CN115626770A

CN115626770A - Cutting edging system for optical glass production

Info

Publication number: CN115626770A
Application number: CN202211252913.3A
Authority: CN
Inventors: 刘青龙; 王震; 汤进强
Original assignee: Anhui Dacheng Intelligent Glass Co Ltd
Current assignee: Anhui Dacheng Intelligent Glass Co Ltd
Priority date: 2022-10-13
Filing date: 2022-10-13
Publication date: 2023-01-20
Anticipated expiration: 2042-10-13
Also published as: CN115626770B

Abstract

The invention relates to a cutting and edging system for optical glass production, which comprises a working platform, wherein a first conveying belt and a second conveying belt are installed on an installation guide rail, a breaking frame is installed on the working platform and positioned between the first conveying belt and the second conveying belt, a supporting cross rod is installed on one side of the upper end of a second vertical rod and positioned right above the breaking frame, a first pressing block and a second pressing block are installed at the telescopic end of a second electric push rod, a stepping motor is installed on the first electric sliding table, a supporting rotating frame is installed at the end part of a driving shaft of the stepping motor, a double-shaft electric sliding table is installed on one side, close to the first electric sliding table, of the working platform, a supporting top frame is installed on one side, close to the double-shaft electric sliding table, a third electric push rod is installed on the double-shaft electric sliding table, an edging machine is installed at the telescopic end of the third electric push rod, the length of each glass plate cut by a glass cutter is kept to be the distance between the glass cutter and the breaking frame, and the glass plates with fixed length can be continuously and accurately obtained.

Description

Cutting and edging system for optical glass production

Technical Field

The invention relates to the technical field of glass production equipment, in particular to a cutting and edging system for optical glass production.

Background

The glass is an amorphous inorganic non-metallic material, and is cut according to requirements in the production process of the glass, and the cut edge of the glass needs to be subjected to edging treatment through a cutting edging system after the glass is cut.

Patent document CN112092200A discloses a cutting and edging integrated device for glass production, and particularly relates to the technical field of glass production equipment. The glass cutting machine comprises a conveying belt, a clamping mechanism, a fixed platform, a first moving mechanism, a cutting platform, a conveying roller way, a polishing mechanism, a connecting rod, a lifting mechanism and a second moving mechanism, wherein the fixed platform is fixed on a supporting frame, the first moving mechanism is arranged on the fixed platform, the cutting platform is arranged on one side of the discharging end of the conveying belt, the cutting mechanism is arranged on the first moving mechanism and extends to the position right above the cutting platform, the conveying roller way is arranged on one side, far away from the conveying belt, of the cutting platform, the lifting mechanisms are arranged on two sides of the conveying roller way, the polishing mechanism is connected with the lifting mechanism through the connecting rod, the second moving mechanism is arranged above the conveying roller way, and the glass cutting machine has the beneficial effects that polishing after glass cutting can be realized through the integrated arrangement of cutting and edge polishing, manual transfer is not needed, and the working efficiency and safety are greatly improved.

Above-mentioned device exists following not enough, and above-mentioned device cuts glass through rotating the blade when using, and the incision is coarse and lead to thin glass board to take place cracked and bursting apart easily, greatly influences product quality, and the working effect is not good, and above-mentioned device can not adapt the glass board of different size and dimension when carrying out the edging to the glass board, to the pressure at glass board edge when can not control the edging, and can not adapt the edge shape of glass board, and the edging effect is not good.

Disclosure of Invention

The invention aims to provide a cutting and edging system for producing optical glass, aiming at the problems and the defects, and improving the overall working efficiency.

The technical problem solved by the invention is as follows:

(1) When the device is used, the glass is cut by rotating the blade, the cut is rough, and the thin glass plate is easy to crack and break, so that the product quality is greatly influenced, and the working effect is poor;

(2) The device can not adapt to glass plates with different sizes when edging the glass plates, can not control the pressure at the edge of the glass plates when edging the glass plates, can not adapt to the edge shapes of the glass plates, and has poor edging effect.

The purpose of the invention can be realized by the following technical scheme: the utility model provides an optical glass production is with cutting edging system, including work platform, the installation guide rail is installed to work platform's upper surface one side, work platform's upper surface opposite side installs first electric slip table, install first conveyer belt and second conveyer belt on the installation guide rail, work platform is last and be located to install between first conveyer belt and the second conveyer belt and break disconnected frame off with the fingers and thumb, work platform is last and be located to break disconnected one side of frame off with the fingers and thumb and install the second montant, upper end one side of second montant just is located and installs the support horizontal pole directly over breaking disconnected frame off with the fingers and thumb, the middle part downside that supports the horizontal pole installs second electric push rod, first briquetting and second briquetting are installed to the flexible end of second electric push rod, install step motor on the first electric slip table, step motor's drive shaft tip is installed and is supported the revolving rack, work platform is last to be close to one side of first electric slip table and to install the biax electric slip table, the last support roof frame of just being close to one side of edging of work platform, install third electric push rod, the flexible end is installed the machine.

As a further scheme of the invention, a supporting chassis is arranged in the first conveyor belt, and the top of the supporting chassis is abutted against the inner side of the belt surface of the first conveyor belt.

As a further scheme of the invention, a second electric sliding table is arranged on one side, close to the first conveyor belt, of the working platform, a first vertical rod is arranged on the second electric sliding table, a supporting guide rail is arranged on one side of the upper end of the first vertical rod and above the first conveyor belt, a linear motor is arranged on the supporting guide rail, a first electric push rod is arranged at the bottom of the linear motor, and a glass cutter is arranged at the telescopic end of the first electric push rod.

As a further scheme of the invention, a top piezoelectric push rod is arranged in the middle of the upper end of the supporting top frame and right above the first electric sliding table, and a telescopic end of the top piezoelectric push rod is rotatably connected with a top pressing plate.

As a further scheme of the invention, one side of the middle part of the second vertical rod, which is close to the breaking-off frame, is fixedly connected with a positioning probe for positioning and detecting the end part of the glass plate.

As a further scheme of the invention, a first spring is arranged at the bottom of the first pressing block, a third pressing block is arranged at the lower end of the first spring, and a separation lug is fixedly connected to one side, away from the first pressing block, of the end face of the bottom of the second pressing block.

As a further proposal of the invention, the length of the first spring is twice of that of the second pressing block, and the lower surface of the third pressing block is higher than that of the second pressing block when the first spring is compressed.

As a further scheme of the invention, the top of the breaking-off frame is fixedly connected with a material guide stay bar for bearing the glass plate, and one side of the material guide stay bar, which is close to the second conveyor belt, is fixedly connected with a material guide inclined plate.

As a further scheme of the invention, the upper surface of the material guiding support rod is flush with the upper surface of the first conveyor belt, the height of the belt surface of the first conveyor belt is higher than that of the belt surface of the second conveyor belt, the length of the material guiding support rod is consistent with that of the first conveyor belt, and the lower end of the material guiding inclined plate is abutted against one end of the belt surface of the second conveyor belt.

As a further scheme, the middle part of the supporting rotating frame is provided with an installation groove and is provided with a plurality of equally-spaced and uniformly-distributed material guide rollers, two ends of a rotating shaft of each material guide roller are fixedly connected with connecting blocks, the lower ends of the connecting blocks are fixedly connected with transmission blocks, the upper sides of two ends of each transmission block are fixedly connected with second springs, and the upper ends of the second springs are fixedly connected with the supporting rotating frame.

The invention has the beneficial effects that:

(1) Moving a glass plate through a first conveyor belt, temporarily stopping the first conveyor belt, moving a glass cutter through a first electric push rod and a linear motor by the aid of a positioning probe, scoring the glass plate under the support of a support chassis on the first conveyor belt, and then enabling a scoring line carved on the glass plate through the glass cutter to be just above a breaking frame by the aid of the positioning probe, so that the length of each glass plate scored by the glass cutter is kept to be the distance between the glass cutter and the breaking frame, moving a first vertical rod through a second electric sliding table, so as to adjust the distance between the glass cutter and the breaking frame, moving a first pressing block and a second pressing block through a second electric push rod when a scoring part moves to be just above the breaking frame, and pressing one side of a separation groove cut out by the glass cutter on the glass plate through a third pressing block first, the third pressing block is matched with the breaking frame to clamp the column glass plate, so that the glass plate is fixed in length and fixed, then the second electric push rod continues to press downwards, the second pressing block pushes the separation lug to abut against the other side of the separation groove on the glass plate and enables the glass plate to be bent, so that the glass plate is broken by taking the separation groove as a boundary, the broken and separated glass plate is continuously conveyed along with the second conveying belt, the third pressing block bears the pressure of the first spring and clamps the glass plate together with the guide support rod, the stability of the glass plate in the breaking process is kept, the yield is improved, after the second pressing block pushes the separation lug to press the glass plate, the broken and separated glass plate is guided and supported by the guide inclined plate, so that the glass plate is prevented from being loosened and separated from the second conveying belt in a reverse inclination manner during breaking separation, and the second electric push rod is contracted, the glass plates are continuously pressed, broken and separated on the breaking-off frame, and the separated glass plates are moved to the supporting rotating frame through the second conveying belt, so that the glass plates with fixed length are continuously and accurately separated;

(2) When the second conveying belt conveys the glass plate with the fixed length to the supporting rotating frame, the glass plate is in friction butt with the material guide rollers, then each material guide roller synchronously operates to move the glass plate to the position right above the supporting rotating frame, then the first electric sliding table moves the stepping motor with the glass plate to the position right below the jacking electric push rod, the jacking electric push rod moves the jacking plate downwards to enable the jacking plate and the supporting rotating frame to clamp the glass plate, and under the stretching of the second spring, the upper side of the material guide roller downwards moves to enable the glass plate to be in butt joint with the upper surface of the supporting rotating frame, so that the stability of the glass plate during polishing is kept.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a front view of the overall structure of the present invention;

FIG. 2 is a top view of the overall structure of the present invention;

FIG. 3 is an enlarged view of area A of FIG. 1;

FIG. 4 is an enlarged schematic view of region B of FIG. 1;

in the figure: 1. a working platform; 2. installing a guide rail; 3. a first conveyor belt; 4. a support chassis; 5. a first vertical bar; 6. supporting the guide rail; 7. a linear motor; 8. a first electric push rod; 9. a glass cutter; 10. a second vertical bar; 11. a support rail; 12. a second electric push rod; 13. breaking off the frame; 14. a second conveyor belt; 15. a first electric slide table; 16. a stepping motor; 17. supporting the rotating frame; 18. supporting the top frame; 19. pushing the electric push rod; 20. a top pressing plate; 21. a double-shaft electric sliding table; 22. a third electric push rod; 23. an edge grinding machine; 24. a second electric slide table; 25. a first pressing block; 26. a second pressing block; 27. separating the bumps; 28. a first spring; 29. a third pressing block; 30. positioning a probe; 31. a material guiding inclined plate; 32. a material guiding support rod; 33. a material guide roller; 34. connecting blocks; 35. a transmission block; 36. a second spring.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description of the embodiments, structures, characteristics and effects according to the present invention will be made with reference to the accompanying drawings and preferred embodiments.

Please refer to fig. 1-4: a cutting and edging system for optical glass production comprises a working platform 1, wherein one side of the upper surface of the working platform 1 is provided with an installation guide rail 2, the other side of the upper surface of the working platform 1 is provided with a first electric sliding table 15, one side of the installation guide rail 2 is provided with a first conveying belt 3, the other side of the installation guide rail 2 is provided with a second conveying belt 14, a supporting underframe 4 is arranged inside the first conveying belt 3, and the top of the supporting underframe 4 is abutted against the inner side of the belt surface of the first conveying belt 3;

a second electric sliding table 24 is arranged on one side, close to the first conveyor belt 3, of the working platform 1, a first vertical rod 5 is arranged on the second electric sliding table 24, a supporting guide rail 6 is arranged on one side of the upper end of the first vertical rod 5 and above the first conveyor belt 3, a linear motor 7 is arranged on the supporting guide rail 6, a first electric push rod 8 is arranged at the bottom of the linear motor 7, the first electric push rod 8 is vertically downward, and a glass cutter 9 is arranged at the telescopic end of the first electric push rod 8;

a breaking frame 13 is arranged on the working platform 1 and between the first conveyor belt 3 and the second conveyor belt 14, a second vertical rod 10 is arranged on one side of the breaking frame 13 on the working platform 1, a supporting cross rod 11 is arranged on one side of the upper end of the second vertical rod 10 and right above the breaking frame 13, a second electric push rod 12 is arranged on the lower side of the middle part of the supporting cross rod 11, the second electric push rod 12 is vertically downward, and a first pressing block 25 and a second pressing block 26 are arranged at the telescopic end of the second electric push rod 12;

a stepping motor 16 is installed on the first electric sliding table 15, the stepping motor 16 is vertically upward, a supporting rotating frame 17 for bearing an optical glass plate is installed at the end part of a driving shaft of the stepping motor 16, a double-shaft electric sliding table 21 is installed on one side, close to the first electric sliding table 15, of the working platform 1, a supporting top frame 18 is installed on one side, close to the double-shaft electric sliding table 21, of the working platform 1, a third electric push rod 22 is installed on the double-shaft electric sliding table 21, the third electric push rod 22 is horizontal and points at the first electric sliding table 15, an edge grinding machine 23 is installed at the telescopic end of the third electric push rod 22, a top pressure electric push rod 19 is installed in the middle of the upper end of the supporting top frame 18 and located right above the first electric sliding table 15, the top pressure electric push rod 19 is vertically downward, and the telescopic end of the top pressure electric push rod 19 is rotatably connected with a top pressure plate 20;

one side of the middle part of the second vertical bar 10 close to the breaking-off frame 13 is fixedly connected with a positioning probe 30 for positioning and detecting the end part of the glass plate, when the end part of the glass plate and the scribing trace of the glass cutter 9 pass through the positioning probe 30, the positioning probe 30 immediately sends a pause signal, so that the first conveyor belt 3 is paused, and the scribing and the dividing of the glass plate with equal length are assisted.

In operation, the end of a glass plate is placed on the first conveyor belt 3, the glass plate is conveyed through the first conveyor belt 3, the first vertical rod 5 is moved through the second electric sliding table 24, so as to adjust the distance between the glass cutter 9 and the breaking frame 13, then the glass plate is moved through the first conveyor belt 3, the first conveyor belt 3 is assisted by the positioning probe 30 to convey the glass plate, one end of the glass plate is just above the breaking frame 13 through the assistance of the positioning probe 30, then the first conveyor belt 3 is temporarily stopped and the glass cutter 9 is moved through the first electric push rod 8 and the linear motor 7, the glass plate is scribed under the support of the first conveyor belt 3 by the support chassis 4, then the scribe line scribed on the glass plate by the glass cutter 9 is just above the breaking frame 13 through the assistance of the positioning probe 30, so as to keep the length of each glass plate scribed by the glass cutter 9 equal to the distance between the glass cutter 9 and the breaking frame 13, then when the scribe line moves to the position just above the breaking frame 13, the second electric push rod 12 moves to precisely press the press block 23 and the press the glass plate moves to separate the glass plate by the third electric sliding table 16, and the glass plate 14, and the electric press the glass plate moves to grind the glass plate, and the press the glass plate.

When the glass cutting machine works, when the second electric push rod 12 presses the first press block 26 downwards, the third press block 29 firstly presses one side of the separation groove cut by the glass cutter 9 on the glass plate, the third press block 29 is matched with the breaking frame 13 to clamp the cylindrical glass plate so as to fix the length of the glass plate, then the second electric push rod 12 continues to press downwards, the second press block 26 pushes the separation bump 27 to abut against the push rod of the separation groove on the other side of the glass plate, the glass plate is bent, so that the glass plate is separated into a glass separation groove, a glass separation belt is cut into a glass separation groove, and the glass separation belt is continuously pressed on the second electric push rod 12, so that the glass plate is continuously conveyed and accurately, and the glass plate is continuously conveyed along with the second electric conveying frame 13, and is continuously and continuously separated along with the second electric conveying belt 13, and the separation bump 27 is fixedly conveyed on the glass plate when the first press block 25, the second press 26, the third block 29 presses one side of the separation groove cut by the glass cutter 9 on the glass plate.

The top of the breaking-off frame 13 is fixedly connected with a material guide support rod 32 for bearing a glass plate, the upper surface of the material guide support rod 32 is flush with the upper surface of the first conveyor belt 3, the belt surface height of the first conveyor belt 3 is higher than that of the second conveyor belt 14, the length of the material guide support rod 32 is consistent with that of the first conveyor belt 3, one side of the material guide support rod 32, which is close to the second conveyor belt 14, is fixedly connected with a material guide inclined plate 31, and the lower end of the material guide inclined plate 31 is abutted against one end of the belt surface of the second conveyor belt 14;

in operation, the third pressing block 29 is pressed by the first spring 28 and clamps the glass plate together with the guide support rod 32, so that the stability of the glass plate in the breaking process is maintained, the yield is improved, and after the second pressing block 26 pushes the separation bump 27 to push the glass plate, the broken and separated glass plate is guided and supported by the guide inclined plate 31, so that the glass plate is prevented from being loosened and separated from the second conveyor belt 14 due to reverse inclination when being broken and separated, and the glass plate with each fixed length is stably guided and conveyed.

The middle part of the supporting rotating frame 17 is provided with a mounting groove and is provided with a plurality of equally-spaced and uniformly-distributed material guide rollers 33, two ends of a rotating shaft of each material guide roller 33 are fixedly connected with connecting blocks 34, the lower end of each connecting block 34 is fixedly connected with a transmission block 35, the upper sides of two ends of each transmission block 35 are fixedly connected with second springs 36, and the upper ends of the second springs 36 are fixedly connected with the supporting rotating frame 17;

during operation, when the second conveyor belt 14 conveys a glass plate with a fixed length onto the supporting rotating frame 17, the glass plate is in frictional abutment with the material guiding rollers 33, then each material guiding roller 33 operates synchronously to move the glass plate to be right above the supporting rotating frame 17, then the first electric sliding table 15 moves the stepping motor 16 with the glass plate to be right below the jacking electric push rod 19, the jacking electric push rod 19 moves the jacking plate 20 downwards to enable the jacking plate 20 and the supporting rotating frame 17 to clamp the glass plate, and under the extension of the second spring 36, the upper side of the material guiding roller 33 moves downwards to enable the glass plate to be in abutment with the upper surface of the supporting rotating frame 17, so that the stability of the glass plate during polishing is maintained, during edge polishing, the stepping motor 16 cooperates with the edge polishing machines 23 to move the periphery of the glass plate to the output end of the edge polishing machine 23, then the horizontal vertical direction movement of the edge polishing machine 23 is controlled by the double-shaft electric sliding table 21, and the jacking pressure degree of the edge of the glass plate is controlled by the third electric push rod 22 to control machine 23, so that the edge of the glass plate is polished accurately, thereby improving the quality of the edge.

When the glass plate cutting machine is used, a worker places the end part of a glass plate on the first conveyor belt 3, moves the glass plate through the first conveyor belt 3, positions one end of the glass plate right above the breaking-off frame 13 with the assistance of the positioning probe 30, stops the first conveyor belt 3, moves the glass cutter 9 through the first electric push rod 8 and the linear motor 7, scores the glass plate under the support of the first conveyor belt 3 by the support chassis 4, then positions the dividing line scribed by the glass cutter 9 on the glass plate right above the breaking-off frame 13 with the assistance of the positioning probe 30, so that the length of each glass plate scored by the glass cutter 9 is kept to be the distance between the glass cutter 9 and the breaking-off frame 13, moves the first vertical rod 5 through the second electric sliding table 24, and adjusts the distance between the glass cutter 9 and the breaking-off frame 13, when the scribing part moves to the position right above the breaking-off frame 13, the second electric push rod 12 moves the first press block 25 and the second press block 26, the third press block 29 firstly pushes one side of the separation groove cut by the glass cutter 9 on the glass plate, the third press block 29 is matched with the breaking-off frame 13 to clamp the column glass plate, so that the glass plate is fixed in length and fixed, then the second electric push rod 12 continues to press downwards, the second press block 26 pushes the separation bump 27 to be abutted against the other side of the separation groove on the glass plate, and the glass plate is bent, so that the glass plate is broken by taking the separation groove as a boundary, the broken and separated glass plate is continuously conveyed along with the second conveyor belt 14, the third press block 29 is pressed by the first spring 28 and clamped by the guide support rod 32, the stability of the glass plate in the breaking process is kept, the yield is improved, after the second press block 26 pushes the separation bump 27 to push the glass plate, the broken and separated glass plates are guided and supported by the guide inclined plate 31, so that the glass plates are prevented from being loosened and separated from the second conveyor belt 14 in a reverse inclined manner during breaking and separation, and meanwhile, the second electric push rod 12 is contracted, so that the glass plates are continuously pressed and broken and separated on the breaking frame 13 and are moved to the support rotating frame 17 through the second conveyor belt 14, and the glass plates with fixed length are continuously and accurately separated;

when the second conveyor belt 14 conveys the glass plate with a fixed length to the supporting rotating frame 17, the glass plate is in friction butt joint with the material guiding rollers 33, then each material guiding roller 33 synchronously operates to move the glass plate to be right above the supporting rotating frame 17, then the first electric sliding table 15 moves the stepping motor 16 with the glass plate to be right below the jacking piezoelectric push rod 19, the jacking piezoelectric push rod 19 moves the jacking plate 20 downwards to enable the jacking plate 20 and the supporting rotating frame 17 to clamp the glass plate, under the extension of the second spring 36, the upper side of the material guiding roller 33 moves downwards to enable the glass plate to be in butt joint with the upper surface of the supporting rotating frame 17, so that the stability of the glass plate during polishing is kept, during polishing, the stepping motor 16 is matched with the edge polishing machine 23 to move each part of the periphery of the glass plate to the output end of the edge polishing machine 23, then the double-shaft electric sliding table 21 controls the horizontal vertical direction movement of the edge polishing machine 23, and the third electric push rod 22 controls the edge-pressing degree of the edge polishing machine 23 to polish the edge of the glass plate, so as to precisely polish the periphery of the glass plate and improve the quality of the edge.

Although the present invention has been described with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the present invention.

Claims

1. The cutting and edging system for optical glass production is characterized by comprising a working platform (1), an installation guide rail (2) is installed on one side of the upper surface of the working platform (1), a first electric sliding table (15) is installed on the other side of the upper surface of the working platform (1), a first conveying belt (3) and a second conveying belt (14) are installed on the installation guide rail (2), a second vertical rod (10) is installed on one side of the first conveying belt (3) and the second conveying belt (14), a support transverse rod (11) is installed on one side of the upper end of the second vertical rod (10) and is positioned right above the first conveying belt (3) and the second conveying belt (14), a second electric push rod (12) is installed on the lower side of the middle part of the support transverse rod (11), a first pressing block (25) and a second pressing block (26) are installed at the telescopic end of the second electric push rod (12), a stepping motor (16) is installed on the first electric sliding table (15), the end part of the stepping motor (16) is installed on the end part of the support transverse rod (1), and is close to one side of the electric sliding table (21), a third electric push rod (22) is installed on the double-shaft electric sliding table (21), and an edge grinding machine (23) is installed at the telescopic end of the third electric push rod (22).

2. The cutting and edging system for producing optical glass according to claim 1, wherein a supporting chassis (4) is mounted inside the first conveyor belt (3), and the top of the supporting chassis (4) abuts against the inner side of the belt surface of the first conveyor belt (3).

3. The cutting and edging system for producing optical glass according to claim 1, wherein a second electric sliding table (24) is mounted on one side of the working platform (1) close to the first conveyor belt (3), a first vertical rod (5) is mounted on the second electric sliding table (24), a support guide rail (6) is mounted on one side of the upper end of the first vertical rod (5) and above the first conveyor belt (3), a linear motor (7) is mounted on the support guide rail (6), a first electric push rod (8) is mounted at the bottom of the linear motor (7), and a glass cutter (9) is mounted at the telescopic end of the first electric push rod (8).

4. The cutting and edging system for producing optical glass according to claim 1, wherein a jacking electric push rod (19) is mounted in the middle of the upper end of the supporting top frame (18) and directly above the first electric sliding table (15), and a jacking plate (20) is rotatably connected to the telescopic end of the jacking electric push rod (19).

5. The cutting and edging system for producing optical glass according to claim 1, wherein a positioning probe (30) for positioning and detecting the end of the glass plate is fixedly connected to one side of the middle part of the second vertical rod (10) close to the breaking-off frame (13).

6. The cutting and edging system for producing optical glass according to claim 1, wherein a first spring (28) is mounted at the bottom of the first pressing block (25), a third pressing block (29) is mounted at the lower end of the first spring (28), and a separation bump (27) is fixedly connected to one side of the bottom end surface of the second pressing block (26) far away from the first pressing block (25).

7. The cutting and edging system for optical glass production according to claim 6, characterized in that the first spring (28) has twice the length of the second presser piece (26), and the lower surface of the third presser piece (29) is higher than the lower surface of the second presser piece (26) when the first spring (28) is compressed.

8. The cutting and edging system for producing optical glass according to claim 1, wherein a material guiding brace rod (32) for receiving the glass plate is fixedly connected to the top of the breaking-off frame (13), and a material guiding inclined plate (31) is fixedly connected to one side of the material guiding brace rod (32) close to the second conveyor belt (14).

9. The cutting and edging system for producing optical glass according to claim 8, wherein an upper surface of the material guiding support rod (32) is flush with an upper surface of the first conveyor belt (3), a belt surface height of the first conveyor belt (3) is higher than a belt surface height of the second conveyor belt (14), a length of the material guiding support rod (32) is consistent with that of the first conveyor belt (3), and a lower end of the material guiding inclined plate (31) abuts against one end of the belt surface of the second conveyor belt (14).

10. The cutting and edging system for producing optical glass according to claim 1, wherein a mounting groove is formed in the middle of the supporting rotating frame (17) and a plurality of material guiding rollers (33) are uniformly distributed at equal intervals, connecting blocks (34) are fixedly connected to both ends of a rotating shaft of each material guiding roller (33), a driving block (35) is fixedly connected to the lower end of each connecting block (34), second springs (36) are fixedly connected to the upper sides of both ends of each driving block (35), and the upper ends of the second springs (36) are fixedly connected to the supporting rotating frame (17).