y axis synchronous wheel rolls on the Y axis synchronous belt body, and the Y axis guide wheel far away from one side of the Y axis synchronous wheel rolls on the Y axis guide rail.
The top of the bracket sliding block is provided with an X-axis guide wheel, and the X-axis guide wheel rolls along the top of the X-axis cantilever guide rail, so that the laser can stably move along the X-axis cantilever guide rail.
And V-shaped grooves are formed in the Y-axis guide rail and the X-axis cantilever guide rail and are matched with the X-axis guide wheel and the Y-axis guide wheel.
The X-axis cantilever guide rail and the Y-axis guide rail are made of 2020 aluminum profiles.
Contrast prior art, the beneficial effects of the utility model reside in that:
for the X axis: the X-axis stepping motor drives the support sliding block through the X-axis synchronous belt body, the laser is arranged on the support sliding block to move, and only one single arm is an X-axis cantilever guide rail;
for the Y axis: two ends of a Y-axis synchronous belt body are fixedly arranged on two sides of the Y-axis guide rail, the Y-axis synchronous belt body does not move when the Y-axis moves, and a Y-axis synchronous wheel moves on the Y-axis synchronous belt body so as to drive a Y-axis stepping motor to move and drive the Y-axis to move integrally;
through above-mentioned open single armed structure, removed the unstability of frame from, moreover through setting up X axle leading wheel, Y axle leading wheel, all set up the V-arrangement groove with leading wheel looks adaptation on Y axle guide rail, the X axle cantilever guide rail, can make printing precision and stability higher.
Drawings
Fig. 1 is a schematic structural diagram of the present invention.
Fig. 2 is a schematic structural diagram and a partial enlarged view of the present invention.
Fig. 3 is a side view of the present invention.
Fig. 4 is a side view of the present invention.
Fig. 5 is a top view of the present invention.
Reference numerals shown in the drawings:
1. an X-axis stepping motor; 2. an X-axis cantilever guide; 3. an X-axis synchronous belt transmission device; 4. a bracket slider; 5. an X-axis synchronous belt body; 6. a laser; 7. acrylic plates; 8. an X-axis synchronizing wheel; 9. an X-axis driven wheel; 10. a Y-axis stepper motor; 11. a Y-axis guide rail; 12. a Y-axis synchronous belt transmission device; 13. a Y-axis synchronizing wheel; 14. a Y-axis guide wheel; 15. a Y-axis synchronous belt body; 16. an X-axis guide wheel; 17. and a V-shaped groove.
Detailed Description
The present invention will be further described with reference to the following specific examples. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Furthermore, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teachings of the present invention, and these equivalents also fall within the scope defined in the present application.
The utility model relates to a laser engraving machine with a novel frame structure, the main structure of which comprises an X-axis device assembly and a Y-axis device assembly;
x axle device assembly:
the X-axis device assembly comprises an X-axis stepping motor 1, an X-axis cantilever guide rail 2, an X-axis synchronous belt transmission device 3 and a support sliding block 4; the X-axis cantilever guide rail 2 is made of 2020 aluminum profile. The X-axis stepping motor 1 is in transmission connection with an X-axis synchronous belt transmission device 3, the support sliding block 4 is connected to the X-axis cantilever guide rail 2 in a sliding mode, the support sliding block 4 is connected to an X-axis synchronous belt body 5 of the X-axis synchronous belt transmission device 3, the support sliding block 4 is driven to move by the movement of the X-axis synchronous belt body 5, and a laser 6 is arranged on the support sliding block 4;
the X-axis stepping motor 1, the X-axis cantilever guide rail 2 and the X-axis synchronous belt transmission device 3 are all arranged on the acrylic plate 7; an X-axis synchronous wheel 8 of the X-axis synchronous belt transmission device 3 is arranged on the acrylic plate 7 on one side, and an X-axis driven wheel 9 of the X-axis synchronous belt transmission device 3 is arranged on the acrylic plate 7 on the other side;
an X-axis guide wheel 16 is arranged at the top of the bracket sliding block 4, and the X-axis guide wheel 16 rolls along the top of the X-axis suspension arm guide rail 2, so that the laser 6 can stably move along the X-axis suspension arm guide rail 2.
Y axle device assembly:
the Y-axis device assembly comprises a Y-axis stepping motor 10, a Y-axis guide rail 11 and a Y-axis synchronous belt transmission device 12; the Y-axis synchronous belt transmission device 12 comprises a Y-axis synchronous wheel 13, a Y-axis guide wheel 14 and Y-axis synchronous belt bodies 15, wherein two ends of each Y-axis synchronous belt body are fixedly arranged on two sides of the Y-axis guide rail 11; when the Y axis moves, the Y axis synchronous belt body 15 does not move, the Y axis synchronous wheel 13 moves on the Y axis synchronous belt body 15, so that the Y axis stepping motor 10 is driven to move, the Y axis overall motion is driven, meanwhile, the Y axis guide wheel 14 close to one side of the Y axis synchronous wheel 13 rolls on the Y axis synchronous belt body 15, and the Y axis guide wheel 14 far away from one side of the Y axis synchronous wheel 13 rolls on the Y axis guide rail 11.
The Y-axis guide rail 11 and the X-axis cantilever guide rail 2 are both provided with V-shaped grooves 17, and the V-shaped grooves 17 are matched with the X-axis guide wheels 16 and the Y-axis guide wheels 14.
In this design, Y axle step motor 10 and inferior gram force board 7 adopt the structure of lying, and Y axle step motor 10 is respectively installed to both sides, forms the motion of Y axle direction, and Y axle motion is level and smooth stable, and the laser instrument 6 operation of operation on the X axle can not produce the shake for the pattern that the carving was carved out is more perfect. Through setting up X axle leading wheel 16, Y axle leading wheel 14, all set up the V-arrangement groove 17 with leading wheel looks adaptation on Y axle guide rail 11, the X axle cantilever guide rail 2, the cooperation can make printing precision and stability higher more fit. Wherein the leading wheel is made for duplex bearing + plastic casing, combines stably with the metal, and the noise is little. Moreover, the structure is convenient to install and simple and stable in structure.
For the X axis: the X-axis stepping motor 1 drives the support sliding block 4 through the X-axis synchronous belt body 5, the laser 6 is arranged on the support sliding block 4 to move, and only the X-axis cantilever guide rail 2 is an 'single arm'; for the Y axis: two ends of a Y-axis synchronous belt body 15 are fixedly arranged at two sides of the Y-axis guide rail 11, the Y-axis synchronous belt body 15 does not move when the Y-axis moves, and a Y-axis synchronous wheel 13 moves on the Y-axis synchronous belt body 15 so as to drive a Y-axis stepping motor 10 to move and drive the Y-axis to move integrally; through above-mentioned open single armed structure, the unstability of frame has been removed from, moreover through setting up X axle leading wheel 16, Y axle leading wheel 14, all set up the V-arrangement groove 17 with leading wheel looks adaptation on Y axle guide rail 11, the X axle cantilever guide rail 2, can make printing precision and stability higher. The X-axis device assembly and the Y-axis device assembly can be independently assembled and separately transported.
Claims (4)
1. A laser engraving machine with a novel frame structure comprises an X-axis device assembly and a Y-axis device assembly; the method is characterized in that:
x axle device assembly:
the X-axis device assembly comprises an X-axis stepping motor (1), an X-axis cantilever guide rail (2), an X-axis synchronous belt transmission device (3) and a support sliding block (4); the X-axis stepping motor (1) is in transmission connection with an X-axis synchronous belt transmission device (3), the support sliding block (4) is connected to the X-axis cantilever guide rail (2) in a sliding mode, the support sliding block (4) is connected to an X-axis synchronous belt body (5) of the X-axis synchronous belt transmission device (3), the support sliding block (4) is driven to move by the movement of the X-axis synchronous belt body (5), and a laser (6) is arranged on the support sliding block (4);
the X-axis stepping motor (1), the X-axis cantilever guide rail (2) and the X-axis synchronous belt transmission device (3) are all arranged on the acrylic plate (7); an X-axis synchronous wheel (8) of the X-axis synchronous belt transmission device (3) is arranged on the acrylic plate (7) on one side, and an X-axis driven wheel (9) of the X-axis synchronous belt transmission device (3) is arranged on the acrylic plate (7) on the other side;
y axle device assembly:
the Y-axis device assembly comprises a Y-axis stepping motor (10), a Y-axis guide rail (11) and a Y-axis synchronous belt transmission device (12); the Y-axis synchronous belt transmission device (12) comprises a Y-axis synchronous wheel (13), a Y-axis guide wheel (14) and Y-axis synchronous belt bodies (15) of which two ends are fixedly arranged on two sides of the Y-axis guide rail (11); y axle hold-in range area body (15) do not move during Y axle motion, and Y axle synchronizing wheel (13) move on Y axle hold-in range area body (15), thereby drive Y axle step motor (10) motion, thereby drive Y axle bulk motion, and Y axle leading wheel (14) that are close to Y axle synchronizing wheel (13) one side simultaneously roll on Y axle hold-in range area body (15), and Y axle leading wheel (14) of keeping away from Y axle synchronizing wheel (13) one side roll on Y axle guide rail (11).
2. The novel frame structured laser engraving machine of claim 1, wherein: the top of the support sliding block (4) is provided with an X-axis guide wheel (16), and the X-axis guide wheel (16) rolls along the top of the X-axis cantilever guide rail (2), so that the laser (6) can stably move along the X-axis cantilever guide rail (2).
3. The laser engraving machine of the novel frame structure of claim 2, wherein: and V-shaped grooves (17) are formed in the Y-axis guide rail (11) and the X-axis cantilever guide rail (2), and the V-shaped grooves (17) are matched with the X-axis guide wheel (16) and the Y-axis guide wheel (14).
4. The novel frame structured laser engraving machine of claim 1, wherein: the X-axis cantilever guide rail (2) and the Y-axis guide rail (11) are made of 2020 aluminum profiles.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201921556281.3U CN210498825U (en) | 2019-09-17 | 2019-09-17 | Novel frame construction's laser engraving machine |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201921556281.3U CN210498825U (en) | 2019-09-17 | 2019-09-17 | Novel frame construction's laser engraving machine |
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CN210498825U true CN210498825U (en) | 2020-05-12 |
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CN201921556281.3U Expired - Fee Related CN210498825U (en) | 2019-09-17 | 2019-09-17 | Novel frame construction's laser engraving machine |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2021232441A1 (en) * | 2020-05-22 | 2021-11-25 | 叶生山 | Laser engraving machine |
-
2019
- 2019-09-17 CN CN201921556281.3U patent/CN210498825U/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2021232441A1 (en) * | 2020-05-22 | 2021-11-25 | 叶生山 | Laser engraving machine |
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GR01 | Patent grant | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20200512 Termination date: 20210917 |
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CF01 | Termination of patent right due to non-payment of annual fee |