CN210548866U - Experimental device integrating three laser processing technologies - Google Patents

Abstract

The utility model discloses an integrated three kinds of laser beam machining process's experimental apparatus, including ultrafast laser instrument, carbon dioxide laser instrument, be located the first group speculum on the light transmission path that the ultrafast laser instrument sent laser, be located second group speculum, XY axle motion platform and the Z axle motion platform on the light transmission path that the carbon dioxide laser instrument sent laser, be equipped with on the XY axle motion platform and be used for placing the work piece that can follow its with the motion, be equipped with on the Z axle motion platform and shake mirror subassembly, second shake mirror subassembly, carbon dioxide mirror seat subassembly and laser cutting subassembly along its first mirror subassembly that shakes, second that follows its with the motion. The utility model discloses to cut edge, chamfer and the integrated completion on an experimental apparatus of the three kinds of differences of process that punch, and utilize a plurality of speculum to form different light propagation routes, recycle different laser light path and accomplish different processing technology, effectively reduce equipment quantity, save equipment area and cost, effectively improve experiment machining efficiency.

Description

Experimental device integrating three laser processing technologies

Technical Field

The utility model relates to a hard and brittle material processing equipment especially relates to an experimental apparatus of three kinds of integrated laser processing technology.

Background

Due to the characteristics of short pulse time, high peak energy and the like, the ultrashort pulse laser has small heat influence area in material processing, can realize better cold processing and is widely applied to processing of hard and brittle materials. Ultrashort pulse laser is often applied to processes of trimming, chamfering, punching and the like of hard and brittle materials. The existing workpiece processing needs to utilize a plurality of laser processing devices to finish different types of processing technologies, and the devices have large occupied area, high cost and low efficiency.

Therefore, it is desired to solve the above problems.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: the utility model aims at providing a can utilize many laser light paths to accomplish different processing technology, reduce equipment quantity, save equipment area and cost, effectively improve the experimental apparatus of three kinds of integrated laser processing technology of experiment machining efficiency.

The technical scheme is as follows: for the purpose of the realization, the utility model discloses an integrated three kinds of laser beam machining process's experimental apparatus, including ultrafast laser instrument, carbon dioxide laser instrument, be located the first group speculum on the light transmission path that the ultrafast laser instrument sent laser, be located second group speculum, XY axle motion platform and the Z axle motion platform on the light transmission path that the carbon dioxide laser instrument sent laser, be equipped with on the XY axle motion platform and be used for placing the work piece that can follow its concerted movement, be equipped with on the Z axle motion platform and shake mirror subassembly, second and shake mirror subassembly, carbon dioxide mirror base subassembly and laser cutting subassembly along its concerted movement first that is used for processing the work piece along its.

The vibration isolation optical platform is provided with a gantry frame for placing the Z-axis motion platform, and the ultrafast laser, the carbon dioxide laser and the XY-axis motion platform are all arranged on the vibration isolation optical platform.

Further, the device also comprises an optical shutter positioned at the light-emitting position of the carbon dioxide laser.

Preferably, the first group of reflectors comprise a first reflector, a second reflector, a third reflector, a fourth reflector, a fifth reflector, a sixth reflector, a seventh reflector and an eighth reflector, wherein the first reflector, the second reflector, the third reflector, the fourth reflector, the fifth reflector and the seventh reflector are sequentially arranged according to the light-emitting direction of the ultrafast laser, the beam direction during processing a workpiece and the spatial position of the experimental device to form a first laser propagation path, and transmit laser to the first galvanometer component for processing the workpiece; the first reflector, the second reflector, the third reflector, the fourth reflector, the fifth reflector and the sixth reflector are sequentially arranged according to the light emitting direction of the ultrafast laser, the beam direction when a workpiece is processed and the spatial position of the experimental device to form a second laser propagation path, and the laser is transmitted to the second galvanometer component for processing the workpiece; the first reflector, the second reflector, the third reflector, the fourth reflector, the fifth reflector and the eighth reflector are sequentially arranged according to the light emitting direction of the ultrafast laser, the beam direction when a workpiece is machined and the spatial position of the experimental device to form a third laser propagation path, and laser is transmitted to the laser cutting assembly to be used for machining the workpiece.

And the second group of reflectors comprise a ninth reflector, a tenth reflector, an eleventh reflector and a tenth reflector, and are sequentially arranged according to the light-emitting direction of the carbon dioxide laser, the light beam direction during workpiece processing and the spatial position of the experimental device to form a fourth laser propagation path, and the laser is transmitted to the carbon dioxide mirror seat assembly for processing the workpiece.

Further, the first galvanometer component comprises a first connecting base plate, and a first galvanometer, a first field lens and a thirteenth reflecting mirror which are all positioned on the first connecting base plate, wherein the thirteenth reflecting mirror is used for reflecting laser emitted by the ultrafast laser and transmitting the laser to the first field lens for processing a workpiece.

Preferably, the second galvanometer assembly comprises a second connecting base plate, and a second galvanometer, a second field lens and a fourteenth reflecting mirror which are all located on the second connecting base plate, wherein the fourteenth reflecting mirror is used for reflecting laser light emitted by the ultrafast laser and transmitting the laser light to the second field lens for processing a workpiece.

Further, carbon dioxide microscope base subassembly is including fixing laser head regulating block and the guide block on Z axle motion platform to and with laser head regulating block bolted connection and can follow the laser head installation piece that installs the carbon dioxide microscope base that Z axle motion platform reciprocated, set up the spout with guide block looks adaptation on the laser head installation piece and be used for connecting the bar hole of Z axle motion platform, laser head installation piece passes through screw and bar hole swing joint on Z axle motion platform.

Furthermore, the laser cutting subassembly includes the laser cutting head and is used for pressing from both sides tight laser cutting head and the interval is fixed in the coupling assembling on the Z axle motion platform, and this coupling assembling includes the last briquetting and the lower briquetting of taking half circular structure of mutual block.

Preferably, the Z-axis motion platform is further provided with a micro-camera for observing the quality of the processed surface of the workpiece, the micro-camera is fixed on the Z-axis motion platform through a camera support, and the camera support comprises two vertical frames which are fixed with the Z-axis motion platform and are oppositely arranged, and a cross beam positioned between the two vertical frames.

Has the advantages that: compared with the prior art, the utility model has the advantages of it is following: the utility model discloses to cut edge, chamfer and the integrated completion on an experimental apparatus of the three kinds of differences of process that punch, and utilize a plurality of speculum to form different light propagation routes, recycle different laser light path and accomplish different processing technology, effectively reduce equipment quantity, save equipment area and cost, effectively improve experiment machining efficiency.

Drawings

Fig. 1 is a schematic structural view of the present invention;

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

FIG. 3 is a schematic structural view of a gantry frame of the present invention;

FIG. 4 is a schematic assembly view of the center subassembly of the present invention;

fig. 5 is a schematic structural diagram of a first galvanometer component in the present invention;

fig. 6 is a schematic structural diagram of a second galvanometer component in the present invention;

fig. 7 is a schematic structural view of a carbon dioxide lens holder assembly according to the present invention;

fig. 8 is a schematic structural view of a laser cutting assembly according to the present invention;

fig. 9 is a schematic view of the installation of the micro-camera of the present invention;

fig. 10 is a schematic structural diagram of the beam expanding lens assembly of the present invention.

Detailed Description

The technical solution of the present invention will be further explained with reference to the accompanying drawings.

As shown in fig. 1 and fig. 2, the utility model relates to an integrated three kinds of laser processing technology's experimental apparatus, including ultrafast laser 1, carbon dioxide laser 2, XY axis motion platform 3, Z axis motion platform 4, first galvanometer subassembly 5, second galvanometer subassembly 6, carbon dioxide mirror holder subassembly 7, laser cutting subassembly 8, vibration isolation optical platform 9, gantry frame 10, first speculum 11, second speculum 12, third speculum 13, fourth speculum 14, fifth speculum 15, sixth speculum 16, seventh speculum 17, eighth speculum 18, ninth speculum 19, tenth speculum 20, eleventh speculum 21, tenth speculum 22, micro-camera 23, camera support 24, optical shutter 25, expand beam mirror group 26, first work piece 27, second work piece 28 and third work piece 29. Wherein the utility model discloses an ultrafast laser 1, carbon dioxide laser 2, XY axle motion platform 3, gantry frame 10, first speculum 11, second speculum 12, third speculum 13, fourth speculum 14, ninth speculum 19, tenth speculum 20, light shutter 25 and the group 26 of beam expanding mirror all set up on vibration isolation optical platform 9.

The utility model discloses a XY axle motion platform 3 includes by X axle motor drive X axle motion platform and Y axle motor drive Y axle motion platform, installs first work piece 27, second work piece 28 and third work piece 29 through anchor clamps 30 on the XY axle motion platform 3, and first work piece 27, second work piece 28 and third work piece 29 all can be along X axle and Y axle back and forth movement along with XY axle motion platform 3.

As shown in fig. 3, the utility model discloses a gantry frame 10 is including the last wrapper sheet 1001 that is located crossbeam department, a left connecting plate 1002 and the balance cylinder 1003 that are located stand department, wherein go up wrapper sheet 1001 and be used for installing fifth speculum 15, sixth speculum 16, seventh speculum 17, eighth speculum 18, tenth speculum 20 and eleventh speculum 21, set up the preformed hole on the left connecting plate 1002, but direct mount when the later stage increases optical parts can be convenient for, need not additionally to join in marriage the hole, balance cylinder 1003 is for the weight of balanced Z axle movable part on the motion platform. As shown in fig. 4, the Z-axis motion platform 4 of the present invention is disposed on the gantry frame 10, and the Z-axis motion platform 4 is driven by the servo motor and the roller screw to move up and down along the gantry frame 10. The Z-axis motion platform 4 comprises a Z-axis sliding plate 401, a first galvanometer component 5, a second galvanometer component 6, a carbon dioxide lens holder component 7 and a laser cutting component 8 are mounted on the Z-axis sliding plate 401, and the first galvanometer component 5, the second galvanometer component 6, the carbon dioxide lens holder component 7 and the laser cutting component 8 can move up and down along the Z axis along with the Z-axis motion platform 4.

As shown in fig. 5, the first galvanometer assembly 5 includes a first connecting base plate 501 fixedly connected to the Z-axis slide 401, and a first galvanometer 502, a first field lens 503 and a thirteenth reflecting mirror 504 all located on the first connecting base plate 501, wherein the thirteenth reflecting mirror 504 is used for reflecting laser light emitted by the ultrafast laser 1 and transmitting the laser light to the first field lens 503 for processing a workpiece, and the first galvanometer 502 may be a 14mm galvanometer. As shown in fig. 6, the second galvanometer assembly 6 includes a second connection bottom plate 601 fixedly connected to the Z-axis sliding plate 401, and a second galvanometer 602, a second field lens 603 and a fourteenth reflecting mirror 604 all located on the second connection bottom plate 601, where the fourteenth reflecting mirror 604 is used for reflecting laser light emitted by the ultrafast laser 1 and transmitting the laser light to the second field lens 603 for processing a workpiece, and the second galvanometer 602 may be a 10mm galvanometer. As shown in fig. 7, the carbon dioxide lens holder assembly 7 includes a laser head adjusting block 701 and a guide block 702 fixed on the Z-axis sliding plate 401, and a laser head mounting block 704 which is connected with the laser head adjusting block 701 by a bolt and is provided with a carbon dioxide lens holder 703 and can move up and down along the Z-axis sliding plate 401, the laser head mounting block 704 is provided with a sliding slot matched with the guide block 702 and a strip-shaped hole 705 for connecting the Z-axis sliding plate 401, and the laser head mounting block 704 is movably connected to the Z-axis sliding plate 401 through a screw and the strip-shaped hole 705; and adjusting two screws which penetrate through the strip-shaped holes 705 and are used for fixing the laser head mounting block 704, and adjusting a bolt 706 on the laser head adjusting block 701 simultaneously to enable the laser head mounting block 704 to move up and down along the guide block 702. As shown in fig. 8, the laser cutting assembly 8 comprises a laser cutting head 801 and a connecting assembly which is used for clamping the laser cutting head 801 and is fixed on a Z-axis sliding plate 401 at intervals, the connecting assembly comprises an upper pressing block 802 and a lower pressing block 803 which are mutually clamped and provided with semicircular structures, and the lower pressing block 803 is fixedly connected with the Z-axis sliding plate 401 through screws.

The utility model discloses a first set of speculum is constituteed to first speculum 11, second speculum 12, third speculum 13, fourth speculum 14, fifth speculum 15, sixth speculum 16, seventh speculum 17 and eighth speculum 18, and this first set of speculum is located the light transmission path that ultrafast laser instrument 1 sent laser. The utility model discloses a ninth speculum 19, tenth speculum 20, eleventh speculum 21 and tenth speculum 22 constitute the second and organize the speculum, and this second group's speculum is located the light transmission path that carbon dioxide laser 2 sent laser.

The utility model discloses a beam direction and experimental apparatus spatial position arrange in proper order and form first laser propagation route when first speculum 11, second reflector 12, third speculum 13, fourth speculum 14, fifth speculum 15 and seventh speculum 17 are according to 1 light-emitting direction of ultrafast laser instrument, processing work piece to with laser transmission to the first scene mirror 503 of the first mirror subassembly 5 that shakes process of punching third work piece 29.

The utility model discloses a first speculum 11, second reflector 12, third speculum 13, fourth speculum 14, fifth speculum 15 and sixth speculum 16 arrange in proper order according to beam direction and experimental apparatus spatial position when ultrafast laser instrument 1 light-emitting direction, processing work piece and form the second and say laser propagation route to the second field lens 603 that shakes mirror assembly 6 with laser transmission carries out the chamfer processing to second work piece 28. The first galvanometer component 5 and the second galvanometer component 6 of the utility model can be processed and exchanged, and the first galvanometer component 5 can be subjected to a punching process or a chamfering process; the second galvanometer component 6 may also be subjected to a chamfering process or a punching process. However, since the two machining processes require different energies for the laser, if the first galvanometer component 5 is subjected to the chamfering process or the second galvanometer component 6 is subjected to the drilling process, a series of parameters such as the laser power, the Z-axis height and the like need to be retested and set, and the quality of the product after the machining processes needs to be retested. The utility model discloses well first mirror subassembly 5 that shakes carries out the technology of punching, the second shakes mirror subassembly 6 and carries out the chamfer technology, is the optimal technology solution.

The utility model discloses a first speculum 11, second reflector 12, third speculum 13, fourth speculum 14, fifth speculum 15 and eighth speculum 18 arrange in proper order according to 1 light-emitting direction of ultrafast laser instrument, beam direction and experimental apparatus spatial position when processing the work piece and form third laser propagation path to carry out side cut preorder processing to first work piece 27 on transmitting laser to the laser cutting head 801 of laser cutting subassembly 8.

The utility model discloses a ninth speculum 19, tenth speculum 20, eleventh speculum 21 and tenth speculum 22 to beam direction and experimental apparatus spatial position arrange in proper order and form fourth laser propagation path when according to 2 light-emitting directions of carbon dioxide laser, processing work pieces, and transmit the carbon dioxide mirror seat 703 of laser to carbon dioxide mirror seat subassembly 7 to first work piece 27 processing of cutting edge sequency.

As shown in fig. 9, the utility model discloses a still install the micro-camera 23 that is used for observing the workpiece by the processing surface quality on the Z axle slide 401 of Z axle motion platform 4, this micro-camera 23 is fixed in on Z axle slide 401 through camera support 24, wherein micro-camera 23 is through briquetting and camera support 24 fixed connection. The camera support comprises two vertical frames which are fixedly and oppositely arranged with the Z-axis motion platform, and a cross beam positioned between the two vertical frames. The micro-cameras 23 can be used for early-stage debugging and are convenient to observe the quality of the machined surface of the part, the number of the micro-cameras 23 is 2, the micro-cameras 23 are respectively positioned above the second workpiece 28 and the third workpiece 29, and accurate positioning can be achieved by the aid of the micro-cameras 23.

The utility model discloses a 2 light-emitting ports departments of carbon dioxide laser still are equipped with light shutter 25, and this light shutter is placed in carbon dioxide laser 2 preceding, and the main effect is the passing through and the disconnection of control laser, so the carbon dioxide laser can keep the start state to stabilize the light-emitting always, only needs opening and closing of control light shutter.

As shown in fig. 1 and 10, the present invention is provided with an expander set 26 between the second reflector 12 and the third reflector 13. The beam expanding lens group 26 of the present invention comprises a sliding guide 2601 fixedly connected to the vibration isolation optical platform 9, and a plurality of guide bases 2602 capable of sliding back and forth along the sliding guide 2601, each guide base 2602 being sequentially connected to a beam expanding lens column 2603 and a beam expanding lens 2604; the sliding guide rail 2601 is provided with a waist-shaped hole, and is fixedly connected with the vibration isolation optical platform 9 through a bolt and the waist-shaped hole, and the beam expanding lens group 26 can enlarge the diameter of a light beam emitted by the laser after expanding the beam, so that the focused light spot is smaller.

Claims (10)

1. The utility model provides an integrated three kinds of laser beam machining process's experimental apparatus which characterized in that: including ultrafast laser instrument (1), carbon dioxide laser instrument (2), be located the first group speculum of the light transmission path that ultrafast laser instrument (1) sent laser, be located the second group speculum of the light transmission path that carbon dioxide laser instrument (2) sent laser, XY axle motion platform (3) and Z axle motion platform (4), be equipped with on XY axle motion platform (3) and be used for placing the work piece that can follow its concerted movement, be equipped with on Z axle motion platform (4) and shake mirror subassembly (5), second that can be used for processing the work piece along with its concerted movement first mirror subassembly (6), carbon dioxide mirror holder subassembly (7) and laser cutting subassembly (8) that shake.

2. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the vibration isolation optical platform is characterized by further comprising a vibration isolation optical platform (9), wherein a gantry frame (10) used for placing the Z-axis moving platform (4) is arranged on the vibration isolation optical platform (9), and the ultrafast laser (1), the carbon dioxide laser (2) and the XY-axis moving platform (3) are all arranged on the vibration isolation optical platform (9).

3. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: and a light shutter (25) is also arranged at the light outlet of the carbon dioxide laser (2).

4. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the first group of reflectors comprise a first reflector (11), a second reflector (12), a third reflector (13), a fourth reflector (14), a fifth reflector (15), a sixth reflector (16), a seventh reflector (17) and an eighth reflector (18), wherein the first reflector (11), the second reflector (12), the third reflector (13), the fourth reflector (14), the fifth reflector (15) and the seventh reflector (17) are sequentially arranged according to the light-emitting direction of the ultrafast laser, the light beam direction during workpiece processing and the space position of an experimental device to form a first laser propagation path, and laser is transmitted to the first vibrating mirror assembly (5) to be used for processing the workpiece; the first reflector (11), the second reflector (12), the third reflector (13), the fourth reflector (14), the fifth reflector (15) and the sixth reflector (16) are sequentially arranged according to the light emitting direction of the ultrafast laser, the beam direction during workpiece processing and the spatial position of the experimental device to form a second laser propagation path, and the laser is transmitted to the second galvanometer component (6) for processing the workpiece; the first reflector (11), the second reflector (12), the third reflector (13), the fourth reflector (14), the fifth reflector (15) and the eighth reflector (18) are sequentially arranged according to the light-emitting direction of the ultrafast laser, the light beam direction during workpiece processing and the spatial position of an experimental device to form a third laser propagation path, and laser is transmitted to the laser cutting assembly (8) to be used for processing the workpiece.

5. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the second group of reflectors comprise a ninth reflector (19), a tenth reflector (20), an eleventh reflector (21) and a tenth reflector (22), and are sequentially arranged according to the light-emitting direction of the carbon dioxide laser, the light beam direction during workpiece processing and the spatial position of the experimental device to form a fourth laser propagation path, and the laser is transmitted to the carbon dioxide mirror holder assembly (7) to be used for processing the workpiece.

6. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the first galvanometer assembly (5) comprises a first connecting base plate (501), a first galvanometer (502), a first field lens (503) and a thirteenth reflecting mirror (504), wherein the first galvanometer, the first field lens (503) and the thirteenth reflecting mirror (504) are all located on the first connecting base plate (501), and the thirteenth reflecting mirror (504) is used for reflecting laser light emitted by the ultrafast laser (1) and transmitting the laser light to the first field lens (503) for processing a workpiece.

7. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the second galvanometer assembly (6) comprises a second connecting bottom plate (601), and a second galvanometer (602), a second field lens (603) and a fourteenth reflecting mirror (604) which are all positioned on the second connecting bottom plate (601), wherein the fourteenth reflecting mirror (604) is used for reflecting laser light emitted by the ultrafast laser (1) and transmitting the laser light to the second field lens (603) for processing a workpiece.

8. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: carbon dioxide mirror seat subassembly (7) are including fixing laser head regulating block (701) and guide block (702) on Z axle motion platform (4) to and with laser head regulating block (701) bolted connection and can follow laser head installation piece (704) of installing carbon dioxide mirror seat (703) that Z axle motion platform (4) reciprocated, set up spout with guide block (702) looks adaptation on this laser head installation piece (704) and be used for connecting Z axle motion platform's bar hole (705), laser head installation piece (704) are through screw and bar hole (705) swing joint on Z axle motion platform (4).

9. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the laser cutting assembly (8) comprises a laser cutting head (801) and a connecting assembly, wherein the connecting assembly is used for clamping the laser cutting head (801) and fixed on the Z-axis moving platform (4) at intervals, and comprises an upper pressing block (802) and a lower pressing block (803) which are mutually clamped and provided with semicircular structures.

10. The experimental facility for integrating three laser processing technologies as claimed in claim 1, wherein: the Z-axis motion platform (4) is further provided with a micro-camera (23) for observing the quality of the processed surface of the workpiece, the micro-camera (23) is fixed on the Z-axis motion platform (4) through a camera support (24), and the camera support (24) comprises two vertical frames which are fixedly arranged opposite to the Z-axis motion platform and a cross beam positioned between the two vertical frames.

Images