CN210254719U - Open type optical fiber laser deep carving machine - Google Patents

Abstract

The utility model discloses an open optic fibre laser deep carving machine, including rack, electric cabinet and display operation panel, the rack includes the workstation and is located four protection lateral walls on the workstation, and electric cabinet and display operation panel establish on protecting the lateral wall, are provided with six robots and pay-off moving platform on the workstation, and pay-off moving platform will treat the work piece of processing and send into to the rack in or send out outside the rack, and six robots are connected with the optic fibre laser deep carving device, display operation panel, six robots, pay-off moving platform, the electric cabinet is connected respectively to the optic fibre laser deep carving device. The utility model adopts the optical fiber laser beam mode to realize the marking and engraving of the product, and therefore, the cutter abrasion and replacement do not exist, and the surface of the processed product has no cutter mark; and secondly, the optical fiber laser processing has high precision and can process any shape and figure. In addition, the six-axis robot is used as a motion driving mechanism, the processing freedom degree is high, the positioning of accurate positions can be realized, and the processing speed is high and the processing efficiency is high.

Description

Open type optical fiber laser deep carving machine

Technical Field

The utility model relates to a laser beam machining equipment technical field, concretely relates to is an open optic fibre laser deep carving machine.

Background

At present, the deep carving machines in the market mostly adopt mechanical contact type processing, and the principle is that a high-speed motor is adopted to drive a carving cutter, and products are processed on an XY moving platform. However, in this conventional machining method, the tool is easily worn or broken, and is a consumable product; the cutter is adopted to process on the surface of a product, the surface of the product has processing traces (tool marks), and after the processing is finished, the product needs to be subjected to surface treatment. Thus, the tool machining accuracy depends on the wear of the XY moving table and the tool, which causes problems such as low product yield, high cost, and low yield. Meanwhile, the tool is repaired or replaced every time, and the XY moving stage is maintained to ensure the machining accuracy. Every time the XY moving platform is maintained and the cutter is replaced, certain influence is caused on the bed structure, and the precision of the bed structure is deteriorated over time, so that the machining precision of a product cannot meet the requirement of a client, and the economic loss is caused to the client.

Therefore, a device with high processing efficiency, low cost, high precision and no tool mark is required.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an utilize six axis robot driven open optic fibre laser deep carving machines, carry out the repeatability through the laser beam to product surface material and beat the mark, make the pattern on material surface shaping gradually to solve above-mentioned cutter processing product with low costs, machining efficiency is low, the machining precision is low, the product surface has the technical problem of tool mark.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an open optic fibre laser deep carving machine, includes rack, electric cabinet and display operation panel, the rack includes the workstation and is located four protection lateral walls on the workstation, the electric cabinet with the display operation panel is established on the protection lateral wall, be provided with six robots and pay-off moving platform on the workstation, pay-off moving platform will treat the work piece of processing send into extremely in the rack or send out extremely outside the rack, six robots are connected with the optic fibre laser deep carving device, the display operation panel the six robots pay-off moving platform the optic fibre laser deep carving device is connected respectively the electric cabinet.

Further, the deep carving device of optical fiber laser includes fixing base and fiber laser, fiber laser includes laser generator, laser output head and optic fibre, laser generator sets up on the workstation, laser output head sets up on the fixing base, the both ends of optic fibre are connected respectively laser generator with laser output head. The fiber laser is arranged on the fixing seat, so that the six-axis robot can accurately control and drive the fiber laser to move to the specified position to mark and carve the surface of a product. The laser generator is used for generating a laser beam with certain energy; the laser output head is used for outputting laser beams and marking and carving the surface of a product; the optical fiber is used as a guided wave medium, has excellent flexibility and is used for connecting a laser generator and a laser output head, so that the formed optical fiber laser has the characteristics of high conversion efficiency, high gain, good output beam quality and flexible product processing.

Preferably, the fiber laser deep carving device further comprises a red light auxiliary positioner and a CCD positioning device, wherein the red light auxiliary positioner is arranged at the lower part of the fixing seat through an angle adjusting component, and the CCD positioning device is arranged at the upper part of the fixing seat. The red light auxiliary positioner is used for generating red light to preliminarily position the laser marking carved pattern; the angle adjusting component is used for adjusting the installation angle of the red light auxiliary positioner; the CCD positioning device is used for detecting the primary positioning position so as to ensure the relative position of the laser processing pattern and the processing contour.

Preferably, the upper surface of the fixed seat is provided with a CCD fine adjustment mechanism, and the CCD positioning device is installed on the CCD fine adjustment mechanism in a matching manner. The CCD fine adjustment mechanism is used for fine adjusting the position of the CCD positioning device, so that the CCD positioning device can be accurately positioned.

Specifically, the angle adjustment subassembly includes the mounting and rotates the piece, the one end setting of mounting is in the lateral wall of fixing base, it includes U-shaped locking end and rotatory end to rotate the piece, rotatory end is articulated to be connected the other end of mounting, U-shaped locking end installation ruddiness assistance-localization real-time ware. The red light auxiliary positioner is locked and fixed by utilizing the U-shaped locking end of the rotating part, and the angle of the rotating end is adjusted to further adjust the optimal position of the red light auxiliary positioner.

Preferably, the deep carving device of optic fibre laser still includes laser range finder and Z axle lift module, the laser range finder passes through the support mounting and is in the upper surface of fixing base, the one end of Z axle lift module is connected the lateral wall of fixing base, the other end of Z axle lift module is connected six robots. Laser range finder is used for detecting the position height that the product needs processing, and Z axle lift module is used for adjusting the difference in height of optic fibre laser deep carving device according to the height that laser range finder provided.

Preferably, the fixing seat is provided with a dust removing device, and the dust removing device comprises an air outlet assembly for blowing dust on the surface of the workpiece and a dust collecting assembly for adsorbing and collecting the dust. When the laser beam machining product, some dust can remain on the product surface, utilize dust clearing device, in time clear away the dust on product surface, play the effect on protection product surface.

Specifically, the air outlet assembly comprises a dust blowing air knife and a dust blowing cylinder, a first air outlet is formed in one end of the dust blowing cylinder, a second air outlet is formed in one end of the dust blowing air knife, and air outlet pipelines are connected to the other end of the dust blowing air knife and the other end of the dust blowing cylinder; the dust collection assembly comprises a dust collection flat nozzle, one end of the dust collection flat nozzle is provided with a dust collection port, the other end of the dust collection flat nozzle is connected with a dust collection pipeline, and the second air outlet and the dust collection port are distributed in a manner of facing. The dust blowing cylinder is used for blowing dust on the surface of a product, and the dust blowing air knife is used for blowing the blown dust to the dust suction port of the dust suction flat nozzle, so that the dust is sucked away by the dust suction port, and the surface of the product is protected.

Furthermore, a movable door which is convenient for putting the workpiece into the feeding moving platform is arranged on the protective side wall. Through opening the dodge gate, be convenient for the workman manually place the product at pay-off moving platform, or take out the product that has processed.

Or, a workpiece placing opening is formed in the protective side wall, and a grabbing mechanism for automatically feeding or discharging workpieces is further arranged on the workbench. Set up open work piece and put into the mouth on the protection lateral wall, be convenient for link up with pipelining's conveyer belt. Snatch the automatic product that snatchs of mechanism through setting up, realize automatic feeding and unloading, improve machining efficiency, reduce the cost of labor.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses set up pay-off moving platform and be used for locating and pay-off and the ejection of compact the work piece of treating processing, utilize six axis robot drive optic fibre laser deep carving device motions, carry out the repeatability through the laser beam and beat the mark sculpture to the material on work piece product surface, make the pattern on material surface shaping gradually. The product marking and engraving processing is realized by adopting an optical fiber laser beam mode, so that the abrasion and the replacement of a cutter are avoided, the surface of the processed product has no cutter mark, and the subsequent surface treatment is not needed; and secondly, the optical fiber laser processing has high precision, and can process the patterns with any shapes. In addition, the six-axis robot is used as a motion driving mechanism, the processing freedom degree is large, the motion response of each joint motion mechanism is fast, and the accurate position positioning can be realized; under the automatic drive effect of six robots, different planes and curved surfaces can be processed to the dark carving device of optic fibre laser when not influencing the machining precision, and the process velocity is fast, efficient and output also improves.

Drawings

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

FIG. 2 is an enlarged view of detail A in FIG. 1;

fig. 3 is a schematic perspective view of another perspective of the present invention;

FIG. 4 is a schematic perspective view of an optical fiber laser deep engraving device;

FIG. 5 is a schematic perspective view of another optical fiber laser deep engraving device;

fig. 6 is an enlarged detail view at B in fig. 5.

Reference numerals: 1. a cabinet; 11. a work table; 12. a protective sidewall; 13. a movable door; 14. a bellows support frame; 2. an electric cabinet; 3. a display console; 4. a six-axis robot; 5. a feeding moving platform; 6. an optical fiber laser deep carving device; 61. a fixed seat; 611. a support; 62. a CCD positioning device; 63. a fiber laser; 631. a laser generator; 632. a laser output head; 633. an optical fiber; 64. a CCD fine adjustment mechanism; 65. a red light auxiliary positioner; 66. a laser range finder; 67. a Z-axis lifting module; 7. an angle adjustment assembly; 71. a fixing member; 72. a rotating member; 721. a U-shaped locking end; 722. a rotating end; 8. a dust removal device; 81. an air outlet assembly; 811. a dust blowing air knife; 812. a second air outlet; 813. an air outlet pipeline; 814. a dust blowing cylinder; 815. a first air outlet; 82. a dust collection assembly; 821. a dust absorption flat nozzle; 822. a dust suction port; 823. a dust collection duct; 9. and (5) a workpiece.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the accompanying drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Referring to fig. 1 to 6, an open type optical fiber laser deep carving machine in one embodiment is shown, and includes a cabinet 1, an electric cabinet 2 and a display console 3, where the display console 3 is used for operating laser processing, and a PLC controller is built in the electric cabinet 2 to control operations of electrical devices. The cabinet 1 includes workstation 11 and four protection lateral walls 12 that are located on workstation 11, electric cabinet 2 with display operation panel 3 establishes on the protection lateral wall 12, be provided with six robots 4 and pay-off moving platform 5 on the workstation 11, be equipped with on the protection lateral wall 12 and be convenient for the workman to put into work piece 9 extremely dodge gate 13 on the pay-off moving platform 5. By opening the movable door 13, a worker can easily manually place the workpiece 9 on the feeding moving platform 5 and fix it in place, or remove the machined workpiece 9 from the feeding moving platform 5. By the forward or backward movement of the feeding moving platform 5, the workpiece 9 to be processed can be fed into the cabinet 1 or discharged out of the cabinet 1. Six robots 4 are connected with optic fibre laser deep carving device 6, optic fibre laser deep carving device 6 includes fixing base 61 and optic fibre laser 63, optic fibre laser 63 includes laser generator 631, laser output head 632 and optic fibre 633, laser generator 631 sets up on the workstation 11, laser output head 632 sets up on the fixing base 61, the both ends of optic fibre 633 are connected respectively laser generator 631 with laser output head 632. The display operation table 3, the six-axis robot 4, the feeding moving platform 5 and the optical fiber laser deep carving device 6 are respectively connected with the electric cabinet 2. Through setting fiber laser 63 on fixing base 61 to six axis robot 4 can control accurately that drive fiber laser 63 removes to the assigned position and beats mark sculpture operation to the product surface of work piece 9, and the product surface of processing does not have the tool mark, need not follow-up surface treatment. The laser generator 631 is used to generate a laser beam having a certain energy; the laser output head 632 is used for outputting laser beams and marking and carving the surface of a product; the optical fiber 633 is used as a guided wave medium, has excellent flexibility and is used for connecting a laser generator and a laser output head, so that the formed optical fiber laser has the characteristics of high conversion efficiency, high gain, good output beam quality and flexible product processing.

Referring to fig. 4 and 5, a dust removing device 8 is arranged on the fixing base 61, and the dust removing device 8 includes an air outlet component 81 for blowing up dust on the surface of the workpiece 9 and a dust suction component 82 for adsorbing and collecting the dust. When the laser beam machining product, some dust can remain on the product surface, utilize dust clearing device, in time clear away the dust on product surface, play the effect on protection product surface.

Specifically, the air outlet assembly 81 comprises a dust blowing air knife 811 and a dust blowing cylinder 814, one end of the dust blowing cylinder 814 is provided with a first air outlet 815, one end of the dust blowing air knife 811 is provided with a second air outlet 812, and the other end of the dust blowing air knife 811 and the other end of the dust blowing cylinder 814 are connected with an air outlet pipeline 813; the dust collection assembly 82 comprises a dust collection flat nozzle 821, one end of the dust collection flat nozzle 821 is provided with a dust collection port 822, the other end of the dust collection flat nozzle 821 is connected with a dust collection pipeline 823, and the second air outlet 812 is opposite to the dust collection port 822. The dust blowing cylinder is used for blowing dust on the surface of a product, and the dust blowing air knife is used for blowing the blown dust to the dust suction port of the dust suction flat nozzle, so that the dust is sucked away by the dust suction port, and the surface of the product is protected. In order to achieve the best dust removing and workpiece surface protecting effects, the air outlet directions of the first air outlet and the second air outlet are vertically distributed.

In a preferred embodiment, the fiber laser deep engraving device 6 further includes a red light auxiliary positioner 65 and a CCD positioning device 62, the red light auxiliary positioner 65 is disposed at a lower portion of the fixed base 61 through an angle adjusting assembly 7, and the CCD positioning device 62 is disposed at an upper portion of the fixed base 61. The red light auxiliary positioner 65 is used for generating red light to preliminarily position the positions of the laser marking engraving patterns; the angle adjusting component 7 is used for adjusting the installation angle of the red light auxiliary positioner 65; the CCD positioning device 62 is used to detect the position of the preliminary positioning to ensure the relative position of the laser processing pattern and the processing profile, and specifically, a CCD camera may be used as the CCD positioning device.

Referring to fig. 6, the angle adjusting assembly 7 includes a fixed member 71 and a rotating member 72, one end of the fixed member 71 is disposed on the side wall of the fixed base 61, the rotating member 72 includes a U-shaped locking end 721 and a rotating end 722, the rotating end 722 is hinged to the other end of the fixed member 71, and the U-shaped locking end 721 mounts the red light auxiliary locator 65. The red light auxiliary positioner is locked and fixed by utilizing the U-shaped locking end of the rotating part to be matched with a fastening piece such as a bolt, and the angle of the rotating end is adjusted to further adjust the optimal position of the red light auxiliary positioner.

Further preferably, a CCD fine-tuning mechanism 64 is disposed on the upper surface of the fixing base 61, and the CCD positioning device 62 is mounted on the CCD fine-tuning mechanism 64 in a matching manner. The CCD fine adjustment mechanism 64 is used for fine adjustment of the position of the CCD positioning device 62 so that the CCD positioning device can be accurately positioned. Specifically, the CCD fine adjustment mechanism may be a lifting mechanism composed of a stepping motor, a screw, a lifting frame, and the like, and realizes position adjustment including but not limited to the height direction of the CCD positioning device.

In other embodiments, the fiber laser deep engraving device 6 further includes a laser range finder 66 and a Z-axis lifting module 67, the laser range finder 66 is mounted on the upper surface of the fixing base 61 through a bracket 611, one end of the Z-axis lifting module 67 is connected to the side wall of the fixing base 61, and the other end of the Z-axis lifting module 67 is connected to the six-axis robot 4. Laser range finder 66 is used for detecting the position height that work piece 9 needs to process, and Z axle lift module 67 is used for adjusting the difference in height of optic fibre laser deep carving device 6 according to the height that laser range finder 66 provided, and its structure only need can realize controllable lift can. For example, Z axle lift module's structure can be by step motor, gear, the mount pad of taking the rack structure, the lift subassembly that the motor mounting bracket constitutes jointly, through connecting fixing base with motor mounting bracket one side, connects six robots with one side of the mount pad of taking the rack structure, utilizes step motor drive gear to realize adjusting the difference in height of optic fibre laser deep carving device along rack structure removal.

In order to prevent interference with the movement of the six-axis robot, the corrugated pipe is used for collecting and accommodating cables such as optical fibers, data lines and power lines of the CCD positioning device, a dust suction pipeline and an air outlet pipeline, and a corrugated pipe supporting frame 14 is installed on the anti-skid side wall 12 for fixing.

Of course, except adopting artifical manual material loading and unloading mode, the utility model discloses can also combine the pipelining in above-mentioned various embodiments be equipped with open work piece entrance to putting on the protection lateral wall 12, link up with pipelining's conveyer belt, simultaneously still be equipped with on the workstation 11 and snatch the mechanism to 9 automatic feeding of work piece or unloading. Snatch the automatic product that snatchs of mechanism through setting up, realize automatic feeding and unloading, improve machining efficiency, reduce the cost of labor. The specific structure of the grabbing mechanism can be a pneumatic sucking disc or a mechanical arm grabbing mechanism, and workpieces can be automatically grabbed, loaded and unloaded.

The utility model discloses in an open optical fiber laser deep carving machine's description of work does: after a worker places a workpiece 9 on the feeding moving platform 5 for positioning, the feeding moving platform 5 moves the workpiece 9 to a specified position through operation on the display operation table 3, and the optical fiber laser deep engraving device 6 fixed on the six-axis robot 4 performs laser processing according to a set processing program. In the processing process, the movement of the fiber laser deep carving device 6 is driven by the six-axis robot 4. Initially, the laser range finder 66 on the fixing base 61 detects the height of the position to be processed of the workpiece 9, and the Z-axis lifting module 67 adjusts the height difference of the optical fiber laser deep-carving device 6 according to the height provided by the laser range finder 66. Then, the red light auxiliary positioner 65 emits red light to perform primary positioning, and the CCD positioning device 62 detects the position of the primary positioning, and emits a laser beam from the laser output head 632 to perform marking and engraving at the corresponding position after precise positioning. When a workpiece product is processed by laser, some dust can remain on the surface of the product, the dust blowing cylinder 814 blows the dust on the surface of the product, the dust blowing air knife 811 blows the blown dust to the flat dust suction nozzle 821, and the dust is sucked away by the dust suction port 822 of the flat dust suction nozzle 821, so that the surface of the workpiece product is protected. After the processing is finished, the workpiece 9 is sent out by the feeding moving platform 5, and then the workpiece is manually taken out for blanking.

The utility model has the advantages that: the utility model discloses set up pay-off moving platform and be used for locating and pay-off and the ejection of compact the work piece of treating processing, utilize six axis robot drive optic fibre laser deep carving device motions, carry out the repeatability through the laser beam and beat the mark sculpture to the material on work piece product surface, make the pattern on material surface shaping gradually. The product marking and engraving processing is realized by adopting an optical fiber laser beam mode, so that the abrasion and the replacement of a cutter are avoided, the surface of the processed product has no cutter mark, and the subsequent surface treatment is not needed; and secondly, the optical fiber laser processing has high precision, and can process the patterns with any shapes. In addition, the six-axis robot is used as a motion driving mechanism, the processing freedom degree is large, the motion response of each joint motion mechanism is fast, and the accurate position positioning can be realized; under the automatic drive effect of six robots, different planes and curved surfaces can be processed to the dark carving device of optic fibre laser when not influencing the machining precision, and the process velocity is fast, efficient and output also improves.

While the preferred embodiments of the present invention have been described, the present invention is not limited to the above embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are intended to be included within the scope of the present invention as defined by the appended claims.

Claims (10)

1. The utility model provides an open optic fibre laser deep carving machine, includes rack, electric cabinet and display operation panel, the rack includes the workstation and is located four protection lateral walls on the workstation, the electric cabinet with the display operation panel is established on the protection lateral wall, its characterized in that: the automatic processing machine is characterized in that a six-axis robot and a feeding moving platform are arranged on the workbench, a workpiece to be processed is sent into the cabinet or sent out of the cabinet by the feeding moving platform, the six-axis robot is connected with an optical fiber laser deep carving device, and the display operation table, the six-axis robot, the feeding moving platform and the optical fiber laser deep carving device are respectively connected with the electric cabinet.

2. The open type optical fiber laser deep carving machine as claimed in claim 1, characterized in that: the optical fiber laser deep carving device comprises a fixing seat and an optical fiber laser, the optical fiber laser comprises a laser generator, a laser output head and an optical fiber, the laser generator is arranged on the workbench, the laser output head is arranged on the fixing seat, and two ends of the optical fiber are respectively connected with the laser generator and the laser output head.

3. The open type optical fiber laser deep carving machine as claimed in claim 2, characterized in that: the optical fiber laser deep carving device further comprises a red light auxiliary positioner and a CCD positioning device, wherein the red light auxiliary positioner is arranged on the lower portion of the fixing seat through an angle adjusting assembly, and the CCD positioning device is arranged on the upper portion of the fixing seat.

4. The open type optical fiber laser deep carving machine as claimed in claim 3, characterized in that: the upper surface of the fixing seat is provided with a CCD fine adjustment mechanism, and the CCD positioning device is installed on the CCD fine adjustment mechanism in a matching mode.

5. The open type optical fiber laser deep carving machine as claimed in claim 3, characterized in that: the angle adjusting assembly comprises a fixing piece and a rotating piece, one end of the fixing piece is arranged on the side wall of the fixing base, the rotating piece comprises a U-shaped locking end and a rotating end, the rotating end is hinged to the other end of the fixing piece, and the U-shaped locking end is installed on the red light auxiliary positioner.

6. The open type optical fiber laser deep carving machine as claimed in claim 2, characterized in that: the optical fiber laser deep carving device further comprises a laser range finder and a Z-axis lifting module, the laser range finder is installed on the upper surface of the fixing base through a support, one end of the Z-axis lifting module is connected with the side wall of the fixing base, and the other end of the Z-axis lifting module is connected with the six-axis robot.

7. The open type optical fiber laser deep engraving machine of any one of claims 2 to 6, wherein: the dust removing device is arranged on the fixing seat and comprises an air outlet assembly for blowing dust on the surface of the workpiece and a dust suction assembly for adsorbing and collecting the dust.

8. The open type optical fiber laser deep carving machine as claimed in claim 7, characterized in that: the air outlet assembly comprises a dust blowing air knife and a dust blowing air cylinder, a first air outlet is formed in one end of the dust blowing air cylinder, a second air outlet is formed in one end of the dust blowing air knife, and air outlet pipelines are connected to the other end of the dust blowing air knife and the other end of the dust blowing air cylinder; the dust collection assembly comprises a dust collection flat nozzle, one end of the dust collection flat nozzle is provided with a dust collection port, the other end of the dust collection flat nozzle is connected with a dust collection pipeline, and the second air outlet and the dust collection port are distributed in a manner of facing.

9. The open type optical fiber laser deep carving machine as claimed in claim 8, characterized in that: the protective side wall is provided with a movable door which is convenient for putting the workpiece into the feeding moving platform.

10. The open type optical fiber laser deep carving machine as claimed in claim 8, characterized in that: the protective side wall is provided with a workpiece placing opening, and the workbench is also provided with a grabbing mechanism for automatically feeding or discharging workpieces.

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