CN112939440A - Circular glass cutting equipment is used in glass production - Google Patents

Abstract

The invention relates to cutting equipment, in particular to circular glass cutting equipment for glass production. The technical problem is to provide a circular glass cutting device for glass production, which can automatically lift, fix and unlock a glass cutter, automatically rotate the glass cutter and automatically knock off redundant glass waste. A circular glass cutting device for glass production comprises: the first support frame is symmetrically arranged on the ground; the feeding component is arranged between the upper parts of the first support frames; the scratching component is arranged on the feeding component. According to the invention, the first slide bar is pushed to move upwards to drive the glass cutter to move upwards, and then the placing frame is pushed to move backwards, so that the glass is positioned at the lower side of the glass cutter, the first slide bar is loosened, the glass cutter moves downwards to contact the glass, the first rotating shaft is rotated to drive the glass cutter to rotate, and the effect of obtaining the round glass by simple operation and cutting is achieved.

Description

Circular glass cutting equipment is used in glass production

Technical Field

The invention relates to cutting equipment, in particular to circular glass cutting equipment for glass production.

Background

Glass, which is a material in the building manufacturing field that is seen everywhere in our daily life, is widely used due to its characteristics of light transmission, hardness, etc., and the forms of glass are different, and in order to obtain glass with different forms, it is usually required to cut it, such as round glass.

The existing circular glass cutting technology is to place square glass on a workbench, a user manually utilizes tools such as a glass cutter to leave circular scratches on the square glass, then forcibly strikes the four corners of the circular glass, and removes redundant glass waste materials to obtain the circular glass.

Therefore, it is necessary to design a circular glass cutting device for glass production, which can automatically lift, fix and unlock the glass cutter, automatically rotate the glass cutter, and automatically knock off the redundant glass waste.

Disclosure of Invention

In order to overcome among the prior art manual glass sword that rotates and strike glass four corners, easily be injured and shortcoming, technical problem of inefficiency: the circular glass cutting equipment for glass production is provided, wherein the glass cutter can be automatically lifted, fixed and unlocked, the glass cutter can be automatically rotated, and redundant glass waste can be automatically knocked off.

The technical scheme is as follows: a circular glass cutting device for glass production comprises: the first support frame is symmetrically arranged on the ground; the feeding component is arranged between the upper parts of the first support frames; the scratching component is arranged on the feeding component.

Preferably, the feeding assembly comprises: the upper parts of the first support frames are connected with first support rods; the inner parts of one sides of the first supporting rods are connected with the sliding blocks in a sliding manner; the placing frame is connected between the sliding blocks; the sucking discs are symmetrically connected to both sides of the upper part of the placing frame.

Preferably, the scoring assembly comprises: the middle of the upper part of the first support rod is connected with a first support block; the first sliding rod is connected between the first supporting blocks in a sliding manner; the first springs are connected between the upper parts of the first sliding rods and the first supporting blocks; the middle part of the first sliding rod is rotatably connected with a first rotating shaft; the lower side of the first rotating shaft is connected with a first connecting rod; the two sides of the first connecting rod are both connected with glass cutters in a sliding manner; and the second springs are connected between the middle part of the glass cutter and the first connecting rod and sleeved on the connecting rod of the glass cutter.

Preferably, the device further comprises a clamping assembly, wherein the clamping assembly comprises: the second support frame is connected between the upper parts of the first support blocks; the air cylinder is mounted on one side of the upper part of the second support frame; the lower side of the piston rod of the air cylinder is connected with a second connecting rod; the two sides of the lower part of the second connecting rod are both connected with a first push rod in a sliding way; the third springs are connected between one side of the first push rod and the second connecting rod; one side of the upper part of the first supporting block is connected with a second supporting block; the inner sides of one part of the second supporting block are connected with clamping blocks in a sliding manner, and the clamping blocks are matched with the first sliding rod; a fourth spring is connected between one part of the clamping block and the second supporting block and sleeved on the clamping block; the first wedge block is connected to one side of the upper portion of the clamping block, and the first wedge block is matched with the first push rod.

Preferably, the lifting device further comprises a lifting assembly, wherein the lifting assembly comprises: the outer side of one part of the lower side of the second connecting rod is symmetrically connected with the guide block; the guide blocks are internally and slidably connected with a second slide bar; the fifth spring is connected between one part of the second sliding rod and the guide block and sleeved on the second sliding rod; the rotating block is rotatably connected to one part of the second sliding rod and is matched with the first sliding rod; torsion springs are symmetrically connected between one side of the rotating block and the second sliding rod; one side of the second sliding rod is connected with a second push rod; the outer sides of one part of the first supporting rod are connected with a second supporting rod; the inner sides of the upper parts of the second support rods are both connected with a second wedge block in a sliding manner, and the second wedge block is matched with the second push rod; and a sixth spring is connected between one part of the outer side of the second wedge block and the second support rod.

Preferably, the device further comprises a driving assembly, wherein the driving assembly comprises: the outer sides of one parts of the first supporting rods are connected with third supporting blocks; the upper parts of the third supporting blocks are connected with pressure rods in a sliding manner, and the pressure rods are matched with the lower parts of the second connecting rods; the seventh spring is connected between the lower side of the compression bar and the third supporting block; the upper part of one side of the pressure rod is connected with the groove rod; the ratchet bars are connected inside the groove rods; the eighth spring, connect with three eighth springs evenly at intervals between slotted pole and one side of the ratchet bar; one side of the upper part of the first supporting rod is connected with a third supporting rod; the inner side of the upper part of the third supporting rod is rotatably connected with a ratchet gear, and the ratchet gear is meshed with a ratchet bar; the second rotating shaft is rotatably connected between one sides of the first supporting rods; the first transmission assemblies are connected between the two sides of the second rotating shaft and the outer side of the ratchet gear transmission shaft; a fourth supporting rod is connected between one sides of the upper parts of the first supporting rods; the upper side of the middle part of the fourth supporting rod is rotatably connected with a first gear; the bevel gear set is connected between the lower side of the first gear transmission shaft and one side of the second rotating shaft; one side of the middle part of the first sliding rod is connected with a fifth supporting rod; the lower side of one part of the fifth supporting rod is rotatably connected with a second gear, and the second gear is meshed with the first gear; and a second transmission assembly is connected between the upper side of the first gear transmission shaft and the upper side of the first rotating shaft.

Preferably, the device further comprises a removing assembly, and the removing assembly is arranged between the upper end of the first rotating shaft and the upper part of the first sliding rod.

Preferably, the removing assembly comprises: the upper end of the first rotating shaft is connected with the rotating lug; the upper part of the first sliding rod is connected with a third supporting frame; the two sides of the upper part of the third support frame are both connected with guide rods in a sliding manner, and the guide rods are matched with the rotating lugs; the fixed bracket is connected between the upper sides of the guide rods; the two sides of the lower part of the fixed support are symmetrically and slidably connected with the removing rods; and the ninth spring is connected between the upper part of the removing rod and the fixed support, and the ninth spring is sleeved on the removing rod.

Compared with the prior art, the invention has the following advantages: 1. according to the invention, the first slide bar is pushed to move upwards to drive the glass cutter to move upwards, and then the placing frame is pushed to move backwards, so that the glass is positioned at the lower side of the glass cutter, the first slide bar is loosened, the glass cutter moves downwards to contact the glass, the first rotating shaft is rotated to drive the glass cutter to rotate, and the effect of obtaining the round glass by simple operation and cutting is achieved.

2. According to the invention, the cylinder is started to drive the first push rod to move downwards, the clamping block is driven to move backwards by matching with the first wedge-shaped block, the first slide rod is loosened, and finally the glass cutter is contacted with the glass, so that the effect of automatically unlocking the glass cutter is achieved, and the cutting efficiency is improved.

3. According to the glass cutter lifting device, the second sliding rod, the rotating block and the second push rod are driven to move downwards through the second connecting rod, the rotating block passes through the first sliding rod, the second push rod passes through the second wedge-shaped block, the second connecting rod drives the second sliding rod, the rotating block and the second push rod to move upwards, the rotating block pushes the first sliding rod to move upwards, the effect of automatically lifting the glass cutter is achieved, and manpower is saved.

4. The invention drives the pressure rod and the ratchet bar to move upwards through the second connecting rod, drives the ratchet wheel to rotate, and drives the first rotating shaft to rotate under the meshing and rotating actions, thereby driving the glass cutter to rotate, achieving the effect of automatically driving the glass cutter to rotate, improving the glass cutting efficiency and saving the time.

5. According to the invention, the rotating lug is driven to rotate by the first rotating shaft, the fixed support and the removing rod are driven to move downwards by matching with the guide rod, the removing rod knocks four corners of square glass, the effect of automatically knocking off redundant glass waste is achieved, and the operation is safe and labor-saving.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of another perspective structure according to the present invention.

FIG. 3 is a schematic diagram of a first partial structure according to the present invention.

FIG. 4 is a second partial structure diagram of the present invention.

FIG. 5 is a third partial structural diagram of the present invention.

FIG. 6 is a schematic diagram of a fourth partial structure of the present invention.

FIG. 7 is a schematic diagram of a fifth partial structure according to the present invention.

FIG. 8 is a schematic diagram of a sixth partial structure according to the present invention.

Description of reference numerals: 1: first support frame, 2: a feeding assembly, 201: first support bar, 202: slider, 203: rack, 204: suction cup, 3: scoring assembly, 301: first support block, 302: first slide bar, 303: first spring, 304: first rotation axis, 305: first connecting rod, 306: glass cutter, 307: second spring, 4: chucking assembly, 401: second support bracket, 402: air cylinder, 403: second connecting rod, 404: first push rod, 405: third spring, 406: second support block, 407: a latch, 408: fourth spring, 409: first wedge block, 5: lifting assembly, 501: guide block, 502: second slide bar, 503: rotation block, 504: torsion spring, 505: fifth spring, 506: second push rod, 507: second support bar, 508: second wedge block, 509: sixth spring, 6: drive assembly, 601: third support block, 602: pressure lever, 603: seventh spring, 604: grooved bar, 605: ratchet bar, 606: eighth spring, 607: third support bar, 608: ratchet gear, 609: first transmission assembly, 610: second rotation shaft, 611: bevel gear set, 612: fourth support bar, 613: first gear, 614: fifth support bar, 615: second gear, 616: second transmission assembly, 7: removal component, 701: rotation knob, 702: third support, 703: fixing bracket, 704: guide bar, 705: removal rod, 706: and a ninth spring.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Example 1

A circular glass cutting device for glass production is shown in figures 1, 2, 3 and 4 and comprises a first support frame 1, a feeding component 2 and a scratching component 3, wherein the first support frame 1 is arranged on the ground in a bilateral symmetry mode, the feeding component 2 is arranged between the upper portions of the first support frame 1, and the scratching component 3 is arranged on the feeding component 2.

The feeding assembly 2 comprises first supporting rods 201, sliding blocks 202, placing frames 203 and suckers 204, the first supporting rods 201 are connected to the upper portion of the first supporting frame 1, the sliding blocks 202 are connected to the inner portions of the front sides of the first supporting rods 201 in a sliding mode, the placing frames 203 are connected between the sliding blocks 202, and the suckers 204 are symmetrically connected to the front side and the rear side of the upper portion of the placing frames 203 in a left-right mode.

The scratching assembly 3 comprises a first supporting block 301, a first sliding rod 302, a first spring 303, a first rotating shaft 304, a first connecting rod 305, a glass cutter 306 and a second spring 307, the first supporting block 301 is connected to the middle of the upper portion of the first supporting rod 201, the first sliding rod 302 is connected between the first supporting block 301 in a sliding mode, the first spring 303 is connected between the upper portion of the first sliding rod 302 and the first supporting block 301, the first rotating shaft 304 is rotatably connected to the middle of the first sliding rod 302, a first connecting rod 305 is connected to the lower side of the first rotating shaft 304, the glass cutter 306 is connected to the left side and the right side of the first connecting rod 305 in a sliding mode, the second spring 307 is connected between the middle of the glass cutter 306 and the first connecting rod 305, and the second spring 307 is sleeved on a connecting rod of the.

When a user needs to cut round glass, firstly, square glass is placed on the upper side of the suction cup 204, the square glass is pressed downwards, the suction cup 204 tightly sucks the square glass to fix the square glass, the first sliding rod 302 is pushed to move upwards, the first spring 303 is compressed to drive the first connecting rod 305 and the glass cutter 306 to move upwards, the state is kept, then the placing frame 203 is pushed to move backwards, the suction cup 204 and the glass are driven to move backwards to the lower side of the glass cutter 306, the first sliding rod 302 is loosened, the first sliding rod 302 is pushed to move downwards under the action of the first spring 303, the first connecting rod 305 and the glass cutter 306 are driven to move downwards, the glass cutter 306 is driven to move upwards after contacting the glass, the second spring 307 is compressed to enable the glass cutter 306 to be tightly attached to the glass, the first rotating shaft 304 is rotated to drive the first connecting rod 305 and the glass cutter 306 to rotate, and the glass cutter 306 scratches round on the glass, stopping rotating the first rotating shaft 304, stopping rotating the glass cutter 306, knocking four corners of square glass at the moment, knocking off redundant glass waste to obtain circular glass, pushing the first sliding rod 302 to move upwards again, compressing the first spring 303 to drive the first connecting rod 305 and the glass cutter 306 to move upwards, pushing the glass cutter 306 to move downwards under the action of the second spring 307 after the glass cutter 306 is far away from the glass, pushing the placing frame 203 to move forwards to drive the sucking disc 204 and the circular glass to move forwards to the original position, loosening the first sliding rod 302 at the moment, pushing the first sliding rod 302, the first connecting rod 305 and the glass cutter 306 to move downwards under the action of the first spring 303 to restore to the original state, finally taking down and collecting the circular glass from the sucking disc 204, and repeating the steps in the above way to achieve the effect of simply operating and cutting to obtain the circular glass.

Example 2

On the basis of embodiment 1, as shown in fig. 1, 2, 5, 6, 7 and 8, the locking device 4 further includes a locking assembly 4, the locking assembly 4 includes a second supporting frame 401, a cylinder 402, a second connecting rod 403, a first push rod 404, a third spring 405, a second supporting block 406, a locking block 407, a fourth spring 408 and a first wedge-shaped block 409, the second supporting frame 401 is connected between the upper portions of the first supporting blocks 301, the cylinder 402 is installed on the rear side of the upper portion of the second supporting frame 401, the second connecting rod 403 is connected to the lower side of the piston rod of the cylinder 402, the first push rod 404 is connected to both left and right sides of the lower portion of the second connecting rod 403 in a sliding manner, the third spring 405 is connected between the rear side of the first push rod 404 and the second connecting rod 403, the second supporting block 406 is connected to the rear side of the upper portion of the first supporting block 301, the locking block 407 is connected to the inner side of the rear portion of the, a fourth spring 408 is connected between the front part of the clamping block 407 and the second supporting block 406, the fourth spring 408 is sleeved on the clamping block 407, a first wedge block 409 is connected to the rear side of the upper part of the clamping block 407, and the first wedge block 409 is matched with the first push rod 404.

In the starting state, the clamping block 407 blocks the first slide bar 302, the first spring 303 is compressed, the air cylinder 402 is started, when the piston rod of the air cylinder 402 moves downwards, the second connecting rod 403 and the first push rod 404 are pushed to move downwards, the first push rod 404 contacts the first wedge-shaped block 409 and pushes the first wedge-shaped block 409 to move backwards, the clamping block 407 is driven to move backwards and away from the first slide bar 302, the fourth spring 408 is compressed, the first slide bar 302 moves downwards under the action of the first spring 303, finally, the glass cutter 306 is tightly attached to the square glass to finish cutting, when the first push rod 404 passes through the first wedge-shaped block 409 and drives the first wedge-shaped block 409 and the clamping block 407 to move forwards under the action of the fourth spring 408, the first slide bar 302 is pushed to move upwards after the round glass is obtained, the first spring 303 is compressed, the first slide bar 302 pushes the clamping block 407 to move backwards, and the fourth spring 408 is compressed, after the first sliding rod 302 passes through the clamping block 407, under the action of the fourth spring 408, the clamping block 407 is pushed to move forward to block the first sliding rod 302, and the original state is recovered, when the piston rod of the air cylinder 402 moves upward, the second connecting rod 403 and the first push rod 404 are driven to move upward, after the first push rod 404 contacts the first wedge block 409, the first push rod 404 is pushed to move backward, the third spring 405 is compressed, after the first push rod 404 passes through the first wedge block 409, under the action of the third spring 405, the first push rod 404 is pushed to move forward to recover to the original state, and the reciprocating operation is performed in this way, so that the effect of automatically unlocking the glass cutter 306 is achieved, and the cutting efficiency is improved.

The lifting assembly 5 comprises a guide block 501, a second sliding rod 502, a rotating block 503, a torsion spring 504, a fifth spring 505, a second push rod 506, a second support rod 507, a second wedge block 508 and a sixth spring 509, wherein the guide block 501 is symmetrically connected to the left and right of the outer side of the lower front part of a second connecting rod 403, the second sliding rod 502 is slidably connected inside the guide block 501, the fifth spring 505 is connected between the rear part of the second sliding rod 502 and the guide block 501, the fifth spring 505 is sleeved on the second sliding rod 502, the rotating block 503 is rotatably connected to the front part of the second sliding rod 502, the rotating block 503 is matched with the first sliding rod 302, the torsion spring 504 is symmetrically connected to the left and right of the rear side of the rotating block 503 and the second sliding rod 502, the second push rod 506 is connected to the rear side of the second sliding rod 502, the second support rod 507 is connected to the outer side of the rear part of the first support rod 201, and the second wedge block 508 is slidably connected to the inner side, the second wedge block 508 is matched with the second push rod 506, and a sixth spring 509 is connected between the rear part of the outer side of the second wedge block 508 and the second support rod 507.

The second connecting rod 403 moves downwards to drive the second sliding rod 502, the rotating block 503 and the second pushing rod 506 to move downwards, the second pushing rod 506 is contacted with the second wedge-shaped block 508 to push the second wedge-shaped block 508 to move backwards, the sixth spring 509 is compressed, the second pushing rod 506 passes through the second wedge-shaped block 508 and pushes the second wedge-shaped block 508 to move forwards under the action of the sixth spring 509 to return to the original state, the rotating block 503 is moved downwards to be contacted with the first sliding rod 302 and then pushed to rotate clockwise, the torsion spring 504 deforms, so that after the rotating block 503 passes through the first sliding rod 302 and pushes the rotating block 503 to rotate anticlockwise under the action of the torsion spring 504 to return to the original state, and after the round glass is cut, the second connecting rod 403 moves upwards to drive the second sliding rod 502, the rotating block 503 and the second pushing rod 506 to move upwards, the rotating block 503 pushes the first sliding rod 302 to move upwards, the first sliding rod 302 is finally stopped by the clamping block 407, the second pushing rod 506 moves upwards to contact with the second wedge-shaped block 508 and is pushed to move backwards, the second sliding rod 502 and the rotating block 503 are driven to move backwards, the fifth spring 505 is compressed, the rotating block 503 is far away from the first sliding rod 302 and continues to move upwards, and after the second pushing rod 506 passes through the second wedge-shaped block 508, the second sliding rod 502 and the rotating block 503 are pushed to move forwards under the action of the fifth spring 505, so that the rotating block 503 moves above the first sliding rod 302 again and returns to the original state, and the reciprocating operation is performed, the effect of automatically lifting the glass cutter 306 is achieved, and the labor is saved.

The device also comprises a driving component 6, the driving component 6 comprises a third supporting block 601, a pressing rod 602, a seventh spring 603, a grooved rod 604, a ratchet strip 605, an eighth spring 606, a third supporting rod 607, a ratchet wheel 608, a first transmission component 609, a second rotating shaft 610, a bevel gear set 611, a fourth supporting rod 612, a first gear 613, a fifth supporting rod 614, a second gear 615 and a second transmission component 616, the outer side of the rear part of the first supporting rod 201 is connected with the third supporting block 601, the upper part of the third supporting block 601 is connected with the pressing rod 602 in a sliding way, the lower parts of the pressing rod 602 and the second connecting rod 403 are matched with each other, the seventh spring 603 is connected between the lower side of the pressing rod 602 and the third supporting block 601, the upper part of the rear side of the pressing rod 602 is connected with the grooved rod 604, the inner part of the grooved rod 604 is connected with the ratchet strip 605, three eighth springs 606 are uniformly spaced between the front side of the ratchet strip 605 and the grooved rod 604, the rear, a ratchet gear 608 is rotatably connected to the inner side of the upper portion of the third support rod 607, the ratchet gear 608 is engaged with the ratchet bar 605, a second rotating shaft 610 is rotatably connected between the rear sides of the first support rod 201, first transmission assemblies 609 are respectively connected between the left and right sides of the second rotating shaft 610 and the outer side of a transmission shaft of the ratchet gear 608, a fourth support rod 612 is connected between the rear sides of the upper portion of the first support rod 201, a first gear 613 is rotatably connected to the upper side of the middle portion of the fourth support rod 612, a bevel gear set 611 is connected between the lower side of the transmission shaft of the first gear 613 and the right side of the transmission shaft of the second rotating shaft 610, a fifth support rod 614 is connected to the rear side of the middle portion of the first slide rod 302, a second gear 615 is rotatably connected to the lower side of the rear portion of the fifth support rod 614, the second gear.

The second connecting rod 403 moves downwards to push the pressing rod 602 to move downwards, the seventh spring 603 is compressed to drive the grooved rod 604 and the ratchet rack 605 to move downwards, thereby driving the ratchet gear 608 to rotate, the second rotating shaft 610 is driven to rotate through the first transmission component 609, thereby driving the bevel gear set 611 and the first gear 613 to rotate, further driving the second gear 615 and the second transmission component 616 to rotate, thereby driving the first rotating shaft 304 to rotate, finally the glass cutter 306 to cut into circular glass, then the second connecting rod 403 moves upwards to be far away from the pressing rod 602, under the action of the seventh spring 603, the pressing rod 602 is driven to move upwards, thereby driving the grooved rod 604 and the ratchet rack 605 to move upwards, under the action of the eighth spring 606, the ratchet rack does not drive the ratchet gear 608 to rotate, finally the first rotating shaft 304 stops rotating, the glass cutter 306 stops rotating, returns to the original state, and so on, the effect of automatically driving the glass cutter 306 to rotate is achieved, the glass cutting efficiency is improved, and the time is saved.

The device is characterized by further comprising a removing assembly 7, wherein the removing assembly 7 comprises a rotating lug 701, a third supporting frame 702, a fixing support 703, a guide rod 704, a removing rod 705 and a ninth spring 706, the upper end of the first rotating shaft 304 is connected with the rotating lug 701, the upper portion of the first sliding rod 302 is connected with the third supporting frame 702, the left side and the right side of the upper portion of the third supporting frame 702 are all slidably connected with the guide rod 704, the guide rod 704 is matched with the rotating lug 701, the fixing support 703 is connected between the upper sides of the guide rod 704, the left side and the right side of the lower portion of the fixing support 703 are all slidably connected with the removing rod 705 in a front-back symmetrical mode, the ninth spring 706 is sleeved on the removing rod 705.

The first sliding rod 302 moves downwards to drive the removing assembly 7 to move downwards integrally, the removing rod 705 is close to round glass, the first rotating shaft 304 rotates to drive the rotating lug 701 to rotate, so that the guide rod 704 is pushed to move up and down continuously, when the guide rod 704 moves upwards, the fixing support 703 and the removing rod 705 are driven to move upwards, then the guide rod 704 moves downwards to drive the fixing support 703 and the removing rod 705 to move downwards, the removing rod 705 moves downwards for a certain distance under the action of inertia, the ninth spring 706 is compressed, the removing rod 705 is knocked at four corners of the square glass after scratching to knock down the redundant glass waste, then the removing rod 705 is pushed to move upwards under the action of the ninth spring 706 to restore to the original state, the reciprocating is carried out, the effect of automatically knocking down the redundant glass waste is achieved, and the operation is safe and labor-saving.

The above description is only an example of the present invention and is not intended to limit the present invention. All equivalents which come within the spirit of the invention are therefore intended to be embraced therein. Details not described herein are well within the skill of those in the art.

Claims (8)

1. The utility model provides a glass production is with circular glass-cutting equipment which characterized in that, including:

the first support frame (1) is symmetrically arranged on the ground;

the feeding component (2) is arranged between the upper parts of the first supporting frames (1);

the scratching component (3) is arranged on the feeding component (2).

2. The circular glass cutting apparatus for glass production according to claim 1, wherein the feeding assembly (2) comprises:

the upper parts of the first support frames (1) are connected with the first support rods (201);

the sliding blocks (202) are connected inside one side of the first supporting rod (201) in a sliding mode;

the placing rack (203) is connected between the sliding blocks (202);

the sucking discs (204) are symmetrically connected to the two sides of the upper part of the placing frame (203).

3. The circular glass cutting apparatus for glass production according to claim 2, wherein the scoring assembly (3) comprises:

the middle of the upper part of the first supporting rod (201) is connected with the first supporting block (301);

the first sliding rod (302) is connected between the first supporting blocks (301) in a sliding manner;

the first spring (303) is connected between the upper part of the first sliding rod (302) and the first supporting block (301);

the middle part of the first sliding rod (302) is rotatably connected with the first rotating shaft (304);

a first connecting rod (305), the lower side of the first rotating shaft (304) is connected with the first connecting rod (305);

the two sides of the first connecting rod (305) are both connected with the glass cutter (306) in a sliding manner;

and a second spring (307) is connected between the middle part of the glass cutter (306) and the first connecting rod (305), and the second spring (307) is sleeved on the connecting rod of the glass cutter (306).

4. The circular glass cutting device for glass production according to claim 3, further comprising a clamping assembly (4), wherein the clamping assembly (4) comprises:

the second support frame (401) is connected between the upper parts of the first support blocks (301);

the air cylinder (402) is mounted on one side of the upper part of the second supporting frame (401);

the lower side of a piston rod of the air cylinder (402) is connected with a second connecting rod (403);

the two sides of the lower part of the second connecting rod (403) are both connected with the first push rod (404) in a sliding way;

the third spring (405) is connected between one side of the first push rod (404) and the second connecting rod (403);

one side of the upper part of the first supporting block (301) is connected with the second supporting block (406);

the inner sides of one part of the second supporting block (406) are both connected with a clamping block (407) in a sliding manner, and the clamping block (407) is matched with the first sliding rod (302);

a fourth spring (408) is connected between one part of the clamping block (407) and the second supporting block (406), and the fourth spring (408) is sleeved on the clamping block (407);

the first wedge block (409) is connected to one side of the upper portion of the clamping block (407), and the first wedge block (409) is matched with the first push rod (404).

5. The circular glass cutting apparatus for glass production according to claim 4, further comprising a lifting assembly (5), wherein the lifting assembly (5) comprises:

the guide block (501) is symmetrically connected to the outer side of one part of the lower side of the second connecting rod (403);

the guide block (501) is internally and slidably connected with a second sliding rod (502);

a fifth spring (505), wherein the fifth spring (505) is connected between one part of the second sliding rod (502) and the guide block (501), and the fifth spring (505) is sleeved on the second sliding rod (502);

the rotating block (503) is rotatably connected to one part of the second sliding rod (502), and the rotating block (503) is matched with the first sliding rod (302);

the torsion springs (504) are symmetrically connected between one side of the rotating block (503) and the second sliding rod (502);

one side of the second sliding rod (502) is connected with a second push rod (506);

the outer sides of one part of the first supporting rod (201) are connected with a second supporting rod (507);

the inner sides of the upper parts of the second supporting rods (507) are both connected with second wedge blocks (508) in a sliding mode, and the second wedge blocks (508) are matched with the second push rods (506);

and a sixth spring (509), wherein the sixth spring (509) is connected between one part of the outer side of the second wedge-shaped block (508) and the second support rod (507).

6. The circular glass cutting apparatus for glass production according to claim 5, further comprising a driving assembly (6), wherein the driving assembly (6) comprises:

the outer sides of one parts of the first supporting rods (201) are connected with the third supporting blocks (601);

the upper parts of the third supporting blocks (601) are connected with the pressing rods (602) in a sliding manner, and the pressing rods (602) are matched with the lower parts of the second connecting rods (403);

the seventh spring (603) is connected between the lower side of the pressure lever (602) and the third supporting block (601);

the upper part of one side of the pressure lever (602) is connected with the groove rod (604);

the ratchet bars (605) are connected inside the groove rods (604);

the eighth spring (606), three eighth springs (606) are evenly connected between one side of the ratchet bar (605) and the slot rod (604) at intervals;

one side of the upper part of the first supporting rod (201) is connected with a third supporting rod (607);

the inner side of the upper part of the third supporting rod (607) is rotatably connected with a ratchet gear (608), and the ratchet gear (608) is meshed with a ratchet rack (605);

a second rotating shaft (610), wherein the second rotating shaft (610) is rotatably connected between one sides of the first supporting rods (201);

the first transmission assembly (609) is connected between both sides of the second rotating shaft (610) and the outer side of the transmission shaft of the ratchet gear (608);

a fourth supporting rod (612), wherein the fourth supporting rod (612) is connected between one sides of the upper parts of the first supporting rods (201);

the upper side of the middle part of the fourth supporting rod (612) is rotatably connected with the first gear (613);

a bevel gear set (611), wherein the bevel gear set (611) is connected between the lower side of the transmission shaft of the first gear (613) and one side of the second rotating shaft (610);

a fifth supporting rod (614), wherein one side of the middle part of the first sliding rod (302) is connected with the fifth supporting rod (614);

a second gear (615), wherein the lower side of one part of the fifth supporting rod (614) is rotatably connected with the second gear (615), and the second gear (615) is meshed with the first gear (613);

and a second transmission assembly (616) is connected between the upper side of the transmission shaft of the first gear (613) and the upper side of the first rotating shaft (304).

7. The circular glass cutting apparatus for glass production according to claim 6, further comprising a removing unit (7), wherein the removing unit (7) is disposed between the upper end of the first rotating shaft (304) and the upper portion of the first sliding bar (302).

8. The circular glass cutting apparatus for glass production according to claim 7, wherein the removing unit (7) comprises:

a rotating lug (701), wherein the upper end of the first rotating shaft (304) is connected with the rotating lug (701);

the upper part of the first sliding rod (302) is connected with a third supporting frame (702);

the two sides of the upper part of the third support frame (702) are both connected with the guide rods (704) in a sliding manner, and the guide rods (704) are matched with the rotating lug (701);

the fixing bracket (703) is connected between the upper sides of the guide rods (704);

the two sides of the lower part of the fixed support (703) are symmetrically and slidably connected with the removing rod (705);

ninth springs (706) are connected between the upper portion of the removing rod (705) and the fixing support (703), and the ninth springs (706) are sleeved on the removing rod (705).

Images