CN113912276A

CN113912276A - Glass processing technology

Info

Publication number: CN113912276A
Application number: CN202111202685.4A
Authority: CN
Inventors: 余虹瑾
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-10-15
Filing date: 2021-10-15
Publication date: 2022-01-11

Abstract

The invention relates to the technical field of glass processing, in particular to a glass processing technology, which comprises the following steps: the method comprises the following steps: placing the glass on a glass processing device, and positioning the glass; step two: selecting a glass transportation position according to the width of the glass after detecting the width of the glass; step three: carrying out flaw detection on the qualified glass; step four: the traceless glass is collected in a concentrated mode, the scratched glass is transported to the other position to be collected in a concentrated mode, the unqualified glass is collected in a concentrated mode after being transported, and the glass with the surplus, the glass with the notch and the qualified glass are distinguished, so that different glass can be treated by different treatment methods conveniently, the quality of the glass is improved, and meanwhile the benefit is improved.

Description

Glass processing technology

Technical Field

The invention relates to the technical field of glass processing, in particular to a glass processing technology.

Background

The glass is classified into quartz glass, silicate glass, soda-lime glass, fluoride glass, high-temperature glass, high-pressure glass, ultraviolet-proof glass, explosion-proof glass and the like. Generally, silicate glass is prepared by taking quartz sand, soda ash, feldspar, limestone and the like as raw materials, mixing, melting at high temperature, homogenizing, processing and forming, and annealing, and is widely applied to the fields of buildings, daily use, art, medical treatment, chemistry, electronics, instruments, nuclear engineering and the like.

Disclosure of Invention

The invention aims to provide a glass processing technology which can detect the width of glass so as to distinguish and process the glass.

The purpose of the invention is realized by the following technical scheme:

a glass-working process, the process comprising the steps of:

the method comprises the following steps: placing the glass on a glass processing device, and positioning the glass;

step two: selecting a glass transportation position according to the width of the glass after detecting the width of the glass;

step three: carrying out flaw detection on the qualified glass;

step four: and (4) carrying out centralized collection on traceless glass, transporting the scratched glass to another position for centralized collection, and transporting the unqualified glass for centralized collection.

The glass processing device comprises a support frame I, a placing groove, a feeding groove, a moving frame, a detection roller and a conveying plate, the gag lever post, the transportation pole, the dwang, the connecting plate, telescopic link and ring, be provided with the standing groove on the support frame I, be provided with the feed chute on the support frame I, communicate between feed chute and the standing groove, two equal sliding connection of carriage are on support frame I, all rotate on two carriages and be connected with a plurality of detection rollers, transportation board sliding connection is on support frame I, the gag lever post passes through pneumatic cylinder I and installs on support frame I, transportation pole lateral sliding connection is on support frame I, two dwangs rotate respectively and connect on two carriages, two dwangs all rotate and connect on the connecting plate, telescopic link fixed connection is at the lower extreme of transportation board, the lower extreme fixed connection of telescopic link is on the connecting plate, ring fixed connection is on the telescopic link, be equipped with spring I between ring and the connecting plate.

Glass processingequipment includes roof, bottom plate and connecting plate II, and roof fixed connection is on connecting plate II, and roof sliding connection is on support frame I, and bottom plate sliding connection is equipped with spring III between bottom plate and the support frame I on support frame I, and connecting plate II is installed through pneumatic cylinder III and is made connecting plate II can longitudinal movement on support frame I, keeps the level between bottom plate and the support frame I.

The glass processing device comprises a support frame II, limiting rods, a detection frame, magnetic plates, hook plates, pressure rods, rotating wheels, a trigger frame, trigger sliders, limiting chutes, blocking rollers, a blocking frame, a driving slider and a driving magnetic plate, wherein the support frame II is fixedly connected to the upper end of the support frame I, the support frame II is fixedly connected with the two limiting rods, the detection frame is slidably connected to the support frame II, the two hook plates are fixedly connected to the detection frame, the magnetic plates are arranged at the left end and the right end of the detection frame, the pressure rods are uniformly slidably connected to the detection frame, springs IV are arranged between the pressure rods and the detection frame, the lower ends of the pressure rods are respectively rotatably connected with the rotating wheels, the two trigger frames are respectively slidably connected to the detection frame, the moving directions of the two trigger frames are opposite, the two trigger frames are respectively slidably connected with the trigger sliders, and the limiting chutes are arranged on the trigger sliders, all be equipped with spring VI between a plurality of trigger slide blocks and two trigger framves, stop the roller and rotate to connect on stopping the frame, stop a sliding connection on support frame II, stop to be equipped with two spring V between frame and the support frame II, two equal sliding connection of drive slide block are on support frame I, all are provided with the drive magnetic sheet on two drive slide blocks, two drive magnetic sheets respectively with two magnetic sheets between inhale mutually, keep the level between roof and the support frame II.

Glass processingequipment is including transportation frame and rotor plate, and the rotor plate articulates on the transportation frame, and the rotor plate can only rotate backward, and transportation frame sliding connection all is provided with magnet at both ends about the transportation frame, and two magnets attract with two drive magnetic plates respectively mutually, are equipped with the torsional spring between rotor plate and the transportation frame, are equipped with two baffles on the support frame I and make the transportation frame can only remove backward.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a flow diagram of a glass processing process of the present invention;

FIG. 2 is a schematic diagram of the moving frame of the present invention;

FIG. 3 is a schematic view of a transport plate according to the present invention;

FIG. 4 is a schematic view of a support frame I of the present invention;

FIG. 5 is a schematic view of a connection plate II of the present invention;

FIG. 6 is a schematic top plan view of the present invention;

FIG. 7 is a schematic view of the inspection frame of the present invention;

FIG. 8 is a schematic view of a resist roll of the present invention;

FIG. 9 is a schematic view of the trigger slide of the present invention;

FIG. 10 is a schematic view of the hook plate of the present invention;

FIG. 11 is a schematic view of a support frame II according to the present invention;

FIG. 12 is a schematic view of a drive block of the present invention;

FIG. 13 is a general view of the present invention.

In the figure:

a support frame I1; a placement groove 101; a feed chute 102; a moving frame 11; a detection roller 12; a transport plate 13; a stopper rod 14; a transport bar 15; turning the levers 16; a connecting plate 17; a telescopic rod 18; a circular ring 181;

a top plate 21; a base plate 22; a connecting plate II 23;

a support frame II 3; a stopper rod 301; a detection frame 31; a magnetic plate 311; a hook plate 32; a pressure lever 33; a rotating wheel 34; a trigger frame 35; the trigger slider 36; a limit chute 361; the resist roller 37; a blocking frame 38; a driving slider 39; a drive magnetic plate 391;

a transport frame 41; the plate 42 is rotated.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1;

a glass-working process, the process comprising the steps of:

step three: carrying out flaw detection on the qualified glass;

As shown in fig. 2-4;

the glass processing technology further uses a glass processing device, the device comprises a support frame I1, a placing groove 101, a feeding groove 102, moving frames 11, detection rollers 12, a conveying plate 13, a limiting rod 14, a conveying rod 15, rotating rods 16, a connecting plate 17, a telescopic rod 18 and a circular ring 181, the placing groove 101 is arranged on the support frame I, the feeding groove 102 is communicated with the placing groove 101, the two moving frames 11 are both connected to the support frame I1 in a sliding mode, the two moving frames 11 are both connected to the plurality of detection rollers 12 in a rotating mode, the conveying plate 13 is connected to the support frame I1 in a sliding mode, the limiting rod 14 is installed on the support frame I1 through a hydraulic cylinder I, the conveying rod 15 is connected to the support frame I1 in a transverse sliding mode, the two rotating rods 16 are respectively connected to the two moving frames 11 in a rotating mode, the two rotating rods 16 are both connected to the connecting plate 17 in a rotating mode, the telescopic rod 18 is fixedly connected to the lower end of the conveying plate 13, the lower end of the telescopic rod 18 is fixedly connected to the connecting plate 17, the circular ring 181 is fixedly connected to the telescopic rod 18, and a spring I is arranged between the circular ring 181 and the connecting plate 17;

the transport rod 15 is driven by the hydraulic cylinder II to enable the transport rod 15 to move transversely, the hydraulic cylinder II is fixedly connected to the support frame I1, and the transport rod 15 is fixedly connected to the hydraulic cylinder II;

glass can be used after being cut usually when being processed, but the glass can be easily cut by a machine, the glass can not be cut sufficiently or the size is wrong, so that the width of the cut glass can be detected when the glass is used, the qualified glass can be directly put into use, the condition that the size is unqualified and secondary processing is needed is avoided, the glass is inserted into the placing groove 101 through the feeding groove 102, one end of the glass is in contact with the inner wall of the placing groove 101, the glass is kept horizontal, the connecting plate 17 moves upwards to drive the telescopic rod 18 to move upwards, the telescopic rod 18 moves upwards to drive the conveying plate 13 to move upwards, the conveying plate 13 moves upwards to drive the glass to move upwards, the conveying plate 13 and the support frame I1 are kept horizontal, and the glass is positioned at the upper end of the horizontal plane of the support frame I1, the connecting plate 17 moves upwards to enable the two rotating rods 16 to rotate, the two rotating rods 16 rotate to drive the two moving frames 11 to move towards the middle, the two moving frames 11 move towards the middle to drive the plurality of detection rollers 12 to move towards the middle, the two detection rollers 12 move towards the middle to be in contact with the left end and the right end of glass, the width of the glass is detected through the distance between the two moving frames 11, the glass can be detected to be too wide in size or the left end and the right end of the glass are left with scraps and not fall off, a worker can selectively perform secondary cutting conveniently, the glass can smoothly move backwards to be separated from the plurality of detection rollers 12 through the contact between the plurality of detection rollers 12 and the glass, the friction between the glass and the device is reduced, and the service life of the device is prolonged;

further, restrict glass through transportation pole 15 and gag lever post 14, it is irregular to avoid controlling both ends behind the glass cutting, cause glass to rotate when a plurality of detection rollers 12 and glass contact and lead to the testing result accurate inadequately, restrict glass through transportation pole 15 and gag lever post 14, make glass remain the level all the time, can not take place to rotate, make the testing result accurate, after the completion is to glass's detection, gag lever post 14 upwards removes and loses the restriction to glass, remove through transportation pole 15 and promote glass and remove, accomplish the transportation to glass.

As shown in fig. 5-6;

the glass processing device further comprises a top plate 21, a bottom plate 22 and a connecting plate II 23, wherein the top plate 21 is fixedly connected to the connecting plate II 23, the top plate 21 is connected to the support frame I1 in a sliding mode, the bottom plate 22 is connected to the support frame I1 in a sliding mode, a spring III is arranged between the bottom plate 22 and the support frame I1, the connecting plate II 23 is installed on the support frame I1 through a hydraulic cylinder III to enable the connecting plate II 23 to move longitudinally, and the bottom plate 22 and the support frame I1 are kept horizontal;

in order to distinguish qualified and unqualified glass after the detection, distinguish glass through roof 21 and bottom plate 22, roof 21 moves down and drives bottom plate 22 and move down when glass is qualified, make roof 21 and I1 level of support frame, at this moment, transport pole 15 removes and promotes glass and move and push away glass to roof 21 on, roof 21 drives glass rebound afterwards, make qualified glass move to the top, and when the glass width was too wide, roof 21 can't move down and drive bottom plate 22 and move down, at this moment, glass will move to on bottom plate 22, let unqualified glass be located the below, thereby distinguish qualified and unqualified glass and collect, thereby be convenient for carry out secondary treatment to unqualified glass, improve the sufficient quality of glass cutting.

As shown in fig. 7-10;

the glass processing device also comprises a support frame II 3, limiting rods 301, a detection frame 31, magnetic plates 311, hook plates 32, pressure rods 33, rotating wheels 34, a trigger frame 35, a trigger slider 36, a limiting sliding chute 361, a blocking roller 37, a blocking frame 38, a driving slider 39 and a driving magnetic plate 391, wherein the support frame II 3 is fixedly connected to the upper end of the support frame I1, two limiting rods 301 are fixedly connected to the support frame II 3, the detection frame 31 is slidably connected to the support frame II 3, the two hook plates 32 are both fixedly connected to the detection frame 31, the magnetic plates 311 are arranged at the left end and the right end of the detection frame 31, the pressure rods 33 are uniformly and slidably connected to the detection frame 31, springs IV are arranged between the pressure rods 33 and the detection frame 31, the lower ends of the pressure rods 33 are respectively and rotatably connected to the rotating wheels 34, the two trigger frames 35 are both slidably connected to the detection frame 31, and the moving directions of the two trigger frames 35 are opposite, the two trigger frames 35 are both connected with a plurality of trigger sliding blocks 36 in a sliding manner, the plurality of trigger sliding blocks 36 are both provided with limiting sliding chutes 361, springs VI are arranged between the plurality of trigger sliding blocks 36 and the two trigger frames 35, the blocking roller 37 is rotationally connected to the blocking frame 38, the blocking frame 38 is connected to the support frame II 3 in a sliding manner, two springs V are arranged between the blocking frame 38 and the support frame II 3, the two driving sliding blocks 39 are both connected to the support frame I1 in a sliding manner, the two driving sliding blocks 39 are both provided with driving magnetic plates 391, the two driving magnetic plates 391 are respectively attracted with the two magnetic plates 311, and the top plate 21 and the support frame II 3 are kept horizontal;

the two trigger frames 35 are driven by the driving assembly to enable the two trigger frames 35 to move transversely and have opposite moving directions, the driving assembly consists of a lead screw and a speed reducing motor, the speed reducing motor is fixedly connected to the detection frame 31, the lead screw is rotatably connected to the detection frame 31, the lead screw is fixedly connected to an output shaft of the speed reducing motor, and the lead screw and the two trigger frames 35 are in threaded transmission;

the two driving sliding blocks 39 are respectively driven by two hydraulic cylinders IV, the two hydraulic cylinders IV are both fixedly connected to the support frame II 3, and the two driving sliding blocks 39 are respectively fixedly connected to the two hydraulic cylinders IV;

the device can also carry out wound detection on glass with qualified width, avoid the situation that the left and right ends of the glass are cracked to generate gaps due to cutting, timely recover the glass with defects, use the glass for other places after processing, improve the qualification rate of the outgoing glass, avoid causing unnecessary waste, drive the glass to move upwards by the top plate 21, enable the top plate 21 and the support frame II 3 to be horizontal, enable the glass to be positioned between the two trigger frames 35, only detect the glass with qualified width, thereby improving the detection efficiency, shorten the detection time, drive the plurality of trigger sliders 36 to move towards the middle by the movement of the two trigger frames 35, move towards the middle and uniformly contact with the left and right ends of the glass, when the glass has no gaps, the plurality of trigger sliders 36 at the two ends are respectively positioned on two parallel lines, and then the plurality of limiting chutes 361 are respectively aligned with the two limiting rods 301, at the moment, the two hook plates 32 are driven to move by the movement of the detection frame 31, the hook plate 32 at the rear end drives the glass plate to move, and the plurality of limiting chutes 361 can pass through the two limiting rods 301, so that the hook plate 32 at the rear end drives the glass plate to move to the front section of the support frame II 3, and the qualified products can be conveniently collected in a centralized manner;

further, in order to fully detect the left end and the right end of the glass, the glass is blocked by the blocking roller 37, at this time, the two triggering frames 35 drive the plurality of triggering sliders 36 to move forwards, so that the plurality of triggering sliders 36 move along the left end and the right end of the glass to fully detect, if no gap exists, the glass is extruded by the plurality of pressing rods 33 and the plurality of rotating wheels 34, and is tightly attached to the support frame II 3, at this time, the hook plate 32 at the rear end drives the glass to move, so that the glass presses the blocking roller 37 to move downwards, the blocking roller 37 moves downwards to drive the blocking frame 38 to move downwards, so that the glass can be smoothly collected by the blocking roller 37, the plurality of rotating wheels 34 and the glass are firm, so that the plurality of pressing rods 33 can press the glass, when the glass is tightly attached to the support frame II 3, the plurality of pressing rods 33 can also move, and the glass is not driven to move, so as to reduce friction force, the glass is prevented from being damaged;

furthermore, if the glass generates a notch in the cutting process, the corresponding trigger slide block 36 is acted by the spring VI to make the trigger slide block 36 move, at this time, the position of the limit chute 361 on the trigger slide 36 is changed, and is not on the same straight line with the limit rod 301, when the two trigger frames 35 drive the plurality of trigger sliders 36 to move, the trigger sliders 36 cannot pass through the limiting rod 301 due to the movement, so that the two trigger frames 35 can not move continuously, then the detection frame 31 drives the two hook plates 32 to move reversely, the hook plate 32 at the front section drives the glass to move backwards, the glass is transported to the rear end of the support frame II 3, at this time, the glass with qualified width but with gap can not be processed for the second time for normal use, but can be used in other places to distinguish and collect different kinds of glass, so that workers can distinguish and process the glass conveniently;

further, two driving magnetic plates 391 are driven to move through the movement of the two driving sliders 39, the two driving magnetic plates 391 and the two magnetic plates 311 are attracted, the two driving magnetic plates 391 and the two magnetic plates 311 are driven to move through magnetic force when the two driving magnetic plates 391 move forwards, when the trigger slider 36 is clamped by the limiting rod 301, the two magnetic plates 311 cannot move, the two driving magnetic plates 391 and the two magnetic plates 311 are separated, the detection frame 31 cannot move, the two driving sliders 39 can normally move, then the two driving sliders 39 move in the reverse direction, the two driving magnetic plates 391 and the two magnetic plates 311 are attracted, then the detection frame 31 can move backwards again, and then resetting is carried out.

As shown in fig. 11-12;

the glass processing device further comprises a transportation frame 41 and a rotating plate 42, wherein the rotating plate 42 is hinged to the transportation frame 41, the rotating plate 42 can only rotate backwards, the transportation frame 41 is connected to the support frame I1 in a sliding mode, magnets are arranged at the left end and the right end of the transportation frame 41, the two magnets are respectively attracted to the two driving magnetic plates 391, a torsion spring is arranged between the rotating plate 42 and the transportation frame 41, and two baffles are arranged on the support frame I1 to enable the transportation frame 41 to only move backwards;

the glass having a width exceeding the normal size, which is cut by mistake, stays on the bottom plate 22, and first contacts the rotating plate 42 to rotate the rotating plate 42, so that the glass is positioned in the transporting frame 41, when the glass stays on the bottom plate 22, the two driving magnetic plates 391 attract the two magnets, respectively, the transporting frame 41 cannot move forward, the two driving magnetic plates 391 normally perform a forward movement, come into contact with the two magnets again when the two driving magnetic plates 391 move reversely, thereby driving the transportation frame 41 to move, the transportation frame 41 to move drives the rotating plate 42 to move, the rotating plate 42 cannot rotate forwards at the moment, the rotating plate 42 drives the glass to move backwards on the support frame I1, therefore, the three kinds of glass under different conditions are distinguished, different kinds of glass are transported to different positions to be collected in a centralized manner, and workers can select different treatment methods according to the states of the glass conveniently.

Claims

1. A glass processing technology is characterized in that: the process comprises the following steps:

step three: carrying out flaw detection on the qualified glass;

2. The glass-working process of claim 1, wherein: glass processingequipment includes support frame I (1), is equipped with standing groove (101) on support frame I (1), and sliding connection has transport plate (13) on support frame I (1), and sliding connection has two to remove frame (11) on support frame I (1), all rotates on two removal frames (11) and is connected with a plurality of detection roller (12).

3. A glass-working process according to claim 2, characterized in that: sliding has transportation pole (15) on support frame I (1), installs gag lever post (14) that can longitudinal movement through two pneumatic cylinders on support frame I (1).

4. A glass-working process according to claim 3, characterized in that: glass processing device still includes roof (21), bottom plate (22) and connecting plate II (23), and connecting plate II (23) sliding connection is on support frame I (1), and roof (21) are fixed on support frame I (1), and bottom plate (22) sliding connection is on support frame I (1), is equipped with spring II between bottom plate (22) and the support frame I (1).

5. A glass-working process according to claim 2, characterized in that: glass processingequipment still includes support frame II (3), and support frame II (3) are fixed on support frame I (1), and it has test rack (31) to slide on support frame II (3), and it has two to trigger frame (35) to slide on test rack (31), and equal sliding connection has a plurality of trigger block (36) on two trigger frame (35), and a plurality of trigger block (36) are the rhombus post.

6. The glass-working process of claim 5, wherein: and a blocking frame (38) is connected onto the supporting frame II (3) in a sliding manner, and a blocking roller (37) is rotated on the blocking frame (38).

7. A glass-working process according to claim 6, characterised in that; a plurality of pressure levers (33) slide on the detection frame (31), all rotate on a plurality of pressure levers (33) and have a runner (34), are fixed with two on the detection frame (31) and collude board (32).

8. The glass-working process of claim 5, wherein: two limiting rods (301) are fixed on the support frame II (3), and limiting sliding grooves (361) are formed in the plurality of trigger sliding blocks (36).

9. The glass-working process of claim 5, wherein: the glass processing device further comprises driving sliding blocks (39), the two driving sliding blocks (39) are connected to the support frame I (1) in a sliding mode, the two driving sliding blocks (39) are provided with driving magnetic plates (391), the detection frame (31) is fixed with two magnetic plates (311), and the two magnetic plates (311) are attracted to the two driving magnetic plates (391) respectively.

10. A glass-working process according to claim 9, wherein: the glass processing device further comprises a transportation frame (41), the transportation frame (41) is connected to the support frame I (1) in a sliding mode, the transportation frame (41) is hinged to a rotating plate (42) which can only rotate backwards, magnets are arranged at the left end and the right end of the transportation frame (41), and the two magnets attract with the two driving magnetic plates (391) respectively.