CN203751531U

CN203751531U - Optical fiber laser cutting machine

Info

Publication number: CN203751531U
Application number: CN201420041546.7U
Authority: CN
Inventors: 邹大润; 樊景风; 赵剑; 陈根余; 陈燚; 高云峰
Original assignee: Shenzhen Hans Laser Technology Co Ltd
Current assignee: Han s Laser Technology Industry Group Co Ltd
Priority date: 2014-01-22
Filing date: 2014-01-22
Publication date: 2014-08-06
Anticipated expiration: 2024-01-22

Abstract

The utility model provides an optical fiber laser cutting machine which is suitable for the field of LED (Light Emitting Diode) products. The optical fiber laser cutting machine comprises a lathe bed, a beam, a Z axis device, a synchronous exchange workbench and a protective outer cover; the Z axis device is provided with a cutting head; the stroke of the cutting head along the length direction of the lathe bed is larger than 6000 mm and the stroke of the cutting head along the width direction of the lathe bed is larger than 2000 mm; the lathe bed and the synchronous exchange workbench are provided with an upper layer of supporting structure and a lower layer of supporting structure respectively; the bilateral sides of the lathe bed are provided with a transmission chain which moves in a reciprocating mode; the chain comprises an upper linear section and a lower linear section, wherein a cutting workbench is driven by the upper linear section to be run on the upper layer of supporting structure and a cutting workbench is driven by the lower linear section to be run on the lower layer of supporting structure. According to the optical fiber laser cutting machine, a higher and lower double-layer exchange workbench structure is adopted and matched with the reciprocating movement of the chain, the upper layer of cutting workbench and the lower layer of cutting workbench are driven to move in a reciprocating mode, and accordingly the exchange of the two cutting workbenches is achieved and the large stroke of Z axis structure is arranged, a precision linear guide rail and a gear and rack transmission part are adopted, and accordingly the high-efficiency, high-accuracy and large-range cutting is achieved.

Description

Optical-fiber laser cutting machine

Technical field

The utility model relates to laser cutting technique field, relates in particular to a kind of optical-fiber laser cutting machine.

Background technology

Dull and stereotyped optical-fiber laser cutting machine is the laser cutting device for working flat plate member, in order to improve cutting efficiency, there is at present a kind of laser cutting machine with exchangeable workbench, but value volume and range of product is less, and the processing breadth of existing dull and stereotyped optical-fiber laser cutting machine only has 3000mm*1500mm and 4000mm*2000mm, cannot adapt to the high accuracy of large-breadth plates by using, the requirement of high efficiency cutting processing.The laser cutting machine of the large format (6000mm*2000mm) of existing only a few is all to adopt hydraulic pressure pallet changer mode, this mode must be carried out pallet changer by lifting platform, swap time is long, and once can only realize the exchange of a cutting working platform, because the synchronism problem of oil hydraulic cylinder easily breaks down, make manufacturing cost higher simultaneously.

Utility model content

The purpose of this utility model is to provide a kind of optical-fiber laser cutting machine, is intended to realize the flat-plate laser cutting of high efficiency, high accuracy and large format.

The utility model is to realize like this, optical-fiber laser cutting machine, comprise lathe bed, the crossbeam that also can slide along lathe bed length direction across described lathe bed setting, be arranged on described crossbeam and can and cover in the containment envelope on described lathe bed along Z axis device, the synchronous exchange workbench docking with described lathe bed of crossbeam slip, described Z axis device is provided with cutting head moving up and down;

Described cutting head is greater than respectively 6000mm and 2000mm along the length of described lathe bed and the stroke of width;

Described lathe bed and synchronous exchange workbench are equipped with the upper and lower two-layer supporting construction for carrying cutting working platform, and the two-layer supporting construction of described lathe bed and synchronous exchange workbench is docked respectively;

The both sides of described lathe bed are provided with reciprocating driving chain, described driving chain comprises: the upper straightway that drives a cutting working platform to move in the supporting construction of the upper strata of described lathe bed, and the lower straightway that drives another cutting working platform to move in the lower layer support structure of described lathe bed.

As optimal technical scheme of the present utility model:

Described lathe bed is provided with and prolongs slide rail and the tooth bar that its length direction extends, and described crossbeam is provided with the chute and the gear that coordinate with described slide rail and tooth bar.

In described cutting head, be provided with the capacitance type sensor for detection of the distance between Laser output end face and the surface of cutting working platform of described cutting head.

The supporting construction of described lathe bed and synchronous exchange workbench is equipped with the six side's rails that slide for described cutting working platform, and six side's rails in six side's rails in the two-layer supporting construction of described lathe bed and the two-layer supporting construction of synchronous exchange workbench dock respectively.

Described lathe bed is provided with chain driving motor near one end of described synchronous exchange workbench, the both sides of described lathe bed are provided with chain kit, described chain kit comprises described chain and drives the reciprocating hinge wheel of described chain and tightener sprocket, the coaxial minor sprocket that connects of described hinge wheel, described chain driving motor is connected with described minor sprocket by two long pass moving axis.

Described chain is provided with two groups of traction wheels that chain is divided equally, and described two groups of traction wheels lay respectively at described upper straightway and lower straightway, and the end that is pulled of described cutting working platform is provided with the guiding piece coordinating with described traction wheel.

One side of described lathe bed is provided with deceleration inductive switch and stops inductive switch near one end part of described chain, the upper straightway of described chain is provided with and can and stops the first sensing chip and the second sensing chip that inductive switch is responded to by described deceleration inductive switch, and the spacing of described the first sensing chip and the second sensing chip is identical with the spacing that stops inductive switch with described deceleration inductive switch.

The trailed one end of described cutting working platform is provided with elastic buffering pad.

The both sides of described lathe bed are provided with the clamping device that puts in place, described lathe bed is provided with away from one end of described synchronous exchange workbench the positioner that puts in place, the described positioner that puts in place has a latch, and the trailed one end of described cutting working platform is provided with the pin hole coordinating with described latch.

Described lathe bed is equipped with automatic lubrication installation.

The optical-fiber laser cutting machine that the utility model provides adopts the double-deck synchronous exchange Working table structure of high-low-position, coordinate chain to move back and forth, drive upper and lower two-layer cutting working platform to move back and forth, chain once moves back and forth the exchange that can realize two cutting working platforms, has significantly improved the exchange efficiency of cutting working platform; Be equipped with large stroke Z axis structure, adopt precise linear guide and high class gear rack-driving parts simultaneously, ensure that cutting working platform is steady, safe, move and exchange fast, and then realize high efficiency, high accuracy, large format cutting, improved to greatest extent production efficiency.

Brief description of the drawings

Fig. 1 is the perspective view of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Fig. 2 is the decomposition texture schematic diagram of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Fig. 3 is the structural representation that the optical-fiber laser cutting machine that provides of the utility model embodiment is removed containment envelope;

Fig. 4 is the enlarged drawing of a-quadrant in Fig. 3;

Fig. 5 is the enlarged drawing in B region in Fig. 3;

Fig. 6 is the enlarged drawing in C region in Fig. 3;

Fig. 7 is the structural representation of facing of the crossbeam of the optical-fiber laser cutting machine that provides of the utility model embodiment and lathe bed;

Fig. 8 is the side-looking structural representation of the header portion of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Fig. 9 is the structural representation of the Z axis device of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Figure 10 is the part-structure schematic diagram () of the Z axis device of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Figure 11 is the part-structure schematic diagram (two) of the Z axis device of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Figure 12 is the structural representation of the synchronous exchange workbench of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Figure 13 is the part-structure schematic diagram () of the synchronous exchange workbench of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Figure 14 is the part-structure schematic diagram (two) of the synchronous exchange workbench of the optical-fiber laser cutting machine that provides of the utility model embodiment;

Figure 15 is the lathe bed of optical-fiber laser cutting machine and the structural representation of synchronous exchange workbench that the utility model embodiment provides;

Figure 16 is the enlarged drawing in D region in Figure 15;

Figure 17 is the enlarged drawing in E region in Figure 15.

Detailed description of the invention

In order to make the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein is only in order to explain the utility model, and be not used in restriction the utility model.

Refer to Fig. 1,2, the optical-fiber laser cutting machine that the utility model embodiment provides mainly comprises: lathe bed 1, crossbeam 2, Z axis device 3, synchronous exchange workbench 4 and containment envelope 5.Crossbeam 2 is fixed on lathe bed 1, and Z axis device 3 is arranged on crossbeam 2, and synchronous exchange workbench 4 docks with lathe bed 1, and containment envelope 5 covers in outside lathe bed 1, and it is lightweight, dustproof, reliable, for the protection of other facilities on lathe bed 1 and lathe bed 1.Wherein, lathe bed 1 and synchronous exchange workbench 4 are equipped with the supporting construction of upper and lower high-low-position, for carrying upper and lower two cutting working platforms.The upper and lower two-layer supporting construction of lathe bed 1 and synchronous exchange workbench 4 is docked respectively, and then ensures that cutting working platform can move to lathe bed 1 by synchronous exchange workbench 4 smoothly.

With further reference to the front view of the lathe bed 1 shown in Fig. 7, lathe bed 1 and cutting working platform are rectangular configuration, and for convenience of description, the present embodiment is called length direction " side ", width is called " end ".The both sides of lathe bed 1 are respectively equipped with slide rail 11 and tooth bar 12, crossbeam 2 is provided with the chute 21 coordinating with slide rail 11 and the gear 22 coordinating with tooth bar 12, rotate along tooth bar 12 by the first AC servo motor 23 driven wheels 22 on digital control system control crossbeam 2, thereby drive chute 21 to slide along slide rail 11, and then drive crossbeam 2 to realize seesawing of X-direction.With further reference to Fig. 8～11, Z axis device 3 comprises slide 31 and slide plate 32, slide 31 is connected respectively the second AC servo motor 33 and the 3rd AC servo motor 34 with slide plate 32, and wherein the second AC servo motor 33 drives slide 31 to slide along crossbeam 2, realizes the side-to-side movement of Y direction.Cutting head 35 is set on slide plate 32, in cutting head 35, be provided with capacitance type sensor, for detection of the end face of cutting head 35 and the spacing on cutting working platform surface, digital control system is determined the height of cutting head 35 according to this spacing and is controlled the 3rd AC servo motor 34 and drive ballscrew nut fitting 36 to drive slide plate 32 to realize moving up and down of Z-direction, thereby drives cutting head 35 to realize upper and lower fast moving and feed motion.Like this, along the seesawing of lathe bed 1, slide 31 along the side-to-side movement of crossbeam 2 and moving up and down of slide plate 32, realize the three-dimensional motion of the X, Y, Z axis direction of cutting head 35 by crossbeam 2, completed laser cutting.

The X-axis stroke of the cutting head 35 in the present embodiment is 6030mm, and Y-axis stroke is 2020mm, and Z axis stroke is 300mm, can realize the large format hi-precision cutting of 6000mm*2000mm.

As Figure 12～14, synchronous exchange workbench 4 comprises fixed frame 41 and is arranged at the cutting working platform 42 on fixed frame 41, and fixed frame 41 adopts channel-section steel, square tube to be welded into machine-shaping after entirety, guarantee its bearing capacity, cutting working platform 42 is welded by square tube, Stability Analysis of Structures, and intensity is high.Fixed frame 41 and lathe bed 1 include upper and lower two-layer high-low-position supporting construction, and six side's rails 6 are installed on all supporting surfaces of supporting construction.Six side's rails in the upper and lower two-layer supporting construction of synchronous exchange workbench 4 dock with six side's rails in the supporting construction of lathe bed 1, and cutting working platform 42 can be slided to lathe bed 1 by synchronous exchange workbench 4 smoothly.

With further reference to Fig. 3,15,16,17, the exchange of cutting working platform 42 realizes by following structure:

Two long pass moving axis 71 that lathe bed 1 is provided with a chain driving motor 7 and is attached thereto near one end of synchronous exchange workbench 4, the both sides of lathe bed 1 are provided with chain kit 8, comprise hinge wheel 81, minor sprocket 82, tightener sprocket 83 and chain 84.Hinge wheel 81 and minor sprocket 82 are located at lathe bed 1 one end near synchronous exchange workbench 4, and tightener sprocket 83 is arranged at the other end of lathe bed 1.Chain driving motor 7 is connected with the minor sprocket 82 of lathe bed 1 both sides by long pass moving axis 71, digital control system Quality Initiative driving motor 7 drives long pass moving axis 71 to drive minor sprocket 82 to rotate, minor sprocket 82 drives hinge wheel 81 to rotate, and hinge wheel 81 drives tightener sprocket 83 to rotate by chain 84.Chain 84 moves back and forth but not equidirectional transmission under the drive of sprocket wheel, and the transmission distance of chain 84 is the length of the straightway of chain.Chain 84 is provided with two groups of traction wheels 841, two groups of traction wheels 841 are divided whole chain 84 equally, and lay respectively on the upper straightway and lower straightway of chain 84, in the time that one group of traction wheel 841 is positioned at one end of chain stroke, another group traction wheel 841 is positioned at the other end of stroke just.The end that is pulled of cutting working platform 42 is provided with the guiding piece 421 matching with traction wheel 841, traction wheel 841 coordinates with the draw-in groove on guiding piece 421, cutting working platform 42 and chain 84 are fixed together, thereby drive cutting working platform 42 to move down six leading of side's rail 6 by chain 84, the transmission distance of chain 84 is the movement travel of cutting working platform 42.The cutting working platform 42 being drawn by the upper straightway of chain 84 moves along upper strata six side's rails 6 of lathe bed 1 just, the cutting working platform 42 being drawn by the lower straightway of chain 84 moves along lower floor's six side's rails 6 of lathe bed 1 just, in the time that the traction wheel 841 of the upper straightway of chain 84 moves to stroke one end, the cutting working platform 42 on upper strata is pulled away, now the traction wheel 841 of the lower straightway of chain 84 moves to the other end of stroke, and 42 tractions of the cutting working platform of lower floor are come in.That is to say, carry out once, in reciprocating process, can completing the exchange of upper and lower two cutting working platforms 42 at chain 84.

With further reference to Fig. 4, in order to make cutting working platform 42 safe operations and steadily exchange, be provided with two sensing chips in the upper straightway of chain 84, be provided with deceleration inductive switch 13 at one end place of the nearly chain stroke of a side joint of lathe bed 1 and stop inductive switch 14, wherein, stop the terminal of the more close chain stroke of inductive switch 14.Corresponding with it, the spacing that the upper straightway of chain 84 is provided with the first sensing chip 842 and 843, two sensing chips of the second sensing chip is identical with the spacing that stops inductive switch 14 with deceleration inductive switch 13.In the time that chain 84 approaches stroke end, when the first sensing chip 842 process deceleration inductive switch 13, digital control system control chain 84 runs slowly, when the first sensing chip 842 is through stopping inductive switch 14, when the second sensing chip 843 process deceleration inductive switch 13, digital control system control chain 84 is out of service.

With further reference to Fig. 5, in order to ensure cutting working platform 42 safe operations, can also elastic buffering pad 422 be set in the trailed one end of cutting working platform 42, prevent that cutting working platform 42 from being clashed into.

With further reference to Fig. 6, the both sides of lathe bed 1 are respectively equipped with the clamping device that puts in place, one end of lathe bed 1 is provided with the positioner 15 that puts in place, this positioner 15 that puts in place specifically has the location cylinder unit of a latch 151, accordingly, the trailed one end of cutting working platform 42 is provided with the pin hole 423 coordinating with latch 151.In the time that cutting working platform 42 is out of service, the latch 151 of location cylinder unit inserts pin hole 423, and the clamping device that puts in place of lathe bed 1 both sides clamps cutting working platform 42, prevents its double swerve, and then by fixing cutting working platform 42, prevent that workbench from shaking in the time of cutting.

Further, the lathe bed 1 in the present embodiment adopts integral solder mode to manufacture, and annealing is eliminated after internal stress is processed and carried out roughing, then carries out oscillating aging processing, then carries out fining-off to guarantee rigidity, stability, shock resistance and the precision of lathe.Crossbeam 2 adopts cast aluminium manufacture, after elimination internal stress, carries out machined, ensures overall rigidity, stability and precision.The slide plate of Z axis device and slide all adopt cast aluminium manufacture, after elimination internal stress, carry out machined, ensure overall precision.The flatness of all guide rails, tooth bar installed surface, linearity, the depth of parallelism all reach Europe superscript 6 class precision requirements.

Further, lathe bed 1 is equipped with automatic lubrication installation, regularly adds lubricating oil to the moving component of lathe bed 1, crossbeam 2 parts, ensures that it moves under good state, improves the service life of the parts such as slide rail 11, chute 21, tooth bar 12, gear 22.

The optical-fiber laser cutting machine that the utility model embodiment provides adopts the double-deck synchronous exchange Working table structure of high-low-position, coordinate chain driving motor drive sprocket chain to move back and forth, drive upper and lower two-layer cutting working platform to move back and forth, chain once moves back and forth the exchange that can realize two cutting working platforms, has significantly improved the exchange efficiency of cutting working platform; Be equipped with large stroke Z axis structure, adopt precise linear guide and high class gear rack-driving parts simultaneously, ensure that cutting working platform is steady, safe, move and exchange fast, and then realize high efficiency, high accuracy, large format cutting, improved to greatest extent production efficiency.

The foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all any amendments of doing within spirit of the present utility model and principle, be equal to and replace and improvement etc., within all should being included in protection domain of the present utility model.

Claims

1. optical-fiber laser cutting machine, it is characterized in that, comprise lathe bed, the crossbeam that also can slide along lathe bed length direction across described lathe bed setting, be arranged on described crossbeam and can and cover in the containment envelope on described lathe bed along Z axis device, the synchronous exchange workbench docking with described lathe bed of crossbeam slip, described Z axis device is provided with cutting head moving up and down;

2. optical-fiber laser cutting machine as claimed in claim 1, is characterized in that, described lathe bed is provided with and prolongs slide rail and the tooth bar that its length direction extends, and described crossbeam is provided with the chute and the gear that coordinate with described slide rail and tooth bar.

3. optical-fiber laser cutting machine as claimed in claim 1, is characterized in that, is provided with the capacitance type sensor for detection of the distance between Laser output end face and the surface of cutting working platform of described cutting head in described cutting head.

4. optical-fiber laser cutting machine as claimed in claim 1, it is characterized in that, the supporting construction of described lathe bed and synchronous exchange workbench is equipped with the six side's rails that slide for described cutting working platform, and six side's rails in six side's rails in the two-layer supporting construction of described lathe bed and the two-layer supporting construction of synchronous exchange workbench dock respectively.

5. optical-fiber laser cutting machine as claimed in claim 1, it is characterized in that, described lathe bed is provided with chain driving motor near one end of described synchronous exchange workbench, the both sides of described lathe bed are provided with chain kit, described chain kit comprises described chain and drives the reciprocating hinge wheel of described chain and tightener sprocket, the coaxial minor sprocket that connects of described hinge wheel, described chain driving motor is connected with described minor sprocket by two long pass moving axis.

6. optical-fiber laser cutting machine as claimed in claim 1, it is characterized in that, described chain is provided with two groups of traction wheels that chain is divided equally, described two groups of traction wheels lay respectively at described upper straightway and lower straightway, and the end that is pulled of described cutting working platform is provided with the guiding piece coordinating with described traction wheel.

7. optical-fiber laser cutting machine as claimed in claim 1, it is characterized in that, one side of described lathe bed is provided with deceleration inductive switch and stops inductive switch near one end part of described chain, the upper straightway of described chain is provided with and can and stops the first sensing chip and the second sensing chip that inductive switch is responded to by described deceleration inductive switch, and the spacing of described the first sensing chip and the second sensing chip is identical with the spacing that stops inductive switch with described deceleration inductive switch.

8. optical-fiber laser cutting machine as claimed in claim 1, is characterized in that, the trailed one end of described cutting working platform is provided with elastic buffering pad.

9. optical-fiber laser cutting machine as claimed in claim 1, it is characterized in that, the both sides of described lathe bed are provided with the clamping device that puts in place, described lathe bed is provided with away from one end of described synchronous exchange workbench the positioner that puts in place, the described positioner that puts in place has a latch, and the trailed one end of described cutting working platform is provided with the pin hole coordinating with described latch.

10. optical-fiber laser cutting machine as claimed in claim 1, is characterized in that, described lathe bed is equipped with automatic lubrication installation.