CN114163116A

CN114163116A - Large-breadth glass laser cutting equipment

Info

Publication number: CN114163116A
Application number: CN202111490384.6A
Authority: CN
Inventors: 李欣明
Original assignee: Suzhou Jinghai Laser Intelligent Technology Co ltd
Current assignee: Suzhou Jinghai Laser Intelligent Technology Co ltd
Priority date: 2021-12-08
Filing date: 2021-12-08
Publication date: 2022-03-11

Abstract

The invention provides large-breadth glass laser cutting equipment which comprises a laser cutting mechanism, a transplanting mechanism, a laser splitting mechanism and a blanking conveying belt, wherein the laser cutting mechanism, the transplanting mechanism, the laser splitting mechanism and the blanking conveying belt are sequentially arranged along a straight line; a transverse positioning plate and a transverse driving part for driving the transverse positioning plate to reciprocate are arranged on one side of the top of each of the cutting conveyer belt and the splitting conveyer belt in a sliding mode in parallel, and a longitudinal positioning plate and a longitudinal driving part for driving the longitudinal positioning plate to reciprocate are arranged at the output ends of each of the cutting conveyer belt and the splitting conveyer belt; according to the glass cutting device, the transverse positioning plate and the longitudinal positioning plate are arranged on the cutting conveying belt and the splitting conveying belt, so that the glass can be positioned in the laser cutting mechanism and the laser splitting mechanism in the transverse direction and the longitudinal direction through the transverse positioning plate and the longitudinal positioning plate, the consistent tracks of cutting and splitting are ensured, and the cutting quality is ensured.

Description

Large-breadth glass laser cutting equipment

Technical Field

The invention belongs to the technical field of glass processing equipment, and particularly relates to large-format glass laser cutting equipment.

Background

Present big breadth glass-cutting device structure is complicated, and degree of automation is not high, all needs the manual work to take out the glass lobe of a leaf tool after cutting in addition after processing and then carries out the product unloading, but because big and the weight of big breadth glass-cutting lobe of a leaf tool is heavier, manual operation is got up very inconveniently, and intensity of labour is great.

In the prior art, a chinese utility model patent with an authorized publication number of CN110563320A discloses a laser large-format glass cutting and splitting device, which comprises a first supporting platform, a feeding mechanism, a conveying mechanism, a laser cutting mechanism, a laser splitting mechanism and a discharging mechanism, wherein the feeding mechanism is arranged at one side of the first supporting platform, and comprises a conveying table and a conveying belt arranged at the upper end of the conveying table; the conveying mechanism, the laser cutting mechanism and the laser splinter mechanism are all arranged at the upper end of the first supporting platform, the conveying mechanism comprises a conveying beam and a material sucking disc capable of moving on the conveying beam, and the material sucking disc is provided with a plurality of suction nozzles; the laser cutting mechanism comprises a cutting bearing platform and a cutting laser head arranged above one end of the cutting bearing platform; the laser splinter mechanism comprises a splinter bearing platform and a splinter laser head arranged above one end of the splinter bearing platform; the blanking mechanism comprises a blanking track.

In the prior art, glass is placed through the cutting bearing seat and the splitting bearing seat, so that the glass cannot be accurately positioned, errors exist in the positions of the glass on the cutting mechanism and the splitting mechanism each time, the cutting track and the splitting track deviate, and the cutting of the glass is influenced.

Therefore, it is necessary to design a large-format glass laser cutting apparatus capable of accurately positioning glass to ensure the cutting quality of the glass, so as to solve the technical problems faced at present.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides large-breadth glass laser cutting equipment which can accurately position glass so as to ensure the cutting quality of the glass.

The technical scheme of the invention is as follows: the large-breadth glass laser cutting equipment comprises a laser cutting mechanism, a transplanting mechanism, a laser splitting mechanism and a blanking conveying belt which are sequentially arranged along a straight line; the laser cutting mechanism is provided with a cutting conveyer belt, a laser cutting head is arranged above the cutting conveyer belt, a cutting transverse moving mechanism for driving the cutting transverse moving mechanism to move along the direction vertical to the conveying direction of the cutting conveyer belt is arranged on the laser cutting head, and cutting longitudinal moving mechanisms for driving the cutting transverse moving mechanism to move along the conveying direction of the cutting conveyer belt are arranged at two ends of the cutting transverse moving mechanism; the laser lobe splitting mechanism is provided with a lobe splitting conveying belt, a laser lobe splitting head is arranged above the lobe splitting conveying belt, a lobe splitting transverse moving mechanism for driving the laser lobe splitting head to move along the direction vertical to the conveying direction of the lobe splitting conveying belt is arranged on the laser lobe splitting head, and lobe splitting longitudinal moving mechanisms for driving the laser lobe splitting head to move along the conveying direction of the lobe splitting conveying belt are arranged at two ends of the lobe splitting transverse moving mechanism; the top parts of the cutting conveyer belt and the splinter conveyer belt are provided with a transverse positioning plate and a transverse driving part for driving the transverse positioning plate to reciprocate in a sliding mode in parallel, and the output ends of the cutting conveyer belt and the splinter conveyer belt are provided with a longitudinal positioning plate and a longitudinal driving part for driving the longitudinal positioning plate to reciprocate.

Transplanting mechanism has the sucking disc mounting panel, the bottom of sucking disc mounting panel all is provided with transplants the sucking disc, the top of sucking disc mounting panel is provided with its elevating system who reciprocates of drive, the last transplanting sideslip mechanism that sets up of elevating system, the both ends of transplanting sideslip mechanism all are provided with transplants and indulge the mechanism that moves.

Isolation guardrails are uniformly arranged on the outer side of the transplanting mechanism.

The lifting mechanism is provided with a lifting box body, a lifting arm is arranged in the lifting box body in a sliding mode along the vertical direction, and a lifting motor for driving the lifting arm to move up and down is arranged on the lifting box body.

The laser cutting head reaches laser splitting head has sharp slip table, the sharp slip table is last to be equipped with the laser head, laser head one side the fixed trigger block that is provided with on the sharp slip table, be provided with on the sharp slip table with trigger block matched with first travel switch and second travel switch.

A laser head in the laser cutting head is connected with an infrared picosecond laser; and a laser head in the laser splitting head is connected with a carbon dioxide laser.

And a push plate is arranged at one end of the cutting conveying belt, which is close to the splitting conveying belt, and a material pushing cylinder for driving the push plate to move reversely along the splitting conveying belt is arranged on the push plate.

A first waste material collecting box is arranged below the laser splitting mechanism; the first waste collecting box is provided with a collecting box body and a handle arranged at one end of the collecting box body.

And second waste collecting boxes are arranged on two sides of one end, close to the laser splitting mechanism, of the blanking conveyor belt.

And finished product temporary storage platforms are arranged on two sides of the blanking conveying belt.

The invention has the beneficial effects that:

(1) in the invention, glass to be cut is conveyed to the top of a cutting conveyer belt, and a laser cutting head is driven by the cutting longitudinal moving mechanism and the cutting transverse moving mechanism to move according to a preset track to finish the cutting of the glass; after cutting, the cut glass is conveyed to the top of the laser splitting mechanism through the transplanting mechanism, the laser splitting head is driven by the splitting longitudinal moving mechanism and the splitting transverse moving mechanism to complete splitting of the glass according to a preset track, proportional cutting and splitting are automatically completed, labor is saved, and processing efficiency is improved;

(2) the cutting conveyer belt and the splitting conveyer belt are both provided with a transverse positioning plate and a longitudinal positioning plate, and the transverse positioning plate and the longitudinal positioning plate can realize the transverse and longitudinal positioning of glass in the laser cutting mechanism and the laser splitting mechanism, so that the consistent tracks of cutting and splitting are ensured, and the cutting quality is ensured.

Drawings

Fig. 1 is a schematic structural diagram of a large-format glass laser cutting apparatus according to the present invention.

Fig. 2 is a schematic structural diagram of a laser cutting mechanism according to the present invention.

FIG. 3 is a schematic structural diagram of a laser splinter mechanism according to the present invention.

Fig. 4 is a schematic structural view of the transplanting mechanism of the present invention.

Fig. 5 is a schematic structural view of the lifting mechanism of the present invention.

Fig. 6 is a partial enlarged view of a portion a in fig. 2.

FIG. 7 is a schematic view of the first waste collection cassette of the present invention.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. The description of the exemplary embodiments is merely illustrative and is in no way intended to limit the invention, its application, or uses. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. These embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. It should be noted that: the relative arrangement of parts and steps, the composition of materials, numerical expressions and numerical values set forth in these embodiments are to be construed as merely illustrative, and not as limitative, unless specifically stated otherwise.

The use of "first," "second," and similar terms in the present application do not denote any order, quantity, or importance, but rather the terms are used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element preceding the word covers the element listed after the word, and does not exclude the possibility that other elements are also covered. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

As shown in fig. 1 to 3, the large-format glass laser cutting device includes a laser cutting mechanism 1, a transplanting mechanism 2, a laser splitting mechanism 3 and a blanking conveyer belt 6, which are arranged in sequence along a straight line; the laser cutting mechanism 1 is provided with a cutting conveyer belt 101, a laser cutting head 102 is arranged above the cutting conveyer belt 101, a cutting transverse moving mechanism 104 for driving the cutting transverse moving mechanism to move along the direction vertical to the conveying direction of the cutting conveyer belt 101 is arranged on the laser cutting head 102, and cutting longitudinal moving mechanisms 103 for driving the cutting transverse moving mechanism 104 to move along the conveying direction of the cutting conveyer belt 101 are arranged at two ends of the cutting transverse moving mechanism 104; the laser splinter mechanism 3 is provided with a splinter conveying belt 301, a laser splinter head 302 is arranged above the splinter conveying belt 301, a splinter transverse moving mechanism 304 for driving the laser splinter head 302 to move along the direction vertical to the conveying direction of the splinter conveying belt 301 is arranged on the laser splinter head 302, and splinter longitudinal moving mechanisms 303 for driving the splinter transverse moving mechanism 304 to move along the conveying direction of the splinter conveying belt 301 are arranged at two ends of the splinter transverse moving mechanism 304; the cutting conveyer belt 101 and the splinter conveyer belt 301 are provided with a transverse positioning plate 8 and a transverse driving part for driving the transverse positioning plate 8 to reciprocate in a sliding manner on one side of the top, and the output ends of the cutting conveyer belt 101 and the splinter conveyer belt 301 are provided with a longitudinal positioning plate 9 and a longitudinal driving part for driving the longitudinal positioning plate 9 to reciprocate.

In this embodiment, the glass to be cut is conveyed to the top of the cutting conveyer 101, and the cutting head 102 is driven by the cutting longitudinal-moving mechanism 103 and the cutting transverse-moving mechanism 104 to move according to a preset track to complete the cutting of the glass; after cutting, the cut glass is conveyed to the top of the laser splitting mechanism 3 through the transplanting mechanism 2, and the laser splitting head 302 is driven by the splitting longitudinal moving mechanism 303 and the splitting transverse moving mechanism 304 to complete splitting of the glass according to a preset track, so that proportional cutting and splitting are automatically completed, labor is saved, and processing efficiency is improved; the cutting conveyer belt 101 and the splinter conveyer belt 301 are both provided with the transverse positioning plate 8 and the longitudinal positioning plate 9, the transverse positioning plate 8 and the longitudinal positioning plate 9 can realize the transverse and longitudinal positioning of the glass in the laser cutting mechanism 1 and the laser splinter mechanism 3, the consistent tracks of cutting and splinter are ensured, and the cutting quality is ensured.

In the above embodiment, one side of the transverse positioning plate 8 is slidably connected with the frame of the conveyor belt through a guide rod, the transverse driving component is a cylinder fixed on the frame and driving the transverse positioning plate 8 to move along the direction perpendicular to the conveying direction of the conveyor belt, the cylinder drives the longitudinal positioning plate 8 to move and clamp the glass, and the glass is positioned in the transverse direction, so that the position of the glass in the transverse direction is fixed; the longitudinal driving part is an air cylinder fixed on the output end rack of the conveying belt, the longitudinal positioning plate 9 is driven to reciprocate by the air cylinder, the air cylinder extends out of the longitudinal positioning plate 9 to be extended out, and a stopping limit is formed on one end of glass on the conveying belt to ensure that the position of the glass in the longitudinal direction is fixed; through horizontal and vertical spacing to glass, can guarantee that glass is fixed in the position at conveyer belt top, and then guarantee that the orbit of cutting and lobe of a leaf is unanimous.

As a specific embodiment of the transplanting mechanism, as shown in fig. 4, the transplanting mechanism 2 has a suction cup mounting plate 204, transplanting suction cups 203 are disposed at the bottoms of the suction cup mounting plates 204, a lifting mechanism 205 for driving the sucking cup mounting plate 204 to move up and down is disposed at the top of the suction cup mounting plate 204, a transplanting traverse mechanism 205 is disposed on the lifting mechanism 205, transplanting longitudinal moving mechanisms 201 are disposed at both ends of the transplanting traverse mechanism, the transplanting suction cups 203 are used for adsorbing and fixing the cut glass, after the transplanting suction cups 203 adsorb, the suction cup mounting plate 204 is lifted up by the lifting mechanism 205, the suction cup mounting plate 204 sucks up the glass by the transplanting suction cups 203, and the glass is moved by the transplanting mechanism 201 and the transplanting traverse mechanism 202 according to a preset path, so that the glass can be transported from the laser cutting mechanism 1 to the top of the laser splitting mechanism 3.

Further, transplant the outside of mechanism 2 and evenly be provided with isolation barrier 207, isolation barrier pass through expansion bolts fixed with ground, can avoid personnel to get into through isolation barrier 207 and transplant mechanism 2 in, cause the damage.

In the above embodiments, the cutting longitudinal moving mechanism 103, the cutting transverse moving mechanism 104, the splitting transverse moving mechanism 304, the splitting longitudinal moving mechanism 303, the transplanting longitudinal moving mechanism 201, and the transplanting transverse moving mechanism are all linear moving mechanisms, and a large number of related technologies are disclosed in the prior art, for example, linear sliding tables can be used for the transplanting transverse moving mechanism 202, the cutting transverse moving mechanism 104, and the splitting transverse moving mechanism 304, the transplanting longitudinal moving mechanism 201, the cutting longitudinal moving mechanism 103, and the splitting longitudinal moving mechanism 303 all have racks fixed on the top of the frames at both sides of the conveyor belt, the end of the transverse moving mechanism is slidably connected with the frames through sliding rail sliders, a gear meshed with the rack and a speed reducing motor driving the gear to rotate are arranged on the transverse moving mechanism, and the gear is driven by the speed reducing motor to drive the gear to move in the same direction as the conveyor belt in cooperation with the rack.

Further, as shown in fig. 5, the lifting mechanism has a lifting box 2052, a lifting arm 2051 is slidably disposed inside the lifting box 2052 along a vertical direction, a lifting motor 2053 for driving the lifting arm 2051 to move up and down is disposed on the lifting box 2052, a rack is disposed in the middle of the lifting arm 2051, a gear engaged with the rack is assembled at an output end of the lifting motor 2053, the lifting motor 2053 drives the gear to rotate forward and backward, and then drives the rack to drive the lifting arm 2051 to move up and down, so as to complete lifting and lowering of the glass, wherein the lifting motor 2053 is a speed reduction motor.

As a specific embodiment of the laser cutting head 102 and the laser splitting head 302, as shown in fig. 6, the laser cutting head 102 and the laser splitting head 302 have a linear sliding table 22, a laser head 21 is assembled on the linear sliding table 22, a trigger block 23 is fixedly arranged on the linear sliding table 22 on one side of the laser head 21, a first travel switch 24 and a second travel switch 25 which are matched with the trigger block 23 are arranged on the linear sliding table 22, the laser head 21 is driven by the linear sliding table 22 to move up and down, the laser head 21 can be driven to move down to be close to glass when cutting or splitting is performed, in order to control the position of the laser head 21, the trigger block 23 just triggers the second travel switch 25 when the laser head 21 moves down to a certain position, and the trigger block 23 just triggers the first travel switch 24 when the laser head 21 moves up to a certain position.

More specifically, a laser head in the laser cutting head 102 is connected with an infrared picosecond laser; the laser head in the laser splitting head 302 is connected with a carbon dioxide laser, and the carbon dioxide laser is a gas laser using carbon dioxide gas as a working substance. The discharge vessel is usually made of glass or quartz material and is filled with carbon dioxide gas and other auxiliary gases (mainly helium and nitrogen, and usually a small amount of hydrogen or xenon); the electrodes are generally hollow cylinders made of nickel; one end of the resonant cavity is a gold-plated total reflector, and the other end is a partial reflector ground by germanium or gallium arsenide.

Further, as shown in fig. 2, a push plate 10 is disposed at one end of the cutting conveyer belt 101 close to the splinter conveyer belt 301, a material pushing cylinder 12 for driving the push plate 10 to move in the reverse direction along the splinter conveyer belt 301 is disposed on the push plate 10, the push plate 10 is assembled on the material pushing cylinder 12 through a push plate support 11, and the push plate 10 can be driven by the material pushing cylinder 12 to move towards the splinter conveyer belt 301 to push the glass towards the splinter conveyer belt 301.

In order to facilitate the collection and treatment of the cut waste materials, a first waste material collecting box 4 is arranged below the laser splitting mechanism 3, and specifically, the first waste material collecting box 4 is uniformly distributed below the laser splitting mechanism 3; as shown in fig. 7, the first scrap collecting box 4 includes a collecting box body 401 and a handle 402 provided at one end of the collecting box body 401, and the first scrap collecting box 4 can be easily drawn out from below the laser cleaving mechanism 3 by the handle 402 to collect and dispose the scraps therein in a unified manner.

Furthermore, a second waste collecting box 5 is arranged on each of two sides of one end, close to the laser splitting mechanism 3, of the blanking conveying belt 6, and waste conveyed from the splitting conveying belt 301 is collected uniformly through the second waste collecting box 5.

Further, finished product temporary storage platform 7 is arranged on both sides of the blanking conveying belt 6, and after glass cutting is finished, the finished product temporary storage platform 7 is manually conveyed to the top of the finished product temporary storage platform 7, and a certain amount of finished product is collected and then conveyed in a unified mode.

Thus, various embodiments of the present invention have been described in detail. Some details well known in the art have not been described in order to avoid obscuring the concepts of the present invention. It will be fully apparent to those skilled in the art from the foregoing description how to practice the presently disclosed embodiments.

The above-mentioned embodiments only express some embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. The large-breadth glass laser cutting equipment is characterized by comprising a laser cutting mechanism, a transplanting mechanism, a laser splitting mechanism and a blanking conveying belt which are sequentially arranged along a straight line;

the laser cutting mechanism is provided with a cutting conveyer belt, a laser cutting head is arranged above the cutting conveyer belt, a cutting transverse moving mechanism for driving the cutting transverse moving mechanism to move along the direction vertical to the conveying direction of the cutting conveyer belt is arranged on the laser cutting head, and cutting longitudinal moving mechanisms for driving the cutting transverse moving mechanism to move along the conveying direction of the cutting conveyer belt are arranged at two ends of the cutting transverse moving mechanism;

the laser lobe splitting mechanism is provided with a lobe splitting conveying belt, a laser lobe splitting head is arranged above the lobe splitting conveying belt, a lobe splitting transverse moving mechanism for driving the laser lobe splitting head to move along the direction vertical to the conveying direction of the lobe splitting conveying belt is arranged on the laser lobe splitting head, and lobe splitting longitudinal moving mechanisms for driving the laser lobe splitting head to move along the conveying direction of the lobe splitting conveying belt are arranged at two ends of the lobe splitting transverse moving mechanism;

the top parts of the cutting conveyer belt and the splinter conveyer belt are provided with a transverse positioning plate and a transverse driving part for driving the transverse positioning plate to reciprocate in a sliding mode in parallel, and the output ends of the cutting conveyer belt and the splinter conveyer belt are provided with a longitudinal positioning plate and a longitudinal driving part for driving the longitudinal positioning plate to reciprocate.

2. The large format glass laser cutting apparatus of claim 1, wherein: transplanting mechanism has the sucking disc mounting panel, the bottom of sucking disc mounting panel all is provided with transplants the sucking disc, the top of sucking disc mounting panel is provided with its elevating system who reciprocates of drive, the last transplanting sideslip mechanism that sets up of elevating system, the both ends of transplanting sideslip mechanism all are provided with transplants and indulge the mechanism that moves.

3. The large format glass laser cutting apparatus of claim 2, wherein: isolation guardrails are uniformly arranged on the outer side of the transplanting mechanism.

4. The large format glass laser cutting apparatus of claim 2, wherein: the lifting mechanism is provided with a lifting box body, a lifting arm is arranged in the lifting box body in a sliding mode along the vertical direction, and a lifting motor for driving the lifting arm to move up and down is arranged on the lifting box body.

5. The large format glass laser cutting apparatus of claim 1, wherein: the laser cutting head reaches laser splitting head has sharp slip table, the sharp slip table is last to be equipped with the laser head, laser head one side the fixed trigger block that is provided with on the sharp slip table, be provided with on the sharp slip table with trigger block matched with first travel switch and second travel switch.

6. The large format glass laser cutting apparatus of claim 5, wherein: a laser head in the laser cutting head is connected with an infrared picosecond laser; and a laser head in the laser splitting head is connected with a carbon dioxide laser.

7. The large format glass laser cutting apparatus of claim 1, wherein: and a push plate is arranged at one end of the cutting conveying belt, which is close to the splitting conveying belt, and a material pushing cylinder for driving the push plate to move reversely along the splitting conveying belt is arranged on the push plate.

8. The large format glass laser cutting apparatus of claim 1, wherein: a first waste material collecting box is arranged below the laser splitting mechanism; the first waste collecting box is provided with a collecting box body and a handle arranged at one end of the collecting box body.

9. The large format glass laser cutting apparatus of claim 1, wherein: and second waste collecting boxes are arranged on two sides of one end, close to the laser splitting mechanism, of the blanking conveyor belt.

10. The large format glass laser cutting apparatus of claim 1, wherein: and finished product temporary storage platforms are arranged on two sides of the blanking conveying belt.