CN219542035U

CN219542035U - Cutting device for tempered glass processing

Info

Publication number: CN219542035U
Application number: CN202320459164.5U
Authority: CN
Inventors: 曾立明; 曾亚
Original assignee: Henan Qinming Energy Saving Glass Co ltd
Current assignee: Henan Qinming Energy Saving Glass Co ltd
Priority date: 2023-03-10
Filing date: 2023-03-10
Publication date: 2023-08-18
Anticipated expiration: 2033-03-10

Abstract

The utility model discloses a cutting device for processing toughened glass, and relates to the technical field of toughened glass processing. The automatic cutting machine comprises a cutting box, a laser cutting knife, a second driving motor and a discharging component, wherein two ends of the inner side of the cutting box are rotationally clamped with an operating platform, the laser cutting knife is arranged on the inner side of the cutting box, extrusion positioning wheels are arranged on the periphery of the laser cutting knife, one side of the cutting box is penetrated and clamped with the discharging component, the bottom end of the inner side of the discharging component is rotationally clamped with a conveying belt, one side of the discharging component is clamped and fixed with the second driving motor, one side of the second driving motor is provided with an air pump, and the bottom end of the air pump is penetrated and clamped with a sucker. According to the utility model, through the cutting box, the laser cutting knife, the second driving motor and the discharging component, the problems that the cutting device can only clean glass slag on the surface of the workbench after cutting, certain potential safety hazards exist and discharging is inconvenient are solved.

Description

Cutting device for tempered glass processing

Technical Field

The utility model belongs to the technical field of tempered glass processing, and particularly relates to a cutting device for tempered glass processing.

Background

Toughened glass is glass with compressive stress on the surface, has the advantages of safe use, high strength and the like, and is widely used in industries of building decoration, furniture manufacture, household appliance manufacture, electronic instrument, automobile manufacture and the like, and in the process of processing, the toughened glass is formed by heating the glass to be close to softening temperature and keeping the temperature for a certain time and quenching the glass to change the temperature so as to form stress, and the toughened glass cannot be cut and processed after being toughened, so that the toughened glass is cut to the required size and shape by a cutting device before being toughened, and then is subjected to toughening treatment, but the toughened glass still has the following defects in actual use:

1. the utility model discloses a cutting device for processing toughened glass, which is characterized in that a cutting mechanism is arranged on the upper surface of a workbench, two collecting barrels are fixedly connected to the front side and the rear side of the workbench, one side of the rear side surface of the workbench is fixedly connected with a positioning plate A, a motor is fixedly arranged on the upper surface of the positioning plate A, the front side surface of the motor is fixedly connected with a threaded rod, one end of the threaded rod, which is far away from the motor, is fixedly connected to the surface of one side of an L-shaped plate, and glass slag generated by cutting can be cleaned through the movement of the positioning plate B on the surface of the workbench, so that the influence of the glass slag on the subsequent processing is avoided, but in actual use, as a whole piece of glass can be cut into a plurality of pieces for subsequent processing, the glass slag can be generated at any time in the process of cutting a plurality of pieces of glass, and the positioning plate B can only clean the glass slag after all glass cutting processing, and workers can easily contact the glass slag when taking glass, so that certain potential safety hazards exist;

2. when cutting device cuts a monoblock glass, when cutting one glass and cutting another glass, probably can lead to the fact the damage to the glass that cuts, and when a monoblock glass cuts into the polylith, the ejection of compact is comparatively inconvenient, increases staff's intensity of labour.

Disclosure of Invention

The utility model aims to provide a cutting device for processing toughened glass, which solves the problems that the cutting device can only clean glass slag on the surface of a workbench after cutting, certain potential safety hazards exist when the cut glass is taken, the cutting of the rear glass possibly affects the front glass and the discharging of the plurality of glass is inconvenient when the plurality of glass is cut.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to a cutting device for processing toughened glass, which comprises a cutting box, a laser cutting knife, a second driving motor and a discharging component, wherein two ends of the inner side of the cutting box are rotationally clamped with an operation table, workers can be protected through the cutting box, personnel injury caused by splashing of glass slag in the cutting process is avoided, after glass is cut and discharged, the operation table can be rotated downwards, the rest leftover materials of the glass are poured into a waste collection box so as to facilitate centralized processing of the workers, the inner side of the cutting box is provided with the laser cutting knife, the periphery of the laser cutting knife is provided with extrusion positioning wheels, when the laser cutting knife cuts the glass, the periphery of a cutting position can be extruded and fixed by the extrusion positioning wheels, the stability of the cutting process is ensured, one side of the cutting box is penetrated and clamped with the discharging component, the inboard bottom rotation joint of ejection of compact subassembly has the conveyer belt, ejection of compact subassembly one side joint is fixed with second driving motor, second driving motor one side is provided with the air pump, the joint has the sucking disc to run through to the air pump bottom, in the cutting process of polylith glass, after the glass cutting is accomplished, second driving motor can drive air pump and sucking disc and remove to the glass upper end that cuts, make air pump and sucking disc downwardly moving through the second lift cylinder, and make the sucking disc laminate in glass upper surface, take out the air between sucking disc and the glass through the air pump, make glass adsorb and be fixed in the sucking disc downside, rethread second driving motor drives glass and removes to the conveyer belt upside, carry out the ejection of compact through the rotation of conveyer belt to glass, do not need manual ejection of compact, reduce staff's intensity of labour, and further reduce the potential safety hazard.

Further, a feed inlet is formed in the front side of the cutting box in a penetrating manner, the feed inlet is attached to the upper side of the operating table, a rotating cover is clamped on the inner side of the feed inlet, a transparent PVC plate is arranged in the front side of the cutting box in a penetrating manner, and the transparent PVC plate is positioned on the upper side of the feed inlet;

the staff can carry out the feeding fast through pegging graft glass in the feed inlet, and easy operation is convenient, can observe the cutting box inboard through transparent PVC board to carry out corresponding operation, when carrying out cutting processing, the cutting box can carry out spacingly with the glass broken bits that rotate the lid to splashing, reduces the potential safety hazard.

Further, one end of the operating platform is clamped with a first rotating motor, one end of the operating platform is provided with a vent, the vent is positioned on one side of the first rotating motor of the operating platform, the first rotating motor is penetrated and clamped on one side of the cutting box, and the first rotating motor is positioned on the other side of the cutting box opposite to the discharging component;

when cutting, the fan drives the flow of air, can blow the glass broken slag on operation panel surface to the garbage collection box through the vent in collect, avoid glass broken slag to cause the influence to subsequent processing, and can not cause the influence to the processing of another piece of glass, improve production efficiency.

Further, a first threaded pipe is welded on one side of the cutting box in a penetrating manner, a second threaded pipe is screwed on the peripheral surface of the first threaded pipe, a ceramic filter element is clamped on one end of the second threaded pipe in a penetrating manner, the ceramic filter element is inserted into the inner side of the first threaded pipe in a penetrating manner, the ceramic filter element is positioned on the lower side of the operating platform, a waste collection box is inserted into the front side of the cutting box in a penetrating manner, and the waste collection box is positioned on the lower side of the ceramic filter element;

when the cutting box is blown out by air through the ceramic filter element, the cutting box is prevented from being blown out by glass residues, pollution to the environment is avoided, after glass cutting is completed, the first rotating motor drives the operating platform to rotate downwards, so that leftover materials remained on the operating platform fall into the waste collection box under the action of gravity, and workers can collect and treat waste in a concentrated mode.

Further, a connecting frame is fixedly clamped on the upper side of the laser cutting knife, a first lifting air cylinder is slidingly clamped on the upper side of the connecting frame, a first moving assembly is slidingly clamped on the upper side of the first lifting air cylinder, a first sliding block is fixedly clamped on the upper side of the first moving assembly, a first threaded rod penetrates through and is rotatably connected on one side of the first sliding block, a first driving motor is rotatably clamped on one end of the first threaded rod, the first driving motor is fixedly clamped on the other side of the cutting box relative to the discharging assembly, the first threaded rod penetrates through and is inserted on one end of the cutting box, and the laser cutting knife is suspended on the upper side of the operating platform;

the first driving motor drives the first threaded rod to rotate, the first sliding block can move in the horizontal direction along the first threaded rod, the laser cutting knife can move in the horizontal direction through the first moving assembly, and the cutting position is controlled.

Further, the upper side of the extrusion positioning wheel is clamped with a rotating assembly, the upper side of the rotating assembly is clamped with a connecting plate in a rotating mode, the center of the upper side of the connecting plate is fixedly welded with a limiting rod, the edge of the upper side of the connecting plate is clamped with an extrusion spring, the limiting rod penetrates through and is connected with the bottom side of the connecting frame in a sliding mode, and the upper end of the extrusion spring is clamped with the lower side of the connecting frame in a clamping mode;

the extrusion positioning wheel surface is smooth, and the operation panel surface is coarse, and the extrusion positioning wheel surface is smooth, and the operation panel surface is coarse, when not receiving external force, extrusion positioning wheel bottom is less than laser cutting knife bottom, when first lift cylinder drives laser cutting knife downwardly moving, can drive extrusion positioning wheel downwardly moving, makes laser cutting knife when cutting, extrusion positioning wheel can extrude glass-cutting department all around, guarantees cutting process's stability, guarantees machining efficiency.

Further, one end of the second driving motor is rotationally clamped with a second threaded rod, the peripheral surface of the second threaded rod is penetrated and rotationally connected with a second sliding block, the bottom end of the second sliding block is fixedly clamped with a second moving assembly, the bottom end of the second moving assembly is slidably clamped with a second lifting cylinder, the air pump is slidably clamped at the bottom side of the second lifting cylinder, the second driving motor is positioned at the other end of the discharging assembly relative to the cutting box, the second threaded rod is penetrated and inserted at one side of the discharging assembly, and the second threaded rod is rotationally clamped at the inner side of the cutting box relative to the other end of the discharging assembly;

after a piece of glass cutting is accomplished, the second driving motor drives the rotation of second threaded rod, makes the second slider remove along the second threaded rod to adjust the horizontal position of air pump through the second removal subassembly, make the sucking disc hang in the glass upper end that cuts, take out the air between glass and the sucking disc through the air pump, make glass adsorb in the sucking disc bottom side, and drive glass through the second driving motor and remove to the conveyer belt upside and go on the ejection of compact, need not the manual ejection of compact that carries out, reduce staff's intensity of labour.

Further, a fan is arranged on one side of the discharging component in a penetrating and clamping manner, the fan is arranged on the other side of the discharging component opposite to the cutting box, a discharging hole is arranged on one side of the discharging component in a penetrating manner, the discharging hole is arranged on the lower side of the fan, the conveyor belt is inserted into the bottom end of the inner side of the discharging hole in a penetrating manner, a second rotating motor is arranged on the front side of the discharging component in a penetrating and clamping manner, the second rotating motor is in transmission connection with the conveyor belt, a supporting plate is fixedly welded on the inner side of the discharging component in a welding manner, the supporting plate is attached to the upper end of the inner side of the conveyor belt, a supporting frame is rotatably clamped at one end of the conveyor belt, and the supporting frame is arranged at the other end of the conveyor belt opposite to the second rotating motor;

the conveyor belt is driven to rotate through the second rotating motor, glass placed on the upper side of the conveyor belt can be further driven to be discharged, the air can be driven to flow through the fan, glass slag on the upper side of an operating table in the cutting box is blown out, the influence of the glass slag on the cutting of the next glass is avoided, delay is avoided in the cutting process of the next glass, and the processing efficiency is improved.

The utility model has the following beneficial effects:

1. according to the utility model, through arranging the cutting box and the discharging component, the problem that the glass slag generated by cutting can be cleaned through the movement of the positioning plate B on the surface of the workbench, so that the influence of the glass slag on the subsequent processing is avoided, but when the glass cutting box is actually used, the whole glass is usually cut into a plurality of pieces for the subsequent processing, the glass slag can be generated at any time in the process of cutting the plurality of pieces of glass, the positioning plate B can clean the glass slag only after all glass cutting processes, workers can easily contact the glass slag when taking the glass, a certain potential safety hazard exists in use, when the glass is cut, the fan drives the air to flow, the glass slag generated by cutting can be blown to the inner side of the waste collection box through the ventilation opening, the influence of the glass slag on the cutting is avoided while the delay of the glass cutting is avoided, and after the glass cutting is finished, the operation table is driven to rotate downwards through the first rotating motor, so that the rest leftovers can fall into the waste collection box under the action of gravity, and the structure is simple, and the operation is convenient.

2. According to the utility model, the problem that when a whole piece of glass is cut by the cutting device and the other piece of glass is cut by the cutting device, damage is possibly caused to the cut glass, when the whole piece of glass is cut into a plurality of pieces, the discharging is inconvenient, the labor intensity of workers is increased, the air pump and the suction cup are driven to move to the upper side of the cut glass by the second driving motor and the second moving component, the air pump and the suction cup are driven to move downwards by the second lifting cylinder until the suction cup is attached to the surface of the glass, air between the suction cup and the glass is pumped out by the air pump, so that the glass is adsorbed and fixed on the lower side of the suction cup, the glass is driven to the upper side of the conveyor belt by the second driving motor and the second moving component, the conveyor belt is driven to rotate by the second rotating motor, the glass is discharged, and the labor intensity of the workers is not required to be manually discharged, and the labor intensity of the workers is reduced.

Drawings

FIG. 1 is a structural effect diagram of the present utility model;

FIG. 2 is a block diagram of a cutting box of the present utility model;

FIG. 3 is a cross-sectional view of the cutting box of the present utility model;

FIG. 4 is a block diagram of an operator station according to the present utility model;

FIG. 5 is a block diagram of a laser cutter according to the present utility model;

FIG. 6 is a block diagram of an extrusion positioning wheel of the present utility model;

fig. 7 is a structural view of a second driving motor of the present utility model;

FIG. 8 is a block diagram of a discharge assembly of the present utility model;

fig. 9 is a side view of the outfeed assembly of the present utility model.

Reference numerals:

1. a cutting box; 101. a feed inlet; 102. a rotary cover; 103. a transparent PVC plate; 104. a first rotating motor; 105. a first threaded pipe; 106. a waste collection box; 107. a ceramic filter element; 108. a second threaded tube; 109. an operation table; 110. a vent; 2. a laser cutter; 201. a first lifting cylinder; 202. a first moving assembly; 203. a first threaded rod; 204. a first slider; 205. a first driving motor; 206. extruding a positioning wheel; 207. a connecting frame; 208. a rotating assembly; 209. a connecting plate; 210. extruding a spring; 211. a limit rod; 3. a second driving motor; 301. a second threaded rod; 302. a second slider; 303. a second moving assembly; 304. a second lifting cylinder; 305. an air pump; 306. a suction cup; 4. a discharge assembly; 401. a conveyor belt; 402. a blower; 403. a second rotating motor; 404. a support frame; 405. a support plate; 406. and a discharge port.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Referring to fig. 1-9, the utility model discloses a cutting device for processing toughened glass, which comprises a cutting box 1, a laser cutting knife 2, a second driving motor 3 and a discharging component 4, wherein two ends of the inner side of the cutting box 1 are rotatably clamped with an operation table 109, after glass is cut and discharged, a first rotating motor 104 drives the operation table 109 to rotate downwards, so that leftover materials of the glass fall into a waste collection box 106 under the action of gravity, the inner side of the cutting box 1 is provided with the laser cutting knife 2, the periphery of the laser cutting knife 2 is provided with extrusion positioning wheels 206, when the laser cutting knife 2 moves and cuts the glass, the periphery of a cutting position is extruded and fixed by the extrusion positioning wheels 206, one side of the cutting box 1 is penetrated and clamped with a discharging component 4, the bottom end of the inner side of the discharging component 4 is rotatably clamped with a conveying belt 401, one side of the discharging component 4 is clamped with a second driving motor 3, one side of the second driving motor 3 is provided with an air pump 305, the bottom end of the air pump 305 is penetrated and clamped with a sucking disc 306, in the cutting process of the glass, when the glass is cut, the second driving motor 3 drives the air pump 305 and 306 to move to the upper end of the glass to the upper end of the cutting box, the glass is extruded and the glass is sucked by the second driving motor 306 and the sucking disc 306 to move downwards through the second sucking disc 306, and the glass is conveyed to the upper side of the glass through the second sucking disc 306 and the sucking disc 306 and is clamped by the conveying the sucking disc 306 and then conveyed by the air pump 306 and the glass is clamped by the sucking disc 3 and the sucking disc 306.

As shown in fig. 1-4, a feed inlet 101 is formed in the front side of the cutting box 1 in a penetrating manner, the feed inlet 101 is attached to the upper side of an operation table 109, a rotary cover 102 is clamped on the inner side of the feed inlet 101, a transparent PVC plate 103 is clamped on the front side of the cutting box 1 in a penetrating manner, the transparent PVC plate 103 is positioned on the upper side of the feed inlet 101, a first rotary motor 104 is clamped on one end of the operation table 109, a vent 110 is formed in one end of the operation table 109, the vent 110 is positioned on one side of the first rotary motor 104 of the operation table 109, the first rotary motor 104 is clamped on one side of the cutting box 1 in a penetrating manner, the first rotary motor 104 is positioned on the other side of the cutting box 1 opposite to the discharging component 4, a first threaded pipe 105 is welded on one side of the cutting box 1 in a penetrating manner, a second threaded pipe 108 is screwed on the outer peripheral surface of the first threaded pipe 105, a ceramic filter element 107 is clamped on one end of the second threaded pipe 108 in a penetrating manner, the ceramic filter element 107 is inserted on the inner side of the first threaded pipe 105, the ceramic filter element 107 is positioned on the lower side of the operation table 109, a waste collection box 106 is inserted on the front side of the cutting box 1 in a penetrating manner, and the waste collection box 106 is positioned on the lower side of the ceramic filter element 107;

the staff inserts glass in feed inlet 101 and makes glass laminating in operation panel 109 upside, can cut case 1 inboard through transparent PVC board and observe, and carry out corresponding operation, when carrying out cutting processing, cut case 1 and rotation lid 102 carry out spacingly to the glass broken bits that splashes, fan 402 drives the flow of air, the flow air blows the glass broken bits on operation panel 109 surface to waste collection box 106 through vent 110, the air blows out through ceramic filter core 107, after glass cutting is accomplished, first rotating electrical machines 104 drive operation panel 109 and rotate downwards, make the leftover bits that remain on operation panel 109 fall to waste collection box 106 under the effect of gravity, the staff takes out waste collection box 106 and carries out centralized processing to the waste.

As shown in fig. 1, 5 and 6, a connecting frame 207 is fixedly clamped on the upper side of the laser cutting knife 2, a first lifting cylinder 201 is slidably clamped on the upper side of the connecting frame 207, a first moving assembly 202 is slidably clamped on the upper side of the first lifting cylinder 201, a first sliding block 204 is fixedly clamped on the upper side of the first moving assembly 202, one side of the first sliding block 204 is penetrated and rotatably connected with a first threaded rod 203, one end of the first threaded rod 203 is rotatably clamped with a first driving motor 205, the first driving motor 205 is fixedly clamped on the other side of the cutting box 1 relative to the discharging assembly 4, the first threaded rod 203 is penetrated and inserted on one end of the cutting box 1, the laser cutting knife 2 is suspended on the upper side of the operating platform 109, a rotating assembly 208 is clamped on the upper side of the extrusion positioning wheel 206, a connecting plate 209 is rotatably clamped on the upper side of the central welding and fixed with a limiting rod 211, the upper side edge of the connecting plate 209 is clamped with an extrusion spring 210, the limiting rod 211 is penetrated and rotatably connected on the bottom side of the connecting frame 207;

the first driving motor 205 drives the first threaded rod 203 to rotate, so that the first sliding block 204 moves left and right along the first threaded rod 203, the laser cutter 2 moves back and forth through the first moving component 202, the laser cutter 2 moves to a cutting position, the first lifting cylinder 201 drives the laser cutter 2 to move downwards, the extrusion positioning wheel 206 is attached to the surface of glass and slides upwards through the limiting rod 211 when moving downwards, the extrusion positioning wheel 206 moves upwards, the extrusion positioning wheel 206 and the glass are extruded through the extrusion spring 210, and the glass is rapidly cut through the laser cutter 2.

As shown in fig. 7, one end of the second driving motor 3 is rotatably clamped with a second threaded rod 301, the outer circumferential surface of the second threaded rod 301 is rotatably connected with a second sliding block 302 in a penetrating and rotating manner, the bottom end of the second sliding block 302 is fixedly clamped with a second moving assembly 303, the bottom end of the second moving assembly 303 is slidably clamped with a second lifting cylinder 304, the air pump 305 is slidably clamped at the bottom side of the second lifting cylinder 304, the second driving motor 3 is positioned at the other end of the discharging assembly 4 relative to the cutting box 1, the second threaded rod 301 is inserted into one side of the discharging assembly 4 in a penetrating manner, and the second threaded rod 301 is rotatably clamped at the inner side of the cutting box 1 relative to the other end of the discharging assembly 4;

after a piece of glass is cut, the second driving motor 3 drives the second threaded rod 301 to rotate, so that the second sliding block 302 moves left and right along the second threaded rod 301, the second moving component 303 drives the air pump 305 and the sucker 306 to move back and forth, so that the sucker 306 hangs on the upper end of the cut glass, the second lifting air cylinder 304 drives the air pump 305 and the sucker 306 to move downwards until the sucker 306 is extruded and attached to the surface of the glass, the air between the glass and the sucker 306 is pumped out through the air pump 305, the glass is adsorbed on the bottom side of the sucker 306, the glass is driven to move to the upper side of the conveyor 401 through the second driving motor 3, and the air pump 305 inflates between the sucker 306 and the glass, so that the glass falls on the surface of the conveyor 401.

As shown in fig. 1, 8 and 9, one side of the discharging component 4 is connected with a fan 402 in a penetrating manner, the fan 402 is positioned on the other side of the discharging component 4 opposite to the cutting box 1, one side of the discharging component 4 is provided with a discharging hole 406 in a penetrating manner, the discharging hole 406 is positioned on the lower side of the fan 402, a conveyor belt 401 is connected with the bottom end of the inner side of the discharging hole 406 in a penetrating manner, the front side of the discharging component 4 is connected with a second rotating motor 403 in a penetrating manner, the second rotating motor 403 is in transmission connection with the conveyor belt 401, a supporting plate 405 is fixedly welded on the inner side of the discharging component 4, the supporting plate 405 is attached to the upper end of the inner side of the conveyor belt 401, one end of the conveyor belt 401 is connected with a supporting frame 404 in a rotating manner, and the supporting frame 404 is positioned on the other end of the conveyor belt 401 opposite to the second rotating motor 403;

when glass is cut, the fan 402 can drive the flow of air, blows the glass slag on the upper side of the operating platform 109 in the cutting box 1 to the inner side of the waste collection box 106, and the second rotating motor 403 drives the conveying belt 401 to rotate, further drives the glass placed on the upper side of the conveying belt 401 to move, and discharges the glass through the discharge hole 406.

The working principle of the embodiment is as follows: the operator inserts glass into the feeding hole 101 to attach the glass to the upper side of the operation table 109, the inner side of the cutting box 1 can be cut by the transparent PVC plate 103, and corresponding operation is performed, during cutting, the first driving motor 205 drives the first threaded rod 203 to rotate, the first sliding block 204 moves left and right along the first threaded rod 203, the first moving component 202 moves the laser cutting knife 2 back and forth, the laser cutting knife 2 moves to the cutting position, the first lifting cylinder 201 drives the laser cutting knife 2 to move downwards, the extrusion positioning wheel 206 is attached to the surface of the glass and moves upwards through the upward sliding of the limiting rod 211 when one part moves downwards, the extrusion positioning wheel 206 and the glass are extruded by the extrusion spring 210, the glass is rapidly cut by the laser cutting knife 2, and the fan 402 drives the air to flow during cutting, the flowing air blows the glass slag on the surface of the operation table 109 into the waste collection box 106 through the ventilation opening 110, the air is blown out through the ceramic filter element 107, the cutting box 1 and the rotating cover 102 limit the splashed glass slag, after one glass is cut, the second driving motor 3 drives the second threaded rod 301 to rotate, the second sliding block 302 moves left and right along the second threaded rod 301, the second moving component 303 drives the air pump 305 and the sucker 306 to move back and forth, the sucker 306 hangs on the upper end of the cut glass, the second lifting cylinder 304 drives the air pump 305 and the sucker 306 to move downwards until the sucker 306 is pressed and attached to the surface of the glass, the air between the glass and the sucker 306 is pumped out through the air pump 305, the glass is adsorbed on the bottom side of the sucker 306, the glass is driven to the upper side of the conveyor 401 through the second driving motor 3, the air pump 305 inflates the space between the sucker 306 and the glass, the glass falls onto the surface of the conveying belt 401, the conveying belt 401 is driven to rotate by the second rotating motor 403, the glass placed on the upper side of the conveying belt 401 is further driven to move, and the glass is discharged through the discharge hole 406, after all the glass is cut and discharged, the operating table 109 is driven by the first rotating motor 104 to rotate downwards, so that leftover materials remained on the operating table 109 fall into the waste collection box 106 under the action of gravity, and workers draw out the waste collection box 106 to perform centralized treatment on the waste.

The foregoing is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, and any modification, equivalent replacement, and improvement of some of the technical features described in the foregoing embodiments are all within the scope of the present utility model.

Claims

1. Cutting device is used in toughened glass processing, including cutting case (1), laser cutting knife (2), second driving motor (3) and ejection of compact subassembly (4), its characterized in that: the cutting box is characterized in that operation tables (109) are rotatably clamped at two ends of the inner side of the cutting box (1), a laser cutting knife (2) is arranged on the inner side of the cutting box (1), extrusion positioning wheels (206) are arranged around the laser cutting knife (2), a discharging component (4) is arranged on one side of the cutting box in a penetrating mode, a conveying belt (401) is rotatably clamped at the bottom end of the inner side of the discharging component (4), a second driving motor (3) is fixedly clamped at one side of the discharging component (4), an air pump (305) is arranged at one side of the second driving motor (3), and a sucker (306) is arranged on the bottom end of the air pump (305) in a penetrating mode.

2. The cutting device for tempered glass processing according to claim 1, wherein: feed inlet (101) have been seted up in running through of cutting case (1) front side, feed inlet (101) laminating in operation panel (109) upside, feed inlet (101) inboard joint has rotation lid (102), cutting case (1) front side runs through the joint has transparent PVC board (103), transparent PVC board (103) are located feed inlet (101) upside.

3. The cutting device for tempered glass processing according to claim 1, wherein: the utility model discloses a cutting box, including cutting box (4) and operation panel, including operation panel (109), vent (110) have been seted up to operation panel (109) one end joint has first rotation motor (104), vent (110) are located first rotation motor (104) one side of operation panel (109), first rotation motor (104) run through the joint in cutting box (1) one side, first rotation motor (104) are located cutting box (1) opposite side for ejection of compact subassembly (4).

4. The cutting device for tempered glass processing according to claim 1, wherein: the cutting box (1) one side runs through the welding has first screwed pipe (105), first screwed pipe (105) outer peripheral face has connect soon second screwed pipe (108), second screwed pipe (108) one end runs through the joint has ceramic filter core (107), ceramic filter core (107) run through and peg graft in first screwed pipe (105) inboard, ceramic filter core (107) are located operation panel (109) downside, cutting box (1) front side runs through and peg graft there is waste collection box (106), waste collection box (106) are located ceramic filter core (107) downside.

5. The cutting device for tempered glass processing according to claim 1, wherein: the utility model provides a laser cutting knife (2) upside joint is fixed with link (207), link (207) upside slip joint has first lift cylinder (201), first lift cylinder (201) upside slip joint has first removal subassembly (202), first removal subassembly (202) upside joint is fixed with first slider (204), first slider (204) one side is run through and is screwed first threaded rod (203), first threaded rod (203) one end rotation joint has first driving motor (205), first driving motor (205) joint is fixed in cutting box (1) for ejection of compact subassembly (4) opposite side, first threaded rod (203) run through grafting in cutting box (1) one end, laser cutting knife (2) overhang in operation panel (109).

6. The cutting device for tempered glass processing as claimed in claim 5, wherein: the extrusion positioning wheel (206) upside joint has rotating assembly (208), rotating assembly (208) upside rotates the joint and has connecting plate (209), connecting plate (209) upside central authorities welded fastening has gag lever post (211), connecting plate (209) upper side edge joint has extrusion spring (210), gag lever post (211) run through the slip and connect in link (207) downside, extrusion spring (210) upper end joint is in link (207) downside.

7. The cutting device for tempered glass processing according to claim 1, wherein: the utility model discloses a cutting box, including cutting box (1), second drive motor (3), second drive motor (301) outer peripheral runs through and connects soon has second slider (302), second slider (302) bottom joint is fixed with second removal subassembly (303), second removal subassembly (303) bottom slip joint has second lift cylinder (304), air pump (305) slip joint in second lift cylinder (304) bottom side, second drive motor (3) are located discharging component (4) for cutting box (1) other end, second drive motor (301) run through and peg graft in discharging component (4) one side, second drive motor (301) rotate the joint in cutting box (1) inboard for discharging component (4) other end.

8. The cutting device for tempered glass processing according to claim 1, wherein: the utility model discloses a cutting box, including cutting box (1) and conveyer belt (401), discharging component (4) are located cutting box (1) and are equipped with fan (402) in the joint, fan (402) are located discharging component (4) opposite side, discharging component (4) one side is run through and is offered discharge gate (406), discharge gate (406) are located fan (402) downside, conveyer belt (401) run through and peg graft in the inboard bottom of discharge gate (406), discharging component (4) front side runs through the joint and has second rotation motor (403), second rotation motor (403) and conveyer belt (401) transmission are connected, discharging component (4) inboard welded fastening has backup pad (405), backup pad (405) laminating is in conveyer belt (401) inboard upper end, conveyer belt (401) one end rotation joint has support frame (404), support frame (404) are located conveyer belt (401) other end for second rotation motor (403).