CN114409238A - Integrated glass laser cutting equipment and glass processing line with same - Google Patents

Abstract

The invention relates to the technical field of glass processing equipment, in particular to integrated glass laser cutting equipment and a glass processing line with the same, wherein the integrated glass laser cutting equipment comprises a rack, a cross beam is arranged on the rack, and a first driving mechanism is arranged between two ends of the cross beam and the rack and is used for driving the cross beam to reciprocate along the conveying direction of glass; the beam is provided with an infrared laser, a first catadioptric lens group and CO₂The laser cutting seat plate is driven by a second driving mechanism to reciprocate on the beam; after the whole glass is cut by the laser cutting equipment provided by the invention, the whole glass can be directly sent into a glass cleaning machine for cleaning without breaking off and edging, and then the whole glass is sent into a toughening furnace for toughening treatment, so that the size is extremely largeThe efficiency of glass processing is improved, the problem of loss appearing in the above-mentioned piece, edging process of breaking off with the fingers and thumb has been avoided, the cost of glass processing has been reduced.

Description

Integrated glass laser cutting equipment and glass processing line with same

Technical Field

The invention relates to the technical field of glass processing equipment, in particular to integrated glass laser cutting equipment and a glass processing line with the same.

Background

Glass is an important material widely used in many industries of the national economy, such as the automotive industry, the construction industry, medical treatment, displays and electronics, and the most common type of glass at present is soda-lime glass, also known as alkali glass, mainly used in the automotive industry, the construction industry and the household appliances field, and the thickness is usually 1.6 to 12 mm.

Glass is characterized by hard, brittle properties which present significant processing difficulties. Conventional glass cutting uses cemented carbide or diamond cutting tools, and the cutting process is typically as follows: the glass is first scored on the surface using a diamond tip or a carbide wheel or a high hardness metal wheel and then mechanically cut along the score line. When glass is scribed by a grinding wheel or a mechanical wheel, tangential tension in the cutting direction is generated, thereby breaking the glass-like scratches. The result of this cutting method is an unsmooth edge, manifested as micro-cracks, residual asymmetric edge stresses, and residual debris on the material. In many applications, microcracks, caused by chipping or localized stress, can lead to device failure, and therefore the edges of the cut glass must be polished to enhance edge strength; in addition, an auxiliary agent is needed in the machining of the mechanical wheel to assist cutting, the auxiliary agent can be adhered to the edge of the glass finished product and needs to be treated by ultrasonic cleaning after water washing, and the subsequent machining operation and low yield directly increase the cost of the glass product.

Nowadays, the quality of glass products is required to be higher and higher, more accurate processing results must be realized, and technical innovation of glass cutting is urgently needed because the traditional process is difficult to meet the requirements of microcrack and edge quality. In the prior art, a laser cutting technology is mature, and the laser cutting technology is successfully applied to cutting of materials such as metal plates, metal pipes, organic plates, pipes and the like, so that the traditional manufacturing process is greatly changed. Glass is an inorganic material and has a very low thermal conductivity, so theoretically, laser machining should be more effective, which has led to the development of laser cutting glass technology.

Disclosure of Invention

One of the objects of the present invention is to provide an integrated glass laser cutting apparatus by which high precision, high efficiency and high quality of glass cutting are achieved to significantly improve the efficiency of glass processing.

In order to achieve the purpose, the invention adopts the following technical scheme:

the integrated glass laser cutting equipment comprises a rack, wherein the rack is provided with a conveying surface for bearing glass and conveying the glass forwards, a cross beam stretching over the conveying surface is arranged on the rack, and a first driving mechanism is arranged between two ends of the cross beam and the rack and used for driving the cross beam to reciprocate along the conveying direction of the glass;

the beam is provided with an infrared laser, a first catadioptric lens group and CO₂The laser cutting seat plate is driven by a second driving mechanism to reciprocate on the beam;

the laser cutting base plate is provided with a first outer light path mirror group, a second outer light path mirror group and a laser cutting module, the laser cutting module comprises a laser mounting plate and a servo motor for driving the laser mounting plate to reciprocate in the vertical direction, the laser mounting plate is provided with a laser cutting head and a focusing mirror, the first outer light path mirror group can receive infrared laser energy of the first turning mirror group and transmit the infrared laser energy to the laser cutting head, and glass on a conveying surface is subjected to laser cutting;

the second outer optical path lens group can receive the laser energy of the second turning lens group and transmit the laser energy to the focusing lens.

In a further technical scheme, two ends of the cross beam are respectively provided with an L-shaped support plate, one side of each L-shaped support plate, which is close to the rack, is provided with a first sliding block, and the first sliding blocks and a first linear guide rail which is arranged on the rack and extends along the length direction of the rack form sliding guide fit;

one side that L type backup pad closes on the frame still is equipped with first iron core coil, first iron core coil closes on the interval arrangement with the first permanent magnet that sets up in the frame and lay along its length direction, and produces magnetic force after first iron core coil circular telegram, drives L type backup pad removes.

In a further technical scheme, the second driving mechanism comprises a second iron core coil and a second sliding block which are arranged on the laser cutting seat plate, and the second sliding block and a second linear guide rail which is arranged on the cross beam and extends along the length direction of the cross beam form sliding guide fit;

the second iron core coil and a second permanent magnet which is arranged on the cross beam and laid along the length direction of the cross beam are arranged at intervals, and magnetic force is generated after the second iron core coil is electrified to drive the laser cutting seat plate to move.

In a further technical scheme, the frame includes bottom sprag frame and sets up the marble slab of bottom sprag frame both sides, a drive mechanism sets up on the marble slab.

In a further technical scheme, a code printer is further arranged on the laser mounting plate and used for printing code marks on the glass.

In a further technical scheme, buffers are arranged at two ends of the rack and used for buffering the cross beam.

In a further technical scheme, the first turning and folding lens group comprises a first 90-degree outer light path lens group, a second 90-degree outer light path lens group, a third 90-degree outer light path lens group and a fourth 90-degree outer light path lens group;

the first 90-degree outer light path mirror group is arranged at a laser emission port of the infrared laser and used for receiving infrared laser energy and transmitting the infrared laser energy to the second 90-degree outer light path mirror group, and the second 90-degree outer light path mirror group receives the infrared laser energy and transmits the infrared laser energy to the first outer light path mirror group through the third 90-degree outer light path mirror group and the fourth 90-degree outer light path mirror group.

In a further technical scheme, a laser beam expander is arranged in the first catadioptric lens group.

In a further technical scheme, the second turning mirror group comprises a 90-degree outer light path mirror group five and a 90-degree outer light path mirror group six, andthe 90-degree outer optical path lens group receives CO₂And laser emitted by the laser is transmitted to the second outer light path lens group through the 90-degree outer light path lens group six.

The invention also provides a glass processing line with the laser cutting equipment.

Compared with the prior art, the invention has the following technical effects:

the laser cutting equipment provided by the invention effectively avoids the defects that the traditional cutting process is easy to generate gaps at the cutting seams and generate more glass scraps, and can directly send the whole glass into a glass cleaning machine for cleaning without sheet breaking and edge grinding after the whole glass is cut by the laser cutting equipment provided by the invention, and then send the whole glass into a tempering furnace for tempering treatment, so that the glass processing efficiency is greatly improved, the problem of loss in the sheet breaking and edge grinding processes is avoided, the energy consumption of the cleaning machine in unit area is reduced, the loading rate of the tempering furnace is increased, the field is saved, and the glass processing cost is reduced.

Additional features and advantages of the invention will be set forth in the detailed description which follows.

Drawings

FIG. 1 is a schematic structural view of an integrated glass laser cutting apparatus provided in accordance with an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of position A of FIG. 1;

FIG. 3 is a schematic diagram showing the position of a second drive mechanism in the present invention;

the reference numbers in the figures illustrate: 1. glass; 10. a first frame; 101. a bottom support frame; 102. a marble plate; 103. a conveyor belt; 104. a Teflon plate; 11. a cross beam; 111. a second linear guide; 112. a second permanent magnet; 12. an infrared laser; 13. a first turning and folding lens group; 131. a 90-degree first external optical path lens group; 132. a 90-degree outer light path lens group II; 133. a 90-degree outer light path lens group III; 134. a 90-degree outer light path lens group IV; 135. a laser beam expander; 14. CO 2₂A laser; 15. a second turning lens group; 151. a 90-degree outer light path lens group V; 152. 90 degree external light pathA sixth lens group; 16. a laser cutting seat plate; 161. a first external optical path lens group; 162. a second outer optical path lens group; 163. a laser cutting module; 1631. a laser mounting plate; 1632. a servo motor; 1633. a laser cutting head; 1634. a focusing mirror; 1635. a code printer; 164. a second core coil; 165. a second slider; 17. a first linear guide rail; 18. a first permanent magnet; 19. a buffer; 20. an L-shaped support plate; 21. a first slider; 22. a first core coil.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further clarified by combining the specific drawings.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As described above, with reference to fig. 1, 2 and 3, the present invention provides an integrated glass laser cutting apparatus, the laser cutting apparatus includes a frame 10, the frame 10 has a conveying surface for carrying glass 1 and conveying it forward, a beam 11 crossing the conveying surface is disposed on the frame 10, and a first driving mechanism is disposed between two ends of the beam 11 and the frame 10 for driving the beam 11 to move back and forth along the conveying direction of the glass 1;

the beam 11 is provided with an infrared laser 12, a first catadioptric lens group 13 and CO₂A laser 14, a second turning mirror group 15 and a laser cutting seat plate 16, whereinThe laser cutting seat plate 16 is driven by a second driving mechanism to reciprocate on the cross beam 11;

the laser cutting seat plate 16 is provided with a first outer optical path lens group 161, a second outer optical path lens group 162 and a laser cutting module group 163, the laser cutting module group 163 comprises a laser mounting plate 1631 and a servo motor 1632 for driving the laser mounting plate 1631 to reciprocate in the vertical direction, the laser mounting plate 1631 is provided with a laser cutting head 1633 and a focusing lens 1634, the first outer optical path lens group 161 can receive the infrared laser energy of the first turning mirror group 13 and transmit the infrared laser energy to the laser cutting head 1633, and the glass 1 on the conveying surface is subjected to laser cutting; the second external optical path lens assembly 162 can receive the laser energy of the second turning lens assembly 15 and transmit the laser energy to the focusing lens 1634.

In the present invention, the first external optical path lens set 161 is mounted on the laser cutting base plate 16, and a mounting frame of the first external optical path lens set and the laser cutting base plate 16 is not shown in the drawing, and in practical use, the first external optical path lens set only moves back and forth along the length direction of the beam 11 along with the laser cutting base plate 16 under the action of the second driving mechanism, so as to ensure that the infrared laser energy from the first turning lens set 13 can be stably received.

In addition, the second external optical lens set 162 and the focusing lens 1634 are not shown in fig. 3, and the second external optical lens set 162 is also fixed on the laser cutting base plate 16, and in practical use, it only moves back and forth along the length direction of the beam 11 along with the laser cutting base plate 16 under the action of the second driving mechanism, so as to ensure that the laser energy from the second turning lens set 15 can be stably received.

The laser cutting equipment provided by the invention is particularly suitable for cutting glass with the thickness of 3-12mm, based on the existing glass cutting equipment, such as a hard alloy or diamond cutting tool, the cutting of the glass with the thickness of 3-12mm usually needs to be scribed twice, then the glass can be completely cut by splitting operation, cracks are easily generated at the cutting seams of the glass, and more glass scraps which are difficult to process are generated, therefore, based on the traditional cutting equipment, the edge grinding treatment needs to be carried out on each piece of glass after the cutting, then the typesetting is carried out in a tempering furnace for tempering treatment, the efficiency of glass production and processing is low, certain loss exists during the splitting and edge grinding treatment of the glass, and the cost of glass products is increased.

Based on the laser cutting equipment provided by the invention, firstly, the infrared laser 12 arranged on the beam 11 carries out primary laser cutting on the whole glass, and then CO is utilized₂The laser 14 performs in-situ splitting on the cutting seam cut by the infrared laser 12, so that the defects that a gap is easily generated at the cutting seam and more glass fragments are generated in the traditional cutting process are avoided, and the laser cutting equipment provided by the invention does not need to perform splitting and edging processes after cutting the whole glass, can directly send the whole glass into a glass cleaning machine for cleaning, and then send the whole glass into a tempering furnace for tempering, so that the glass processing efficiency is greatly improved, the problem of loss in the splitting and edging processes is avoided, and the glass processing cost is reduced.

In a specific embodiment of the present invention, the conveying surface on the frame 10 is composed of a plurality of conveying belts 103 arranged in parallel at intervals, in order to avoid damaging the conveying belts 103 during laser cutting, a teflon plate 104 is further disposed on the frame 10 to lift the glass 1 during laser cutting, and the plurality of conveying belts 103 carry the glass 1 and convey it forward is a prior art in the field, which is not described herein again.

In the present invention, the first driving mechanism is used for driving the beam 11 to move on the frame 10 to drive the infrared laser assembly and the CO on the beam 11₂The laser assembly is moved to different positions on the frame 10 to effect laser cutting of different positions of the glass 1 carried on its conveying surface.

As a specific embodiment of the first driving mechanism, two ends of the cross beam 11 are respectively provided with an L-shaped support plate 20, one side of the L-shaped support plate 20 adjacent to the rack 10 is provided with a first slide block 21, and the first slide block 21 forms a sliding guiding fit with a first linear guide rail 17 which is arranged on the rack 10 and extends along the length direction thereof;

one side that L type backup pad 20 closes to frame 10 still is equipped with first iron core coil 22, first iron core coil 22 closes to the interval arrangement with the first permanent magnet 18 that sets up on frame 10 and lay along its length direction, and produces magnetic force after first iron core coil 22 circular telegram, drives L type backup pad 20 removes.

The infrared laser component and the CO can be realized through the first driving mechanism₂The laser assembly moves back and forth along the length direction of the frame 10, and the infrared laser assembly and the CO are realized through a second driving mechanism₂The laser assembly moves back and forth in the width direction of the frame 10, and the infrared laser assembly and the CO are matched with each other₂As a specific embodiment of the second driving mechanism, the laser assembly moves to any position of the conveying surface on the machine frame 10, the second driving mechanism includes a second iron core coil 164 and a second slide block 165 which are arranged on the laser cutting seat plate 16, and the second slide block 165 and a second linear guide rail 111 which is arranged on the cross beam 11 and extends along the length direction of the cross beam form a sliding guiding fit;

the second iron core coil 164 is disposed adjacent to and spaced apart from the second permanent magnet 112 disposed on the cross beam 11 and laid along the length direction thereof, and generates a magnetic force after the second iron core coil 164 is energized, so as to drive the laser cutting base plate 16 to move.

Further, in an embodiment of the present invention, the frame 10 includes a bottom supporting frame 101 and marble plates 102 disposed on both sides of the bottom supporting frame 101, and the first driving mechanism is disposed on the marble plates 102.

In the prior art, as the frame 10 mainly playing a supporting role, the side frame for mounting the driving assembly of the beam 11 is usually formed by welding metal plates, but certain errors may exist in the side frames at two sides during welding, and the errors may further increase in the subsequent use process, so that the deviation between the actual cutting position and the preset cutting position gradually occurs in the use process of the laser cutting equipment, and the quality of the finished glass product is affected; in the invention, the marble plates 102 are used on the two side edges of the frame 10, and the marble plates 102 are integrally designed along the length direction of the frame 10, so that manual splicing and welding line processing are avoided, and position deviation is avoided in subsequent use, so that the stability of the beam 11 in the front-back movement process in the use process is ensured, and the reliability of the laser cutting equipment in the working process is further ensured.

In a specific embodiment of the present invention, the laser mounting plate 1631 is further provided with a code printer 1635 for printing code on the glass 1.

The glass 1 is marked by the marking device 1635, so that the glass 1 can be conveniently used and stored for subsequent processing. As a specific embodiment of the code printer 1635, the code printer 1635 adopts a laser code printer, specifically, a small-sized and compact laser code printer can be selected to be conveniently mounted on the laser mounting plate 1631 to move along the laser mounting plate in the horizontal and vertical directions, and the laser code printer can specifically be, for example, Grace X-355-3/5 available from englo laser.

In the present invention, two ends of the frame 10 are provided with buffers 19 for buffering the beam 11. Through the arrangement of the buffer 19, the problem that the cross beam 11 is shifted out when moving to the two ends of the frame 10 is avoided; preferably, in order to improve the buffering effect, two buffers 19 are provided at each end of the frame 10, and are arranged at intervals in the vertical direction; one specific embodiment of the shock absorber 19 is a hydraulic shock absorber of yawauka ACA 3350-1.

According to the laser cutting device provided by the invention, the first turning mirror group 13 is used for transmitting the infrared laser energy emitted by the infrared laser 12 to the laser cutting head 1633 movably arranged on the cross beam 11 through a certain transmission path, so that a certain space is provided for arranging the infrared laser 12, the infrared laser 12 is arranged at a proper position on the cross beam 11, and when the laser cutting device is used specifically, the infrared laser 12 only moves along with the cross beam 11, does not vertically adjust the distance from the glass to be cut along with the laser cutting head 1633, and does not move along with the laser cutting head 1633 in the width direction of the frame 10, so that the stability of the infrared laser 12 in the using process is ensured.

In a specific embodiment of the present invention, the first turning mirror group 13 includes a first 90 ° outer optical path mirror group 131, a second 90 ° outer optical path mirror group 132, a third 90 ° outer optical path mirror group 133, and a fourth 90 ° outer optical path mirror group 134; the first 90-degree outer optical path mirror group 131 is disposed at a laser emission port of the infrared laser 12, and is configured to receive infrared laser energy and transmit the infrared laser energy to the second 90-degree outer optical path mirror group 132, and after receiving the infrared laser energy, the second 90-degree outer optical path mirror group 132 is transmitted to the first outer optical path mirror group 161 through the third 90-degree outer optical path mirror group 133 and the fourth 90-degree outer optical path mirror group 134.

In a specific embodiment of the present invention, in order to expand the diameter of the laser beam and reduce the divergence angle of the laser beam, a laser beam expander 135 is further disposed in the first turning mirror group 13.

In the present invention, the second turning mirror group 15 is used for turning CO₂The laser energy emitted by the laser 14 is transmitted to the second external optical path lens group 162, and further transmitted to the focusing lens 1634; to make CO into₂The laser 14 is arranged at a suitable location on the beam 11 and, in the specific use, the CO₂The laser 14 only moves along with the beam 11, does not vertically adjust the distance from the glass to be cut along with the focusing mirror 1634, and does not move along with the focusing mirror 1634 in the width direction of the frame 10, so that CO is ensured₂Stability of the laser 14 during use. In an embodiment of the present invention, the second turning mirror assembly 15 includes a 90 ° external optical path mirror assembly five 151 and a 90 ° external optical path mirror assembly six 152, and the 90 ° external optical path mirror assembly five 151 receives CO₂The laser light emitted by the laser 14 is transmitted to the second outer optical path lens group 162 through the 90 ° outer optical path lens group six 152.

The foregoing shows and describes the general principles, essential features, and inventive features of this invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. An integrated glass laser cutting device is characterized by comprising a frame (10), wherein the frame (10) is provided with a conveying surface for carrying glass (1) and conveying the glass forwards,

a cross beam (11) stretching across the conveying surface is arranged on the rack (10), and a first driving mechanism is arranged between two ends of the cross beam (11) and the rack (10) and used for driving the cross beam (11) to reciprocate along the conveying direction of the glass (1);

an infrared laser (12), a first catadioptric lens group (13) and CO are arranged on the beam (11)₂The laser cutting device comprises a laser (14), a second turning lens group (15) and a laser cutting seat plate (16), wherein the laser cutting seat plate (16) is driven by a second driving mechanism to reciprocate on a cross beam (11);

the laser cutting seat plate (16) is provided with a first outer light path lens group (161), a second outer light path lens group (162) and a laser cutting module group (163), the laser cutting module group (163) comprises a laser mounting plate (1631) and a servo motor (1632) for driving the laser mounting plate (1631) to reciprocate in the vertical direction,

the laser device mounting plate (1631) is provided with a laser cutting head (1633) and a focusing mirror (1634), the first outer optical path mirror group (161) can receive infrared laser energy of the first turning and folding mirror group (13) and transmit the infrared laser energy to the laser cutting head (1633), and the glass (1) on the conveying surface is subjected to laser cutting;

the second outer optical path lens group (162) can receive the laser energy of the second turning lens group (15) and transmit the laser energy to the focusing lens (1634).

2. The integrated glass laser cutting device according to claim 1, wherein the two ends of the cross beam (11) are respectively provided with an L-shaped support plate (20), one side of the L-shaped support plate (20) close to the machine frame (10) is provided with a first slide block (21), and the first slide block (21) and a first linear guide rail (17) which is arranged on the machine frame (10) and extends along the length direction of the machine frame form sliding guide fit;

one side that L type backup pad (20) are close to frame (10) still is equipped with first iron core coil (22), first iron core coil (22) and setting are close to the interval arrangement with first permanent magnet (18) that set up on frame (10) and lay along its length direction, and produce magnetic force after first iron core coil (22) circular telegram, drive L type backup pad (20) remove.

3. The integrated glass laser cutting apparatus according to claim 1, wherein the second driving mechanism comprises a second iron core coil (164) and a second slider (165) provided on the laser cutting base plate (16), the second slider (165) forming a sliding guiding fit with a second linear guide rail (111) provided on the cross beam (11) and arranged to extend along a length direction thereof;

the second iron core coil (164) is arranged close to and spaced from a second permanent magnet (112) which is arranged on the cross beam (11) and laid along the length direction of the cross beam, and magnetic force is generated after the second iron core coil (164) is electrified to drive the laser cutting seat plate (16) to move.

4. The integrated glass laser cutting apparatus according to claim 1, wherein the frame (10) includes a bottom support frame (101) and marble plates (102) disposed at both sides of the bottom support frame (101), the first driving mechanism being disposed on the marble plates (102).

5. The integrated glass laser cutting apparatus according to claim 1, wherein the laser mounting plate (1631) is further provided with a code printer (1635) for marking the glass (1).

6. The integrated glass laser cutting apparatus according to claim 1, wherein both ends of the machine frame (10) are provided with bumpers (19) for cushioning the cross beam (11).

7. The integrated glass laser cutting device according to claim 1, wherein the first turning mirror group (13) comprises a first 90 ° outer optical path mirror group (131), a second 90 ° outer optical path mirror group (132), a third 90 ° outer optical path mirror group (133) and a fourth 90 ° outer optical path mirror group (134);

the first 90-degree outer light path mirror group (131) is arranged at a laser emitting port of the infrared laser (12) and used for receiving infrared laser energy and transmitting the infrared laser energy to the second 90-degree outer light path mirror group (132), and the second 90-degree outer light path mirror group (132) receives the infrared laser energy and transmits the infrared laser energy to the first outer light path mirror group (161) through the third 90-degree outer light path mirror group (133) and the fourth 90-degree outer light path mirror group (134).

8. The integrated glass laser cutting apparatus according to claim 1, wherein a laser beam expander (135) is provided in the first turning mirror group (13).

9. The integrated glass laser cutting apparatus according to claim 1, wherein the second turning mirror group (15) comprises a 90 ° outer optical path mirror group five (151) and a 90 ° outer optical path mirror group six (152), the 90 ° outer optical path mirror group five (151) receiving CO₂The laser emitted by the laser (14) is transmitted to the second outer optical path lens group (162) through the 90-degree outer optical path lens group six (152).

10. A glass processing line having an integral laser cutting apparatus as claimed in any one of claims 1 to 9.

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