CN113585926B - Method for injecting inert gas into hollow glass - Google Patents

Abstract

The invention relates to the field of injecting inert gas into hollow glass, and discloses a method for injecting inert gas into hollow glass.

Description

Method for injecting inert gas into hollow glass

Technical Field

The invention relates to the field of injecting inert gas into hollow glass, in particular to a method for injecting inert gas into hollow glass.

Background

The argon filled in the hollow glass can reduce the pressure difference between the inside and the outside, keep the pressure balance and reduce the glass burst caused by the pressure difference. The K value of the hollow glass can be effectively improved, condensation of indoor glass is reduced, and the comfort level is improved. Because argon is used as inert gas, the characteristics of the argon can slow down the heat convection in the hollow glass, and simultaneously can greatly improve the sound insulation and noise reduction effects, namely the heat insulation and sound insulation effects of the hollow glass are better.

In the existing equipment, after the inert gas is filled in, the edge warping deformation of the glass caused by temperature change cannot be ensured, and the processing speed is slow, so that the improvement is necessary.

Disclosure of Invention

The invention aims to provide a method for injecting inert gas into hollow glass, which solves the problems in the background technology.

The invention is realized by the following modes: the hollow glass inert gas injection method uses a hollow glass inert gas injection device, the hollow glass inert gas injection device comprises a working box body, four conveying ports are symmetrically formed in the working box body, two inert gas conveying box bodies are symmetrically and fixedly arranged at the top of the working box body, two electric heating box bodies are symmetrically and fixedly arranged at two sides of the working box body, conveying parts are arranged at the inner bottom of the working box body, clamping and overturning parts are arranged between the conveying parts, punching gas injection parts are arranged at the inner top of the working box body, and the electric heating box bodies can heat the conveying parts and provide power for the conveying parts.

Preferably, the conveying part comprises first conveying troughs symmetrically formed in the inner bottom of the working box body, a plurality of groups of rotating rollers are arranged in each first conveying trough, the other ends of the rotating rollers are connected with first springs used for resetting, the other ends of the first springs are connected with second conveying troughs, the other ends of the second conveying troughs are connected with the same first springs and the same second conveying troughs, the second conveying troughs slide in the first conveying troughs, and a plurality of groups of first rollers are symmetrically arranged on the side walls of the working box body.

Preferably, the clamping and overturning part comprises a first sliding telescopic base fixedly arranged between first conveying grooves, a first sliding telescopic rod is arranged in the first sliding telescopic base in a sliding mode, a vacuum suction box body is arranged at the other end of the first sliding telescopic rod, two second sliding telescopic rods are symmetrically arranged on two sides of the first sliding telescopic rod, each second sliding telescopic rod is rotatably connected with a sucker, and a first air conveying groove is formed in each second sliding telescopic rod and communicated with the vacuum suction box body.

Preferably, the punching gas injection part comprises a first bearing block symmetrically arranged at the top end of the working box body, a gas pipe is arranged in the first bearing block, one end of the gas pipe is communicated to the inert gas conveying box body, the first bearing block is close to two limiting plates symmetrically and fixedly arranged on one side of the clamping turnover part, a first sliding groove is formed between the limiting plates, a first sliding plate is arranged in the first sliding groove in a sliding mode, a second spring is arranged between the first sliding plate and the limiting plates, a first bearing shaft is fixedly arranged on one side, far away from the second spring, of the first sliding plate, a gas injection module is arranged at the bottom of the first bearing shaft, a second bearing block is fixedly arranged on one side of the first bearing shaft, a punching module is connected to the bottom of the second bearing block, an inclined scraper for cleaning is symmetrically arranged at the other end of the first bearing shaft, a first bearing rod is fixedly arranged below the inclined scraper, a second roller is rotatably arranged between the first bearing rods, a screw rod is arranged above the second roller, the screw rod is matched with the first bearing rod through a gear, and a sliding scraper is arranged on the screw rod in a threaded fit mode.

Preferably, the gas injection part that punches still includes the inside cam of second bearing block, the first axis of rotation of fixedly connected with in the cam, the first axis of rotation other end is connected with first gear, the second axis of rotation that the level set up in the second bearing block, first gear one side is kept away from in the second axis of rotation has set firmly spiral flabellum, spiral flabellum extends to in the gas transmission pipe the second axis of rotation other end is equipped with the disc, the second axis of rotation slides with the disc junction and is equipped with the flexible base of second slip, the disc is equipped with all around and is used for intermittent type pivoted quarter one section rack.

Preferably, the punching module comprises a third sliding telescopic base, a hole breaking cone is arranged in the third sliding telescopic base in a sliding mode, the hole breaking cone is close to one side of the cam and fixedly provided with a first connecting rod, the first connecting rod is located below the cam, a third spring used for resetting is arranged between the hole breaking cone and the second bearing block, two air pumps used for air suction and collection are symmetrically arranged at the other end of the third sliding telescopic base, a second air conveying groove is formed in the hole breaking cone, and the second air conveying groove is connected with the air pumps through hoses.

Preferably, the gas injection module includes a gas injection rod, a third gas transmission groove is formed in the gas injection rod, the other end of the gas transmission pipe is communicated to the third gas transmission groove, first glue injection grooves for injecting glue are symmetrically formed in two sides of the third gas transmission groove, two glue storage boxes are fixedly arranged on two sides of the gas injection rod, the glue storage boxes are communicated with one end of each first glue injection groove, a control valve module is arranged at the other end of each first glue injection groove, two annular glue suction pumps are correspondingly arranged below the glue storage boxes, the annular glue suction pumps are communicated with the first glue injection grooves through the second glue injection grooves, an L-shaped scraper plate is fixedly arranged on one side, away from the glue storage boxes, of each annular glue suction pump, the first glue suction grooves are formed in the L-shaped scraper plates, the annular glue suction pumps are in threaded fit with the gas injection rod, and a heating plate is arranged above the control valve modules.

Preferably, the control flap module sets up the rotation valve plate at first injecting glue inslot including rotating, first injecting glue trench has seted up first rotating groove in rotating valve plate other end level, the rotating valve plate has set firmly the pinion rod towards the one end in first rotating groove, it is equipped with the cambered surface pin to slide in the first rotating groove, the cambered surface pin stretches into the one end in first rotating groove and is connected with the rack bar, the rack bar removes and can drive the pinion rod when contacting with the pinion rod and rotate, be equipped with the fourth spring between cambered surface pin and the first rotating groove.

Advantageous effects

The invention provides a method for injecting inert gas into hollow glass by improvement, compared with the prior art, the method has the following improvement and advantages:

1. by arranging the inclined scraper, the screw and the sliding scraper, the sealant can be adjusted and scraped, and the sealing flatness is ensured.

2. By arranging the control valve module, the invention can ensure that the sealant does not flow out when the inert gas is injected, and can seal the periphery of the hole when the hole is reset, thereby ensuring the quality of subsequent 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 schematic side view of the perforating and gas-injecting component of the present invention;

FIG. 5 is a schematic cross-sectional view of a gas injection component of the invention;

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

FIG. 7 is a schematic cross-sectional view of a punching module according to the present invention;

FIG. 8 is a schematic cross-sectional view of a gas injection module according to the present invention;

FIG. 9 is an enlarged view taken at A in FIG. 2;

fig. 10 is an enlarged view of fig. 8 at B.

In the figure: a working box body 1, a conveying port 101, an inert gas conveying box body 102, an electric heating box body 103, a conveying part 2, a clamping turnover part 3, a punching and gas injection part 4, a first conveying groove 201, a rotating roller 202, a first spring 203, a second conveying groove 204, a first roller 205, a first sliding telescopic base 302, a first sliding telescopic rod 303, a vacuum suction box body 301, a second sliding telescopic rod 304, a suction cup 305, a first gas conveying groove 306, a first bearing block 401, a gas conveying pipe 410, a limiting plate 404, a first sliding groove 445, a first sliding plate 402, a second spring 403, a first bearing shaft 406, a gas injection module 409, a second bearing block 407, a punching module 408, an inclined scraper 411 and a first bearing rod 412, the device comprises a second roller 413, a screw 443, a sliding scraper 444, a cam 414, a first rotating shaft 415, a first gear 416, a second rotating shaft 418, a spiral fan blade 419, a disc 417, a second sliding telescopic base 421, a rack 420, a third sliding telescopic base 422, a hole breaking cone 428, a first connecting rod 424, a third spring 423, an air pump 425, a second air conveying groove 427, a hose 426, an air injection rod 429, a third air conveying groove 435, a first glue injection groove 431, a glue storage box 430, a control valve module 438, an annular glue suction pump 432, a second glue injection groove 434, an L-shaped scraper 433, a first glue suction groove 436, a heating plate 437, a rotating valve plate 439, a first rotating groove 441, a cambered surface blocking rod 442 and a fourth spring 440.

Detailed Description

The present invention will be described in detail with reference to fig. 1 to 10, and the technical solutions in the embodiments of the present invention will be clearly and completely described, 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 making creative efforts belong to the protection scope of the present invention, and the hydraulic cylinder in the present invention is the prior art, and for convenience of description, the hydraulic cylinder in the drawings of the present invention is only a schematic structural diagram, and its internal structure and specific arrangement are the same as those in the prior art in the "mechanical design manual".

As shown in fig. 1-10, the present invention is a method for injecting inert gas into hollow glass, the method for injecting inert gas into hollow glass uses a device for injecting inert gas into hollow glass, the device for injecting inert gas into hollow glass comprises a work box 1, four delivery ports 101 are symmetrically formed on the work box 1, two inert gas delivery boxes 102 are symmetrically and fixedly formed on the top of the work box 1, two electric heating boxes 103 are symmetrically and fixedly formed on two sides of the work box 1, a delivery part 2 is formed on the bottom inside the work box 1, a clamping and turning part 3 is formed between the delivery parts 2, a punching and gas injection part 4 is formed on the top inside the work box 1, and the electric heating boxes 103 can heat and provide power for the delivery part 2.

Further, the conveying part 2 comprises first conveying grooves 201 symmetrically formed in the bottom of the working box body 1, a plurality of groups of rotating rollers 202 are arranged in each first conveying groove 201, the other ends of the rotating rollers are connected with first springs 203 used for resetting, the other ends of the first springs 203 are connected with second conveying grooves 204, the other ends of the second conveying grooves 204 are connected with the same first springs 203 and the same second conveying grooves 204, the second conveying grooves 204 slide in the first conveying grooves 201, and a plurality of groups of first rollers 205 are symmetrically arranged on the side wall of the working box body 1.

Further, the clamping and turning part 3 comprises a first sliding telescopic base 302 fixedly arranged between the first conveying grooves 201, a first sliding telescopic rod 303 is arranged in the first sliding telescopic base 302 in a sliding mode, the other end of the first sliding telescopic rod 303 is provided with a vacuum suction box body 301, two second sliding telescopic rods 304 are symmetrically arranged on two sides of the first sliding telescopic rod 303, the other end of each second sliding telescopic rod 304 is rotatably connected with a suction cup 305, and a first air conveying groove 306 is formed in each second sliding telescopic rod 304 and communicated with the vacuum suction box body 301.

Further, the punching gas injection component 4 comprises first bearing blocks 401 symmetrically arranged at the top end of the working box body 1, gas pipes 410 are arranged in the first bearing blocks, one ends of the gas pipes 410 are communicated to the inert gas conveying box body 102, two limiting plates 404 are symmetrically and fixedly arranged on one sides, close to the clamping turnover component 3, of the first bearing blocks 401, a first sliding groove 445 is formed between the limiting plates 404, a first sliding plate 402 is arranged in the first sliding groove 445 in a sliding mode, a second spring 403 is arranged between the first sliding plate 402 and the limiting plates 404, a first bearing shaft 406 is fixedly arranged on one side, far away from the second spring 403, of the first sliding plate 402, a gas injection module 409 is arranged at the bottom of the first bearing shaft 406, a second bearing block 407 is fixedly arranged on one side of the first bearing shaft 406, a punching module 408 is connected to the bottom of the second bearing block 406, inclined scrapers for cleaning are symmetrically arranged on the other ends of the first bearing shaft 406, a first bearing rod 411 is fixedly arranged on the inclined lower surface of each inclined scraper 411, a second bearing rod 412 is rotatably arranged with a second roller 413, a screw 443 is arranged above the second roller 413, the screw is arranged on the first bearing rod 412, and matched with the scraper through a screw 444 in a thread.

Further, the perforation air injection component 4 further comprises a cam 414 inside the second bearing block 407, a first rotating shaft 415 is fixedly connected inside the cam 414, the other end of the first rotating shaft 415 is connected with a first gear 416, a second rotating shaft 418 is horizontally arranged inside the second bearing block 407, a spiral fan blade 419 is fixedly arranged on one side, away from the first gear 416, of the second rotating shaft 418, the spiral fan blade 419 extends into the air pipe 410, a disc 417 is arranged at the other end of the second rotating shaft 418, a second sliding telescopic base 421 is arranged at the connection position of the second rotating shaft 418 and the disc 417 in a sliding manner, and a quarter-section rack 420 for intermittent rotation is arranged around the disc 417.

Further, the punching module 408 comprises a third sliding telescopic base 422, a hole-breaking cone 428 is slidably disposed in the third sliding telescopic base 422, a first connecting rod 424 is fixedly disposed on one side of the hole-breaking cone 428 close to the cam 414, the first connecting rod 424 is located below the cam 414, a third spring 423 for resetting is disposed between the hole-breaking cone 428 and the second bearing block 407, two air pumps 425 for sucking air and collecting are symmetrically disposed at the other end of the third sliding telescopic base 422, a second air delivery groove 427 is disposed in the hole-breaking cone 428, and the second air delivery groove 427 is connected with the air pumps 425 through a hose 426.

Further, the gas injection module 409 comprises a gas injection rod 429, a third gas transmission groove 435 is formed in the gas injection rod 429, the other end of the gas transmission pipe 410 is communicated with the third gas transmission groove 435, first glue injection grooves 431 for injecting glue are symmetrically formed in two sides of the third gas transmission groove 435, two glue storage boxes 430 are fixedly arranged on two sides of the gas injection rod 429, the glue storage boxes 430 are communicated with one ends of the first glue injection grooves 431, a control valve module 438 is arranged at the other end of each first glue injection groove 431, two annular glue suction pumps 432 are correspondingly arranged below the glue storage boxes 430, the annular glue suction pumps 432 are communicated with the first glue injection grooves 431 through the second glue injection grooves 434, an L-shaped scraper 433 is fixedly arranged on one side, away from the glue storage boxes 430, of the annular glue suction pumps 432, the first glue suction grooves 436 are formed in the L-shaped scraper 433, the annular glue suction pumps 432 are in threaded fit with the gas injection rod 429, and a heating plate 437 is arranged above the control valve module 438.

Further, control valve module 438 sets up the rotary valve plate 439 in first injecting glue groove 431 including rotating, first injecting glue trench has been seted up in rotary valve plate 439 other end level to first injecting glue groove, rotary valve plate 439 has set firmly the gear pole towards the one end of first rotary groove 441, it is equipped with cambered surface pin 442 to slide in the first rotary groove 441, cambered surface pin 442 stretches into the one end in first rotary groove 441 and is connected with the rack pole, can drive the gear pole rotation when the rack pole removes and contacts with the gear pole, be equipped with fourth spring 440 between cambered surface pin 442 and the first rotary groove 441.

The invention also provides a method for injecting inert gas into hollow glass, which comprises the following specific steps:

the first step is as follows: the equipment is powered on, the electric heating box 103 heats the first roller 205 to raise the temperature in the working box 1, the first piece of glass is conveyed to the inside of the working box 1 through the rotating roller 202, and then the glued aluminum sealing strip and the second piece of glass are conveyed to the designated position in the working box 1 through the second conveying groove 204.

The second step is that: the second sliding telescopic rod 304 extends towards two sides to extrude and seal glass and an aluminum sealing strip, the second conveying groove 204 slides in the first conveying groove 201 along with extrusion, the adhesive effect of the sealant and the glass is better under the high-temperature state until the glass and the aluminum sealing strip are completely sealed, and the vacuum suction box body 301 slowly adsorbs the glass which is completely adhered to the sucker 305.

The third step: the first sliding telescopic rod 303 is lifted up slowly to drive the hollow glass to lift, the suction cup 305 starts to rotate, the inert gas conveying box body 102 conveys gas into the third gas conveying groove 435 in the rotating process, the air in the third gas conveying groove 435 is discharged, meanwhile, the spiral fan blade 419 is driven to rotate, the cam 414 is driven to rotate intermittently by the rack 420, the cam 414 intermittently enables the first connecting rod 424 to impact downwards, and meanwhile, the air pump 425 sucks the gas in the second gas conveying groove 427 into the air pump 425.

The fourth step: the hole-breaking cone 428 intermittently perforates the aluminum sealing strip during rotation, and perforates on opposite sides of the aluminum sealing strip, and debris generated by the perforation is absorbed and collected by the air pump 425.

The fifth step: after punching the both sides and finishing when rotating to the both sides of punching once more, slide second axis of rotation 418 and stretch out and draw back to in the flexible base 421 of second slip, spiral fan blade 419 no longer rotates, aim at the hole that broken hole awl 428 was beaten with gas injection module 409 simultaneously, second bearing block 407 slides down, make gas injection pole 429 stretch into to the aluminium sealing strip in, inert gas gets into in cavity glass through third gas transmission groove 435, because of inert gas is bigger than the air quality, discharge the air in the glass along the hole of opposite face, store up gluey box 430 and pour into first glue injection groove 431 with sealed glue.

And a sixth step: slide cambered surface pin 442 to inside first rotating groove 441 when gas injection pole 429 descends in-process hole face and cambered surface contact, simultaneously annular glue suction pump 432 is rotatory promotion upwards after being restricted by the hole surface, gas injection pole 429 descends to cambered surface pin 442 and pops out after surpassing the aluminium sealing strip and stops descending when gas injection pole 429, rotating valve plate 439 seals first glue injection groove 431, make gas injection pole 429 reset after inert gas discharges the air, make cambered surface pin 442 remove when upwards in-process cambered surface pin 442 and hole bottom surface contact, thereby make the rack bar drive the gear pole and rotate and drive rotating valve plate 439 and rotate, rotating valve plate 439 removes the sealed effect of first glue injection groove 431, sealed glue spouts through first glue injection groove 431.

The seventh step: the heating plate 437 heats when the sealant is sprayed out, the sealant slowly seals the side wall of the punched hole, the sealant is dried by the heating plate 437, the gas injection rod 429 slowly ascends to the cambered surface stop rod 442 to reset to the original position, the sealant stops sealing, the heating plate 437 stops heating, when the sealant ascends, the annular glue suction pump 432 rotates under the action of the threads due to gravity, the L-shaped scraper 433 cleans the sealant possibly remained on the upper surface of the hole while the sealant rotates, the annular glue suction pump 432 sucks the redundant sealant into the annular glue suction pump 432 through the first glue suction groove 436, the annular glue suction pump 432 injects the redundant sealant into the first glue injection groove 431 through the second glue injection groove 434, the surface of the hole is guaranteed to be flat, and the redundant sealant is recycled.

Eighth step: the sealant continuously seals the aluminum sealing strip and the hole, meanwhile, the hollow glass is controlled to continuously rotate, the inclined scraper 411 scrapes the sealant to the middle part of the sealing strip in the rotating process, then the second roller 413 scrubs the aluminum sealing strip, and the screw 443 is driven to rotate in the rotating process of the second roller 413, so that the sliding scraper 444 slides on the screw 443 to clean the sealant on the second roller 413.

The ninth step: when the hollow glass rotates to the hole on the opposite side, the gas injection module 409 performs the same action to inject gas into the hole for sealing, so that the content of inert gas in the hollow glass reaches the standard, and after sealing is completed, the first sliding telescopic rod 303 slides downwards, so that the hollow glass falls back to the rail and is transported out through the rail.

The tenth step: and then, conveying the first piece of glass into the working box body 1 through the rotating roller 202, conveying the glued aluminum sealing strip and the second piece of glass into the working box body 1 to a specified position through the second conveying groove 204, and then repeatedly performing the actions of punching, gas injection and sealing.

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.

Claims (5)

1. The method for injecting the inert gas into the hollow glass uses equipment for injecting the inert gas into the hollow glass, and comprises a working box body (1), wherein four conveying ports (101) are symmetrically formed in the working box body (1), two inert gas conveying box bodies (102) are symmetrically and fixedly arranged at the top of the working box body (1), two electric heating box bodies (103) are symmetrically and fixedly arranged at two sides of the working box body (1), a conveying part (2) is arranged at the bottom in the working box body (1), a clamping and overturning part (3) is arranged between the conveying parts (2), a punching gas injection part (4) is arranged at the top in the working box body (1), and the electric heating box bodies (103) can heat and provide power for the conveying parts (2);

the conveying part (2) comprises first conveying troughs (201) symmetrically formed in the bottom of the working box body (1), a plurality of groups of rotating rollers (202) are arranged in each first conveying trough (201), the other ends of the rotating rollers are connected with first springs (203) for resetting, the other ends of the first springs (203) are connected with second conveying troughs (204), the other ends of the second conveying troughs (204) are connected with the same first springs (203) and the same second conveying troughs (204), the second conveying troughs (204) slide in the first conveying troughs (201), and a plurality of groups of first rollers (205) are symmetrically arranged on the side walls of the working box body (1);

the clamping and turning part (3) comprises a first sliding telescopic base (302) fixedly arranged between first conveying grooves (201), a first sliding telescopic rod (303) is arranged in the first sliding telescopic base (302) in a sliding mode, a vacuum suction box body (301) is arranged at the other end of the first sliding telescopic rod (303), two second sliding telescopic rods (304) are symmetrically arranged on two sides of the first sliding telescopic rod (303), the other end of each second sliding telescopic rod (304) is rotatably connected with a sucking disc (305), and a first air conveying groove (306) is formed in each second sliding telescopic rod (304) and communicated with the vacuum suction box body (301);

the punching gas injection component (4) comprises first bearing blocks (401) symmetrically arranged at the top end of a working box body (1), gas pipes (410) are arranged in the first bearing blocks, one ends of the gas pipes (410) are communicated to an inert gas conveying box body (102), two limiting plates (404) are symmetrically and fixedly arranged on one side, close to a clamping turnover component (3), of the first bearing blocks (401), a first sliding groove (445) is formed between the limiting plates (404), a first sliding plate (402) is arranged in the first sliding groove (445) in a sliding mode, a second spring (403) is arranged between the first sliding plate (402) and the limiting plates (404), a first bearing shaft (406) is fixedly arranged on one side, away from the second spring (403), of the first sliding plate (402), a gas injection module (409) is arranged at the bottom of the first bearing shaft (406), a second bearing block (407) is fixedly arranged on one side of the first bearing shaft (406), a punching module (408) is connected to the bottom of the second bearing block (407), inclined scrapers (411) for cleaning are symmetrically arranged at the other ends of the first bearing shaft (406), a second bearing plate (412) is provided with inclined scrapers (411), a second inclined rod (413) is arranged above the first inclined rotating roller (413) is arranged on each inclined surface (412), and a rotary roller (413) is arranged below the second bearing plate (412), the screw (443) is engaged with the first bearing rod (412) through a gear, and the screw (443) is engaged with a sliding scraper (444) through threads.

2. The method for injecting inert gas into hollow glass according to claim 1, wherein: the punching gas injection component (4) further comprises a cam (414) inside a second bearing block (407), a first rotating shaft (415) is fixedly connected in the cam (414), the other end of the first rotating shaft (415) is connected with a first gear (416), a second rotating shaft (418) horizontally arranged in the second bearing block (407), a spiral fan blade (419) is fixedly arranged on one side, away from the first gear (416), of the second rotating shaft (418), the spiral fan blade (419) extends into the gas conveying pipe (410), a disc (417) is arranged at the other end of the second rotating shaft (418), a second sliding telescopic base (421) is arranged at the joint of the second rotating shaft (418) and the disc (417) in a sliding manner, and a quarter section of rack (420) used for intermittent rotation is arranged on the periphery of the disc (417).

3. The method for injecting inert gas into hollow glass according to claim 2, wherein: the punching module (408) comprises a third sliding telescopic base (422), a hole breaking cone (428) is arranged in the third sliding telescopic base (422) in a sliding mode, a first connecting rod (424) is fixedly arranged on one side, close to the cam (414), of the hole breaking cone (428), the first connecting rod (424) is located below the cam (414), a third spring (423) used for resetting is arranged between the hole breaking cone (428) and the second bearing block (407), two air pumps (425) used for air suction and collection are symmetrically arranged at the other end of the third sliding telescopic base (422), a second air conveying groove (427) is formed in the hole breaking cone (428), and the second air conveying groove (427) is connected with the air pumps (425) through a hose (426).

4. The method for injecting inert gas into hollow glass according to claim 3, wherein: the air injection module (409) comprises an air injection rod (429), a third air injection groove (435) is formed in the air injection rod (429), the other end of the air injection pipe (410) is communicated to the third air injection groove (435), first glue injection grooves (431) for injecting glue are symmetrically formed in two sides of the third air injection groove (435), two glue storage boxes (430) are fixedly arranged on two sides of the air injection rod (429), the glue storage boxes (430) are communicated with one ends of the first glue injection grooves (431), each first glue injection groove (431) is provided with a control valve module (438), two annular glue suction pumps (432) are correspondingly arranged below the glue storage boxes (430), the annular glue suction pumps (432) are communicated with the first glue injection grooves (431) through second glue injection grooves (434), one sides, far away from the glue storage boxes (430), of the annular glue suction pumps (432) are fixedly provided with L-shaped scrapers (433), first glue suction grooves (436) are formed in the L-shaped scrapers (433), the annular glue suction pumps (437) are matched with the air injection rods (429), and the control valve modules (432) are arranged above the air injection rods (429).

5. The method for injecting inert gas into hollow glass according to claim 4, wherein: control flap module (438) is including rotating rotary valve plate (439) that sets up in first injecting glue groove (431), first injecting glue trench is located rotary valve plate (439) other end level and has seted up first rotating groove (441), rotary valve plate (439) has set firmly the gear pole towards the one end of first rotating groove (441), it is equipped with cambered surface pin (442) to slide in first rotating groove (441), the cambered surface pin (442) stretches into the one end in first rotating groove (441) and is connected with the rack pole, can drive the gear pole when rack pole removes and gear pole contact and rotate, be equipped with fourth spring (440) between cambered surface pin (442) and first rotating groove (441).

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