阅读说明：本技术 一种防脱胶夹层玻璃生产方法 (Production method of anti-adhesive-release laminated glass ) 是由 孙斌 于 2021-09-02 设计创作，主要内容包括：本发明涉及防脱胶夹层玻璃生产领域,公开了一种防脱胶夹层玻璃生产方法,该防脱胶夹层玻璃生产方法使用了防脱胶夹层玻璃生产设备,该防脱胶夹层玻璃生产设备包括工作箱体,所述工作箱体一侧开设有第一进料口,所述工作箱体另一侧开设有第一出料口,所述第一进料口与第二进料口上设有输送部件,所述工作箱体内部对称设有两组夹持调整部件,所述工作箱体内部靠近第一出料口一侧设有密封部件,所述工作箱体内对称设有两组烘干部件,避免了在夹层玻璃生产过程中因内部水分或空气过多引起开胶的现象。(The invention relates to the production field of anti-degumming laminated glass, and discloses a production method of the anti-degumming laminated glass, which uses anti-degumming laminated glass production equipment, wherein the anti-degumming laminated glass production equipment comprises a working box body, one side of the working box body is provided with a first feed inlet, the other side of the working box body is provided with a first discharge outlet, the first feed inlet and the second feed inlet are provided with conveying parts, two groups of clamping and adjusting parts are symmetrically arranged inside the working box body, one side of the working box body, which is close to the first discharge outlet, is provided with a sealing part, and two groups of drying parts are symmetrically arranged inside the working box body, so that the phenomenon of degumming caused by excessive internal moisture or air in the production process of the laminated glass is avoided.)

1. The production method of the anti-glue-dropping laminated glass uses anti-glue-dropping laminated glass production equipment, the anti-glue-dropping laminated glass production equipment comprises a working box body (1), a first feeding hole (101) is formed in one side of the working box body (1), a first discharging hole (102) is formed in the other side of the working box body (1), a conveying part (2) is arranged between the first feeding hole (101) and the second feeding hole (102), two groups of clamping and adjusting parts (3) are symmetrically arranged in the working box body (1), a sealing part (4) is arranged in one side, close to the first discharging hole (102), of the inner part of the working box body (1), and two groups of drying parts (5) are symmetrically arranged on two sides of the sealing part (4).

2. The production method of the anti-adhesive interlayer glass according to claim 1, characterized in that: the conveying component (2) comprises a conveying track (201), and a conveying belt (202) is arranged in the conveying track (201).

3. The production method of the anti-adhesive interlayer glass according to claim 2, characterized in that: centre gripping adjusting part (3) are including symmetry setting at first sliding base (304) of work box (1) inner wall, every it is equipped with first slip telescopic link (305) to slide in first sliding base (304), first slip telescopic link (305) other end vertical direction is equipped with first slide bar (301), first slip track (313) have been seted up in first slide bar (301), it is equipped with first slider (303) to slide in first slip track (313), be equipped with squeeze roll (302) between first slider (303), it has first gas transmission groove (312) to open in squeeze roll (302), first bearing bar (307) have set firmly between first slip telescopic base (304), first bearing bar (307) other end rotates and is equipped with grip block (319).

4. The production method of the anti-adhesive interlayer glass according to claim 3, characterized in that: the clamping and adjusting component (3) also comprises a second gas transmission groove (310) arranged in the first bearing rod (307), two heating gas transmission box bodies (306) are fixedly arranged on two sides of the working box body (1), the first gas transmission groove (310) is communicated with the heating gas transmission box bodies (306), a first sliding groove (316) is formed in the clamping block (319), the first sliding groove (316) is communicated with the second gas transmission groove (310), a heating block (315) is arranged on the first sliding groove (316) in a sliding manner, a first spring (317) for resetting is arranged between the heating block (315) and the first sliding groove (316), two third gas transmission grooves (314) are symmetrically arranged on two sides of the first sliding groove (316), the other end of the third gas transmission groove is provided with a vacuumizing box body (311), and the first gas transmission groove (312) is communicated with the heating gas transmission box body (306) through a first sliding rod (301).

5. The production method of the anti-adhesive interlayer glass according to claim 4, characterized in that: the sealing part (4) comprises two first bearing rods (401) arranged in the vertical direction in the working box body (1), a first glue absorption groove (408) is formed in each first bearing rod (401), a collection box body (440) is fixedly arranged on the outer side of the working box body (1), a first collection cavity (409) is formed in each bearing rod (401), the first collection cavity (409) is communicated with the collection box body (440), a second collection cavity (403) is slidably arranged on each first bearing rod (401), a second spring (424) for resetting is arranged between each second collection cavity (403) and the inner wall of the working box body (1), two second glue absorption holes (407) are symmetrically formed in two sides of each second collection cavity (403), each second glue absorption groove (407) is communicated with the corresponding first glue absorption groove (408), a first rotating rod (404) is rotatably arranged on one side, far away from the first bearing rod (401), of each second collection cavity (403), the other end of the first rotating rod (404) is provided with a convex block (405), a third glue sucking groove (406) is formed in the convex block (405) close to one side of the clamping adjusting component (3), one end of the third glue sucking groove (406) is communicated with the second glue sucking hole (407), the other end of the third glue sucking groove (406) extends to the edge of the convex block (405), and a vibrating component (425) is arranged at the edge of the convex block (405).

6. The production method of the anti-adhesive interlayer glass according to claim 5, characterized in that: the sealing component (4) further comprises a second sliding telescopic base (414) rotatably arranged on the side wall of the second collection cavity (403) close to one side of the clamping and adjusting component (3), a second sliding telescopic rod (416) is slidably arranged in the second sliding telescopic base (414), the other end of the second sliding telescopic rod (416) is rotatably connected with the side wall of the other collection cavity (403), a second sliding groove (415) is formed in one side, close to the lug (405), of the second sliding telescopic base (414), a second sliding rod (417) is slidably arranged on the second sliding groove (415), a first glue outlet groove (413) is formed in the second sliding rod (417), one end of the first glue outlet groove (413) leads to a small glue outlet (411) in one side of the lug (405), glue is fed outside, a large glue outlet (412) is formed in the side wall of the second sliding rod (417), a fourth glue suction groove (422) is formed in the flat end face of the other lug (405), the fourth glue suction groove (422) is connected with the third glue suction groove (406).

7. The production method of the anti-adhesive interlayer glass according to claim 6, characterized in that: the vibration part (425) comprises a first vent hole (410) communicated with the third glue sucking groove (406), the first vent hole (410) is connected with a first rotating cavity (427), one side in the first rotating cavity (427) is provided with a first bearing (434), the first bearing (434) is provided with a second rotating rod (418) in a rotating way, one end of the second rotating rod (418) is fixedly provided with a first spiral fan blade (426), the other end of the second rotating rod (418) is connected with a large belt pulley (436), one side of the first rotating cavity (427), which is far away from the first vent hole (410), is provided with a second rotating cavity (439), a second bearing (419) is arranged in the second rotating cavity (439), the second bearing (419) is provided with a third rotating rod (430) in a rotating way, one end of the third rotating rod (430) is provided with a small belt pulley (438), the large belt pulley (436) is connected with the small belt (437), the other end of the third rotating rod (430) is fixedly provided with a cam (429), a third sliding groove (432) is formed in the second rotating cavity (439), a second sliding block (431) is arranged in the third sliding groove (432) in a sliding manner, a third spring (428) used for resetting is arranged between the second sliding block (431) and the third sliding groove (432), and the other end of the second sliding block (432) is provided with a plurality of soft contact rods (433) which are uniformly distributed.

8. The production method of the anti-adhesive interlayer glass according to claim 7, characterized in that: the drying component (5) comprises a drying box body (504) which is arranged on the outer side of the working box body (1) and is symmetrically arranged on two sides of the first discharge hole (102), a drying pipe (501) is fixedly arranged in the working box body (1) and is connected with the drying box body (504), a drying groove (505) is formed in the drying pipe (501), and a second spiral blade (502) is arranged in the drying pipe (501).

Technical Field

The invention relates to the production field of anti-adhesive interlayer glass, in particular to a production method of the anti-adhesive interlayer glass.

Background

The laminated glass is a composite glass product which is formed by two or more pieces of glass, wherein one or more layers of organic polymer intermediate films are sandwiched between the two or more pieces of glass, and the glass and the intermediate films are permanently bonded into a whole after special high-temperature prepressing (or vacuumizing) and high-temperature high-pressure processing.

In the production process, a large amount of water or air exists in the laminated glass, so that the laminated glass can be separated from the adhesive in a short time, the using effect is seriously influenced, the protective effect of the laminated glass can be lost after the laminated glass is impacted, and the danger is brought, so that the laminated glass has the need of improvement.

Disclosure of Invention

The invention aims to provide a production method of anti-adhesive interlayer glass, which aims to solve the problems in the background technology.

The invention is realized by the following modes: the production method of the anti-adhesive-separation laminated glass uses anti-adhesive-separation laminated glass production equipment which comprises a working box body, wherein a first feeding hole is formed in one side of the working box body, a first discharging hole is formed in the other side of the working box body, a conveying part is arranged between the first feeding hole and the second feeding hole, two groups of clamping and adjusting parts are symmetrically arranged inside the working box body, a sealing part is arranged in the working box body and close to one side of the first discharging hole, and two groups of drying parts are symmetrically arranged on two sides of the sealing part.

The conveying part comprises a conveying rail, and a conveying belt is arranged in the conveying rail.

The clamping adjustment component comprises a first sliding base and a first sliding rail, the first sliding base is symmetrically arranged on the inner wall of the working box body, the first sliding base is internally provided with a first sliding telescopic rod in a sliding mode, the other end of the first sliding telescopic rod is provided with a first sliding rod in the vertical direction, a first sliding rail is arranged in the first sliding rod, a first sliding block is arranged in the first sliding rail in a sliding mode, an extrusion roller is arranged between the first sliding blocks, a first gas transmission groove is formed in the extrusion roller, a first bearing rod is fixedly arranged between the first sliding telescopic base, and the other end of the first bearing rod is provided with a clamping block in a rotating mode.

The clamping adjustment component further comprises a second gas transmission groove formed in the first bearing rod, two heating gas transmission boxes are fixedly arranged on two sides of the working box body, the first gas transmission groove is communicated with the heating gas transmission boxes, a first sliding groove is formed in the clamping block, the first sliding groove is communicated with the second gas transmission groove, a heating block is arranged on the first sliding groove in a sliding mode, a first spring used for resetting is arranged between the heating block and the first sliding groove, two third gas transmission grooves are symmetrically formed in two sides of the first sliding groove, a vacuumizing box body is arranged at the other end of each third gas transmission groove, and the first gas transmission grooves are communicated with the heating gas transmission boxes through first sliding rods.

The sealing part comprises two first bearing rods arranged in the vertical direction in the working box body, a first glue absorption groove is formed in each first bearing rod, a collection box body is fixedly arranged on the outer side of the working box body, a first collection cavity is formed in each bearing rod and communicated with the collection box body, a second collection cavity is arranged on each first bearing rod in a sliding mode, a second spring for resetting is arranged between each second collection cavity and the inner wall of the working box body, two second glue absorption holes are symmetrically formed in two sides of each second collection cavity, each second glue absorption groove is communicated with the corresponding first glue absorption groove, a first rotating rod is rotatably arranged on one side, away from the first bearing rod, of each second collection cavity, a lug is arranged at the other end of each first rotating rod, a third glue absorption groove is formed in a lug close to one side of the clamping and adjusting part, one end of each third glue absorption groove is communicated with the corresponding second glue absorption hole, the other end extends to the edge of the bump, and the edge of the bump is provided with a vibration part.

Sealing member still collects the cavity lateral wall including the second that is close to centre gripping adjustment part one side and rotates on and be equipped with the second and slide flexible base, it slides and is equipped with the second and slides the telescopic link to slide in the second slides flexible base, the second slides the telescopic link other end and collects the cavity lateral wall with another and rotates and be connected, the second slides flexible base and is close to lug one side and has seted up the second sliding tray, it is equipped with the second slide bar to slide on the second sliding tray, set up first gluey groove in the second slide bar, first gluey groove one end of going out is led to the little gluey mouth of lug one side, and the other end is advanced gluey externally, big gluey mouth has been seted up to second slide bar lateral wall, it inhales gluey groove to have seted up the fourth on another lug flush end, the fourth is inhaled gluey groove third and is inhaled gluey groove connection.

The vibration part comprises a first vent hole communicated with a third glue sucking groove, the first vent hole is connected with a first rotating cavity, a first bearing is arranged on one side in the first rotating cavity, a second rotating rod is arranged on the first bearing in a rotating mode, one end of the second rotating rod is fixedly provided with a first spiral fan blade, the other end of the second rotating rod is connected with a large belt pulley, a second rotating cavity is arranged on one side, away from the first vent hole, of the first rotating cavity, a second bearing is arranged in the second rotating cavity, a third rotating rod is arranged on the second bearing in a rotating mode, one end of the third rotating rod is provided with a small belt pulley, the large belt pulley is connected with the small belt pulley through a belt, the other end of the third rotating rod is fixedly provided with a cam, a third sliding groove is formed in the second rotating cavity, a second sliding block is arranged in the third sliding groove in a sliding mode, and a third spring for resetting is arranged between the second sliding block and the third sliding groove, and the other end of the second sliding block is provided with a plurality of soft contact rods which are uniformly distributed.

The drying component comprises a drying box body, the outer side of the drying box body is located on the two sides of the first discharge port, the drying box body is symmetrically arranged, a drying pipe is fixedly arranged inside the drying box body and connected with the drying box body, a drying groove is formed in the drying pipe, and a second helical blade is arranged in the drying pipe.

Advantageous effects

The invention provides a production method of anti-adhesive-release laminated glass by improvement, compared with the prior art, the production method has the following improvements and advantages:

1. by arranging the vacuumizing box body, the clamping block and the first gas transmission groove, the middle part of the glass can be safely clamped and extruded and heated.

2. By arranging the second spring, the first rotating rod and the lug, the glass sealing device can clean a glass gap and supplement sealant, so that the sealing performance is greatly improved.

3. The first spiral fan blade, the belt pulley and the cam are arranged to form the sealing device, so that a thin layer of sealing gum is filled in a glass gap, the sealing gum is stirred and fused with the internal colloid, and more sealing gum is filled in the glass gap for sealing.

Drawings

The invention is further explained below with reference to the figures and examples:

FIG. 1 is a schematic isometric view of the present invention;

FIG. 2 is a front sectional structural view of the present invention;

FIG. 3 is a schematic top cross-sectional view of the present invention;

FIG. 4 is a side cross-sectional structural view of the present invention;

FIG. 5 is a schematic cross-sectional view of the vibration unit of the present invention;

FIG. 6 is a front cross-sectional structural view of a seal assembly of the present invention;

FIG. 7 is a top cross-sectional structural view of the seal assembly of the present invention;

fig. 8 is an enlarged view of fig. 6 at a.

In the figure, a working box 1, a first feeding port 101, a first discharging port 102, a conveying component 2, a clamping adjusting component 3, a sealing component 4, a drying component 5, a conveying rail 201, a conveying belt 202, a first sliding base 304, a first sliding telescopic rod 305, a first sliding rod 301, a first sliding rail 313, a first sliding block 303, an extrusion roller 302, a first gas conveying groove 312, a first bearing rod 307, a clamping block 319, a second gas conveying groove 310, a heating gas conveying box 306, a first sliding groove 316, a heating block 315, a first spring 317, a third gas conveying groove 314, a vacuumizing box 311, a first bearing rod 401, a first glue absorbing groove 408, a collecting box 440, a first collecting cavity 409, a second collecting cavity 403, a second spring 424, a second glue absorbing hole 407, a first rotating rod 404, a bump 405, a third glue absorbing groove 406, a vibrating component 425, a second sliding telescopic base 414, a second sliding telescopic rod 416, a second sliding groove 415, a second sliding rod 417, a first glue outlet groove 413, a small glue outlet 411, a large glue outlet 412, a fourth glue suction groove 422, a first vent hole 410, a first rotating cavity 427, a first bearing 434, a second rotating rod 418, a first spiral fan blade 426, a large belt pulley 436, a second rotating cavity 439, a second bearing 419, a third rotating rod 430, a small belt pulley 438, a belt 437, a cam 429, a third sliding groove 432, a second sliding block 431, a third spring 428, a soft contact rod 433, a drying box 504, a drying groove 505, a second spiral blade 502

Detailed Description

The present invention will be described in detail with reference to fig. 1 to 8, and the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention, and the motor in the present invention is the prior art, and for convenience of description, the motor in the drawings of the present specification is only a schematic structural diagram, and its internal structure and specific arrangement are the same as those in the prior art in "mechanical design manual".

As shown in fig. 1-8, the invention relates to a production method of anti-adhesive-release laminated glass, which uses an anti-adhesive-release laminated glass production device, the anti-adhesive-release laminated glass production device comprises a working box body 1, a first feed inlet 101 is arranged on one side of the working box body 1, a first discharge outlet 102 is arranged on the other side of the working box body 1, a conveying part 2 is arranged between the first feed inlet 101 and the second feed inlet 102, two groups of clamping and adjusting parts 3 are symmetrically arranged inside the working box body 1, a sealing part 4 is arranged on one side of the inside of the working box body 1, which is close to the first discharge outlet 102, and two groups of drying parts 5 are symmetrically arranged on two sides of the sealing part 4.

The conveying component 2 comprises a conveying track 201, and a conveying belt 202 is arranged in the conveying track 201.

The clamping adjustment component 3 comprises first sliding bases 304 symmetrically arranged on the inner wall of the work box body 1, a first sliding telescopic rod 305 is arranged in each first sliding base 304 in a sliding mode, a first sliding rod 301 is arranged at the other end of each first sliding telescopic rod 305 in the vertical direction, a first sliding track 313 is arranged in each first sliding rod 301, a first sliding block 303 is arranged in each first sliding track 313 in a sliding mode, an extrusion roller 302 is arranged between the first sliding blocks 303, a first gas transmission groove 312 is arranged in each extrusion roller 302, a first bearing rod 307 is fixedly arranged between the first sliding telescopic bases 304, and a clamping block 319 is arranged at the other end of each first bearing rod 307 in a rotating mode.

The clamping adjustment component 3 further comprises a second gas transmission groove 310 arranged in the first bearing rod 307, two heating gas transmission box bodies 306 are fixedly arranged on two sides of the working box body 1, the first gas transmission groove 310 is communicated with the heating gas transmission box bodies 306, a first sliding groove 316 is arranged in the clamping block 319, the first sliding groove 316 is communicated with the second gas transmission groove 310, a heating block 315 is arranged on the first sliding groove 316 in a sliding mode, a first spring 317 for resetting is arranged between the heating block 315 and the first sliding groove 316, two third gas transmission grooves 314 are symmetrically arranged on two sides of the first sliding groove 316, a vacuumizing box body 311 is arranged at the other end of each third gas transmission groove, and the first gas transmission groove 312 is communicated with the heating gas transmission box bodies 306 through the first sliding rod 301.

The sealing part 4 comprises two first bearing rods 401 arranged in the vertical direction in the working box body 1, a first glue absorption groove 408 is arranged in each first bearing rod 401, a collecting box body 440 is fixedly arranged on the outer side of the working box body 1, a first collecting cavity 409 is arranged in each bearing rod 401, the first collecting cavity 409 is communicated with the collecting box body 440, a second collecting cavity 403 is arranged on each first bearing rod 401 in a sliding mode, a second spring 424 for resetting is arranged between each second collecting cavity 403 and the inner wall of the working box body 1, two second glue absorption holes 407 are symmetrically arranged on two sides of each second collecting cavity 403, each second glue absorption groove 407 is communicated with the corresponding first glue absorption groove 408, a first rotating rod 404 is rotatably arranged on one side, away from the corresponding first bearing rod 401, of each second collecting cavity 403, a lug 405 is arranged at the other end of the corresponding first rotating rod 404, a third glue absorption groove 406 is arranged in each lug 405 on one side, close to the clamping and adjusting part 3, one end of each third glue absorption groove 406 is communicated with the corresponding second glue absorption hole 407, the other end extends to the edge of the convex block 405, and the edge of the convex block 405 is provided with a vibration part 425.

The sealing member 4 further includes a second sliding telescopic base 414 rotatably disposed on a side wall of the second collection cavity 403 close to one side of the clamping adjustment member 3, a second sliding telescopic rod 416 is slidably disposed in the second sliding telescopic base 414, the other end of the second sliding telescopic rod 416 is rotatably connected to a side wall of another collection cavity 403, a second sliding groove 415 is disposed on one side of the second sliding telescopic base 414 close to the protrusion 405, a second sliding rod 417 is slidably disposed on the second sliding groove 415, a first glue outlet groove 413 is disposed in the second sliding rod 417, one end of the first glue outlet groove is connected to the small glue outlet 411 on one side of the protrusion 405, the other end of the first glue outlet groove is externally filled with glue, a large glue outlet 412 is disposed on a side wall of the second sliding rod 417, a fourth glue suction groove 422 is disposed on a flat end surface of another protrusion 405, and the fourth glue suction groove 422 is connected to the third glue suction groove 406.

The vibration component 425 comprises a first vent hole 410 communicated with the third glue sucking groove 406, the first vent hole 410 is connected with a first rotating cavity 427, a first bearing 434 is arranged on one side in the first rotating cavity 427, a second rotating rod 418 is rotatably arranged on the first bearing 434, one end of the second rotating rod 418 is fixedly provided with a first spiral fan blade 426, the other end of the second rotating rod 418 is connected with a large belt pulley 436, one side of the first rotating cavity 427, which is far away from the first vent hole 410, is provided with a second rotating cavity 439, a second bearing 419 is arranged in the second rotating cavity 439, a third rotating rod 430 is rotatably arranged on the second bearing 419, one end of the third rotating rod 430 is provided with a small belt pulley 438, the large belt pulley 436 is connected with the small belt pulley 438 through a belt 437, the other end of the third rotating rod 430 is fixedly provided with a cam 429, a third sliding groove 432 is arranged in the second rotating cavity 439, and a second sliding block 431 is slidably arranged in the third sliding groove 432, a third spring 428 for resetting is arranged between the second sliding block 431 and the third sliding groove 432, and a plurality of soft contact rods 433 which are uniformly distributed are arranged at the other end of the second sliding block 432.

The drying component 5 comprises a drying box body 504 which is arranged outside the working box body 1 and symmetrically arranged on two sides of the first discharge hole 102, a drying pipe 501 is fixedly arranged inside the working box body 1 and connected with the drying box body 504, a drying groove 505 is formed in the drying pipe 501, and a second helical blade 502 is arranged in the drying pipe 501.

The invention also provides a production method of the anti-adhesive interlayer glass, which comprises the following specific steps:

the first step is as follows: the equipment is powered on, the laminated glass is conveyed into the working box body 1 through the conveying track 201, the laminated glass is moved to the middle part and is stopped, the gas conveying box body 306 is heated, the drying box body 504 starts to heat and provides power for the first sliding telescopic rod 305, and hot gas is introduced into the second gas conveying groove 310.

The second step is that: the first sliding telescopic rods 305 on the two sides are moved to the surface of the glass, the vacuumizing box body 311 pumps away air, the clamping blocks 319 are adsorbed on the surface of the glass, the second air conveying groove 310 heats the middle of the glass, the heating blocks 315 move towards the surface of the glass under the pushing of hot air, the middle of the glass is extruded, bubbles in the middle of the glass are extruded all around, and the middle of the glass is bonded firstly.

The third step: the interior of the pressing roller 302 is heated, and simultaneously, upward pressing is started, bubbles of the glass seeds on one side are heated in the process of heating upward, and the pressing roller 302 returns to the initial position after the pressing is finished.

The fourth step: after the extrusion is finished, the clamping blocks 319 are controlled to rotate, in the rotating process, the two convex blocks 405 always slide along the surface of the glass, the convex blocks 405 on the upper portions firstly contact the gaps of the glass, the third glue sucking grooves 406 suck out redundant glue in the gaps of the glass to the collecting box body 440, when the convex blocks 406 on the lower portions pass through the gaps, the first spiral fan blades 426 rotate under the action of wind power, meanwhile, the large belt pulley 436 is driven to rotate, the large belt pulley 436 drives the cam 429 to rotate, the second sliding blocks 431 reciprocate under the action of the cam 429, and the second sliding blocks 431 drive the soft contact rods 433 to poke in the gaps.

The fifth step: the small glue outlet 411 fills a layer of thin sealant into the gap when the soft touch rod 433 is shifted, the glue inside the gap is mixed with the sealant when the soft touch rod 433 is shifted, the glue is supplemented through the large glue outlet 412, and the redundant glue is sucked out by the fourth glue sucking groove 422 after overflowing, so that the gap is guaranteed to be flat.

And a sixth step: and the sealing of the glass gap is completed in the rotating process, the second collecting cavity 403 slides to the initial position when the glass gap rotates by 90 degrees, the squeezing rollers 302 are continuously controlled to continuously squeeze and exhaust the other sides of the glass, and the glass gap is continuously rotated and filled.

The seventh step: after each side surface of a piece of glass is squeezed and sealed, the glass is placed back to the conveying track 201, the vacuumizing box body 311 slowly sends air back, the glass is separated from the clamping block 319, and the sealed glass is conveyed out of the working box body 1.

Eighth step: and conveying new glass into the working box body 1, and repeating the extruding and sealing steps.

The above description is only for the preferred embodiment of the present invention and is not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.