CN115648788A - Irradiation-resistant multilayer glass bonding device - Google Patents

Abstract

The invention discloses an irradiation-resistant multi-layer glass bonding device, which relates to the technical field of glass bonding and comprises the following components: the device comprises a shell, a feed inlet, a discharge outlet and a sealing plate; a bonding device is arranged in the shell and used for bonding the multilayer glass; a cleaning device is arranged on one side of the shell close to the feed inlet; the cleaning device is used for cleaning the surface of the glass; in the process that the glass enters the shell, the cleaning device immediately cleans the surface of the glass to remove dust and impurities on the surface of the glass, so that the phenomenon that the bonding surface of the glass is hollowly formed in the bonding process of the glass due to the fact that the dust and impurities are remained on the surface of the glass is avoided, the bonding quality of the multilayer glass is influenced, and the bonding quality of the glass is improved; when the glass moves to the inside of the shell, the bonding device performs gluing and bonding on the surface of the glass, and the bonding efficiency of the glass is improved.

Description

Irradiation-resistant multilayer glass bonding device

Technical Field

The invention relates to the technical field of glass bonding, in particular to an irradiation-resistant multilayer glass bonding device.

Background

The glass is a non-crystalline inorganic material which is prepared by melting, molding, cooling and solidifying quartz sand, soda ash, feldspar, limestone and the like which are used as main raw materials; the glass has transparency which is difficult to be possessed by common materials, has excellent mechanical property and thermal property, continuously develops towards multiple functions along with the development requirement of modern buildings, and needs to bond multiple layers of glass in order to enable the glass to have multiple functions; the existing glass bonding is manual gluing bonding, the production efficiency is low, and air bubbles are generated when glass is bonded, so that the bonding quality of the glass is influenced, and the bonding surface of the multilayer glass is peeled.

Disclosure of Invention

The invention aims to provide an irradiation-resistant multi-layer glass bonding device to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme:

an irradiation resistant multiple layer glass bonding apparatus comprising: the side wall of the shell is provided with a feeding hole, the top of the shell is provided with a discharging hole, one side of the feeding hole, which is far away from the shell, is provided with a sealing plate, and the sealing plate is in sliding connection with the outer wall of the shell through a pulley; a bonding device is arranged in the shell and used for bonding the multilayer glass; a cleaning device is arranged on one side of the shell close to the feed inlet; the cleaning device is used for cleaning the surface of the glass;

the controller controls the telescopic clamping plate to start, and the telescopic clamping plate clamps the irradiation-resistant glass; the irradiation-resistant glass moves under the action of the telescopic clamping plate, the irradiation-resistant glass moves towards one side close to the feeding hole and enters the shell through the feeding hole, and in the process that the glass enters the shell, the surface of the irradiation-resistant glass meets the cleaning device, the cleaning device immediately cleans the surface of the glass, dust and impurities on the surface of the irradiation-resistant glass are removed, so that the situation that the irradiation-resistant glass is adhered due to the fact that the surface of the irradiation-resistant glass is empty and bulged in the adhering process is avoided, the adhering quality of the irradiation-resistant multi-layer glass is affected, and the adhering quality of the irradiation-resistant glass is further improved; when irradiation-resistant glass moves to the inside of the shell, the bonding device coats and bonds the surface of irradiation-resistant glass, the bonding efficiency of irradiation-resistant glass is improved, when irradiation-resistant glass is bonded, the controller controls the sealing plate to move, the sealing plate moves to the position of the feed inlet, the feed inlet is closed by the sealing plate, and after irradiation-resistant glass is bonded, irradiation-resistant glass is conveyed out through the discharge outlet.

Preferably, the bonding means comprises: the support frame is arranged inside the shell, the side wall of the support frame is symmetrically provided with extension plates, the inner wall of the shell is provided with a slide way, the extension plates are provided with springs, one end of each spring is connected with the inner wall of the slide way, and the support frame is connected with the shell in a sliding mode through the extension plates and the slide way; a push plate is arranged at the bottom of the support frame, and a hydraulic cylinder is arranged on one side, away from the support frame, of the push plate; the support frame is of a C-shaped structure; the top of the supporting frame is communicated with the discharge hole.

Preferably, the support frame comprises: the upper support frame and the lower support frame are symmetrically arranged; an expansion plate is arranged on one opposite side of the upper support frame and the lower support frame; the telescopic plate is telescopic through a spring; a plurality of air holes are formed in the surface of the expansion plate, an air extracting pump is arranged outside the shell, and the air holes are connected with the air extracting pump through pipelines.

Preferably, a gluing device is arranged on one side of the upper support frame and one side of the lower support frame, which are close to the telescopic plate; the rubber coating device includes: the spraying box is internally provided with a micro pump and is arranged between the upper support frame and the lower support frame; the upper end and the lower end of the spraying box are symmetrically provided with spraying grooves, and two sides of the spraying box are symmetrically provided with sliding rods; the sliding rod is of a telescopic structure; the support frame is close to one side surface of expansion plate and has seted up the spout, the slide bar passes through pulley and spout sliding connection.

Preferably, a glue storage box is arranged on one side, away from the feed inlet, of the spraying box, a conveying belt is arranged between the glue storage box and the spraying box, an extrusion rod is arranged in the conveying belt, an extrusion plate is arranged on the outer wall of the glue storage box, and the extrusion plate is connected with the extrusion rod; a conveying pipe is arranged in the conveying belt; one end of the conveying pipe is communicated with the glue storage box, and the other end of the conveying pipe is communicated with the spraying box;

the upper layer of glass and the lower layer of glass which are cleaned move under the driving of the telescopic clamping plate, the upper layer of glass moves into the upper supporting frame, the lower layer of glass moves into the lower supporting frame, a gap exists between the upper supporting frame and the lower supporting frame at the moment, when the middle layer of glass moves towards the supporting frame, the arc-shaped plate is pushed open towards two sides in the process of moving the middle layer of glass, in the process of pushing open the arc-shaped plate, the arc-shaped plate drives the upper supporting frame and the lower supporting frame to move, the upper supporting frame and the lower supporting frame drive the extension plate to move along the inner wall of the shell, the upper supporting frame and the lower supporting frame respectively move towards one side far away from the supporting frame, and in the process of moving the upper supporting frame and the lower supporting frame, the telescopic plate is driven to move, so that the telescopic plates are in a mutual contact state; the middle layer glass then enters a gap between the upper support frame and the lower support frame;

when the middle-layer glass moves towards the shell, the side wall of the middle-layer glass is in contact with the spraying box, then the spraying box is pushed to move when the middle-layer glass moves, the sliding rod is driven to move in the moving process of the spraying box, the sliding rod moves along the sliding chute, and the sliding rod moves towards one side far away from the feeding hole; when the spraying box moves, the spraying box pushes the conveying belt to move, in the pushing process of the spraying box, the extrusion rod in the conveying belt is extruded, the extrusion rod pushes the extrusion plate under the action of the spraying box, the extrusion plate moves to one side far away from the conveying belt, the extrusion plate extrudes the glue storage box, at the moment, the pressure in the glue storage box is increased, the bonding glue in the glue storage box enters a pipeline in the conveying belt, the bonding glue enters the spraying box through the pipeline and then is conveyed into the spraying groove through the spraying box, and the spraying groove is used for coating glue on the lower surface of the upper-layer glass and the upper surface of the lower-layer glass, so that in the moving process of the glass, the spraying of the glue is realized, the bonding time of the multilayer glass is saved, and the bonding efficiency of the multilayer glass is improved; when the middle-layer glass enters the support frame, the spraying box moves to the farthest end away from the feeding hole;

when the equipment starts, firstly, the multilayer glass subjected to gluing treatment is not subjected to pressing treatment, then, the multilayer glass moves to one side, close to the discharge hole, of the rotating plate under the action of the hydraulic cylinder, and then, the first multilayer glass stays between the discharge hole and the rotating plate; then, a second piece of multi-layer glass enters through the feeding hole, after the second piece of multi-layer glass is coated with glue, the controller controls the sealing plate to be closed, the sealing plate is matched with the sealing strip on the rotating plate, the controller controls the air extracting pump to be started, the air in the shell is extracted outwards by the air extracting pump, the air in the shell enters the pipeline through the air hole and is conveyed into the air extracting pump through the pipeline, and the air in the bonding surface of the multi-layer glass is exhausted; the air in the shell is discharged, so that the shell is in a negative pressure state, the outer part of the shell is in a normal pressure state, at the moment, the multilayer glass positioned on one side of the rotating plate, which is close to the discharge hole, extrudes the rotating plate under the action of gravity, and simultaneously, the external air pressure also extrudes one side, which is close to the rotating plate, under the action of atmospheric pressure, after the rotating plate is extruded, the borne pressure is applied to the surface of the multilayer glass in the shell, so that the multilayer glass in the shell is pressed and fixed in the process of removing bubbles on the bonding surface; after the multilayer glass is bonded, the controller controls the sealing plate to be opened, so that the normal pressure in the shell is recovered, and then the controller controls the hydraulic cylinder to move the multilayer glass to one side close to the discharge hole.

Preferably, a rotating plate is arranged on one side of the upper support frame, which is far away from the lower support frame, and a blocking block is arranged on one side of the rotating plate, which is close to the push plate; the two sides of the push plate are hinged with rotating plates, and one side of each rotating plate, which is close to the hydraulic cylinder, is provided with a stop block; the surface of the rotating plate is provided with a sealing strip;

after the multiple layers of glass are bonded, the controller controls the hydraulic cylinder to be started, the hydraulic cylinder in the hydraulic cylinder pushes the push plate to move, the push plate drives the multiple layers of glass to move towards one side away from the hydraulic cylinder, the push plate pushes the multiple layers of glass to move towards the discharge port, the rotating plate is driven to move in the moving process of the push plate, and the stop block is arranged at the bottom of the rotating plate, so that the multiple layers of glass can be lifted to move in the moving process of the rotating plate; in the moving process of the multilayer glass, the multilayer glass pushes the rotating plate to rotate, the rotating plate rotates to one side close to the discharge port, after the rotating plate rotates, the multilayer glass can be smoothly sent out from the support frame, when the push plate moves to the position above the rotating plate, the rotating plate loses support, then the rotating plate resets, after the rotating plate resets, the controller controls the hydraulic cylinder to recover, the hydraulic cylinder in the hydraulic cylinder drives the push plate to reset, in the resetting process of the push plate, the push plate meets the blockage of the rotating plate, then the rotating plate rotates under the action of the rotating plate, the rotating plate rotates to one side far away from the push plate, the rotating plate rotates, so that the push plate resets smoothly, when the rotating plate leaves the surface of the rotating plate, then the rotating plate resets, and the push plate drives the rotating plate to reset; after the push plate is reset, the conveyed multilayer glass is pressed on the surface of the rotating plate, and the rotating plate lifts the multilayer glass due to the blocking block arranged at the bottom of the rotating plate; the sealing strips on the rotating plate are pressed by the multilayer glass, so that the sealing property inside the shell is improved. When the multilayer glass is placed on the surface of the rotating plate, the multilayer glass close to one side of the feeding hole is stacked one by one, the glass above exerts certain gravity on the multilayer glass at the bottom, pressure maintaining on the multilayer glass at the bottom is realized, the bonding of the multilayer glass is further enhanced, and the bonding quality of the multilayer glass is improved.

Preferably, one sides of the upper support frame and the lower support frame, which are close to the feed port, are provided with telescopic clamping plates, and one sides of the telescopic clamping plates, which are close to the feed port, are provided with suckers; an air pump is arranged outside the shell; the sucker is connected with the air pump through a pipeline.

Preferably, the cleaning device includes: the arc plates are symmetrically arranged on the side wall of the support frame; the two arc-shaped bottom surfaces of the arc-shaped plates are oppositely arranged, a cleaning push is arranged on the arc-shaped bottom surface of each arc-shaped plate, a spray head is arranged on one side, away from the feed inlet, of the cleaning push, a cleaning tank is arranged outside the shell, a water pump is arranged in the cleaning tank, and the spray heads are communicated with the water pump through pipelines; a cleaning roller is arranged at one end, far away from the feeding hole, of the arc-shaped plate, and the cleaning roller is rotatably connected with the arc-shaped plate;

when the upper layer of glass and the lower layer of glass move towards the inside of the shell, the controller controls the telescopic clamping plate to be started, the telescopic clamping plate moves towards one side close to the feeding hole, after the sucker is contacted with the side walls of the upper layer of glass and the lower layer of glass, the controller controls the air pump to be started, the air pump pumps air in the sucker outwards, so that the sucker can firmly clamp the upper layer of glass and the lower layer of glass, when the upper layer of glass and the lower layer of glass move, the lower surface of the upper layer of glass and the upper surface of the lower layer of glass are contacted with the cleaning roller, and the cleaning roller cleans dust and impurities on the lower surface of the upper layer of glass and the upper surface of the lower layer of glass;

when the upper layer glass and the lower layer glass move into the support frame, the middle layer glass is driven by the external clamping device to move towards the inside of the shell, the middle layer glass penetrates through the two arc-shaped plates, the two arc-shaped plates are pushed open by the middle layer glass in the moving process of the middle layer glass, the two arc-shaped plates move towards one side far away from the middle layer glass, the controller controls the water pump to be started, the water pump drives the water in the cleaning tank to convey, the cleaning water is conveyed to the spray head through the pipeline and then is sprayed out outwards through the spray head, the surface of the middle layer glass is cleaned by the sprayed cleaning water, and when the middle layer glass moves, the surface of the middle layer glass is in contact with the cleaning push to scrape the residual cleaning water on the surface of the middle layer glass by the cleaning push, so that the surface of the middle layer glass is clean, dust impurities are prevented from falling onto the surface of the glass, the adhesion of the multilayer glass is influenced, and the adhesion quality of the glass is improved; the cleaned middle glass layer enters a gap between the upper glass layer and the lower glass layer; and then the controller controls the air pump to start, and the air pump pumps the outside air into the sucker, so that the sucker is separated from the upper layer of glass and the lower layer of glass.

Compared with the prior art, the invention has the following beneficial effects:

1. the in-process that the spraying case promoted, the extrusion ram in the extrusion conveyer belt, the extrusion ram pushes the stripper plate under the effect of spraying case, the stripper plate removes to the one side of keeping away from the conveyer belt, the stripper plate extrusion stores up gluey case, store up the pressure increase of gluing incasement this moment, store up the pipeline that the bonding glue in the gluey incasement got into the conveyer belt, the bonding glue gets into in the spraying case through the pipeline, carry to spraying groove in afterwards through the spraying case, through spraying groove upper glass's lower surface and lower floor's glass's upper surface rubber coating, make the in-process that removes at glass, realize the spraying of glue, the time that multilayer glass bonded has been saved, the efficiency that multilayer glass bonded has been improved.

2. The closing plate is controlled to the controller to be closed, the sealing strip on the closing plate and the rotating plate is mutually matched, the air pump is controlled to be started, the air in the shell is outwards pumped by the air pump, the air in the shell enters the pipeline through the air hole, and the air is conveyed to the air pump through the pipeline, so that the air in the bonding surface of the multilayer glass is discharged, the multilayer glass is convenient to bond better, and the bonding quality of the multilayer glass is improved.

3. The in-process that middle level glass removed, the controller control water pump starts, the water pump drives the water transport in the clean jar, clean water passes through the pipe-line transportation to the shower head, outwards spout through the shower head afterwards, spun clean water cleans middle level glass's surface, when middle level glass removed afterwards, middle level glass's surface pushes away the contact with the cleanness, the cleanness pushes away scrapes off the remaining clean water in middle level glass surface, make middle level glass surface clean, avoid dust impurity to fall on glass surface, thereby influence multiple layer glass's bonding, and then the quality that glass bonded has been improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a body diagram of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic structural view of the lower support frame and the hydraulic cylinder;

FIG. 4 is a schematic side view of the present invention;

FIG. 5 is a schematic view of the support frame;

FIG. 6 is a side view of the support bracket;

FIG. 7 is a cross-sectional view of the support frame;

fig. 8 is an enlarged view at a in fig. 4.

In the figure: 1. a housing; 11. a feed inlet; 12. a discharge port; 13. a sealing plate;

2. a bonding device; 21. a support frame; 211. an extension plate; 22. pushing a plate; 221. a rotating plate; 23. a hydraulic cylinder; 24. an upper support frame; 25. a lower support frame; 26. a retractable plate; 261. an air hole; 27. a rotating plate;

3. a cleaning device; 31. an arc-shaped plate; 32. cleaning and pushing; 33. a shower head; 34. a cleaning roller;

4. a gluing device; 41. a spraying box; 42. spraying a groove; 43. a slide bar; 44. a chute; 45. a glue storage box; 451. a pressing plate; 46. and (5) conveying the belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution:

an irradiation resistant multiple layer glass bonding apparatus comprising: the device comprises a shell 1, wherein a feed inlet 11 is formed in the side wall of the shell 1, a discharge outlet 12 is formed in the top of the shell 1, a sealing plate 13 is arranged on one side, away from the shell 1, of the feed inlet 11, and the sealing plate 13 is connected with the outer wall of the shell 1 in a sliding mode through a pulley; a bonding device 2 is arranged inside the shell 1, and the bonding device 2 is used for bonding the multiple layers of glass; a cleaning device 3 is arranged on one side of the shell 1 close to the feed port 11; the cleaning device 3 is used for cleaning the surface of the glass;

the controller controls the telescopic clamping plate to start, and the telescopic clamping plate clamps the glass; the glass moves under the action of the telescopic clamping plate, the glass moves towards one side close to the feed port 11 and enters the shell 1 through the feed port 11, and when the glass enters the shell 1, the surface of the glass meets the cleaning device 3, the cleaning device 3 immediately cleans the surface of the glass, removes dust and impurities on the surface of the glass, and avoids the phenomenon that the surface of the glass is remained with dust and impurities to cause hollowing on the bonding surface of the glass in the bonding process; when the glass moves to the inside of the shell 1, the bonding device 2 is used for gluing and bonding the surface of the glass, when the glass is bonded, the controller controls the sealing plate 13 to move, the sealing plate 13 moves to the position of the feeding hole 11, the feeding hole 11 is closed by the sealing plate 13, and after the glass is bonded, the glass is conveyed out through the discharging hole 12.

As a specific embodiment of the present invention, the bonding apparatus 2 includes: the supporting frame 21 is arranged inside the shell 1, the side walls of the supporting frame 21 are symmetrically provided with extending plates 211, the inner wall of the shell 1 is provided with a slide way, the extending plates 211 are provided with springs, one end of each spring is connected with the inner wall of the slide way, and the supporting frame 21 is in sliding connection with the shell 1 through the extending plates 211 and the slide way; a push plate 22 is arranged at the bottom of the support frame 21, and a hydraulic cylinder 23 is arranged on one side, away from the support frame 21, of the push plate 22; the support frame 21 is of a C-shaped structure; the top of the support frame 21 is communicated with the discharge hole 12.

As an embodiment of the present invention, the supporting frame 21 includes: the upper support frame 24 and the lower support frame 25 are symmetrically arranged; an expansion plate 26 is arranged on one side of the upper support frame 24 opposite to the lower support frame 25; the expansion plate 26 is expanded and contracted through a spring; a plurality of air holes 261 are formed in the surface of the expansion plate 26, an air pump is arranged outside the shell 1, and the air holes 261 are connected with the air pump through a pipeline.

As a specific embodiment of the present invention, the gluing device 4 is disposed on one side of the upper support frame 24 and one side of the lower support frame 25 close to the expansion plate 26; the gluing device 4 comprises: the spraying box 41 is internally provided with a micro pump, and the spraying box 41 is arranged between the upper support frame 24 and the lower support frame 25; the upper end and the lower end of the spraying box 41 are symmetrically provided with spraying grooves 42, and two sides of the spraying box 41 are symmetrically provided with sliding rods 43; the sliding rod 43 is of a telescopic structure; the surface of one side of the support frame 21 close to the expansion plate 26 is provided with a sliding groove 44, and the sliding rod 43 is connected with the sliding groove 44 in a sliding manner through a pulley.

As a specific embodiment of the present invention, a glue storage box 45 is disposed on one side of the spraying box 41 away from the feed inlet 11, a conveying belt 46 is disposed between the glue storage box 45 and the spraying box 41, an extrusion rod is disposed in the conveying belt 46, an extrusion plate 451 is disposed on an outer wall of the glue storage box 45, and the extrusion plate 451 is connected to the extrusion rod; a conveying pipe is arranged in the conveying belt 46; one end of the conveying pipe is communicated with the glue storage box 45, and the other end of the conveying pipe is communicated with the spraying box 41;

the cleaned upper layer glass and the lower layer glass move under the driving of the telescopic clamping plate, the upper layer glass moves into the upper supporting frame 24, the lower layer glass moves into the lower supporting frame 25, a gap exists between the upper supporting frame 24 and the lower supporting frame 25 at the moment, when the middle layer glass moves towards the supporting frame 21, the arc-shaped plate 31 is pushed open towards two sides in the moving process of the middle layer glass, in the pushing open process of the arc-shaped plate 31, the arc-shaped plate 31 drives the upper supporting frame 24 and the lower supporting frame 25 to move, the upper supporting frame 24 and the lower supporting frame 25 drive the extension plate 211 to move along the inner wall of the shell 1, the upper supporting frame 24 and the lower supporting frame 25 respectively move towards one side far away from the supporting frame 21, and in the moving process of the upper supporting frame 24 and the lower supporting frame 25, the telescopic plate 26 is driven to move, so that the telescopic plates 26 are in a mutual contact state; the middle layer glass then enters the gap between the upper support frame 24 and the lower support frame 25;

in the process that the middle-layer glass moves into the shell 1, the side wall of the middle-layer glass is in contact with the spraying box 41, then when the middle-layer glass moves, the spraying box 41 is pushed to move, in the process that the spraying box 41 moves, the sliding rod 43 is driven to move, the sliding rod 43 moves along the sliding chute 44, and the sliding rod 43 moves towards one side far away from the feed port 11; when the spraying box 41 moves, the spraying box 41 pushes the conveying belt 46 to move, in the pushing process of the spraying box 41, the extrusion rod in the conveying belt 46 is extruded, the extrusion rod pushes the extrusion plate 451 under the action of the spraying box 41, the extrusion plate 451 moves towards one side far away from the conveying belt 46, the extrusion plate 451 extrudes the glue storage box 45, at the moment, the pressure in the glue storage box 45 is increased, the bonding glue in the glue storage box 45 enters a pipeline in the conveying belt 46, the bonding glue enters the spraying box 41 through the pipeline, then the controller controls the micro pump in the spraying box 41 to start, and the micro pump drives the bonding glue to move towards the spraying groove 42; then, the bonding glue is conveyed into a spraying groove 42 through a micro pump in a spraying box 41, and the lower surface of the upper layer glass and the upper surface of the lower layer glass are coated with the glue through the spraying groove 42, so that the glue is sprayed in the moving process of the glass; after the middle glass layer enters the support frame 21, the spraying box 41 moves to the farthest end away from the feeding hole 11;

when the equipment starts, the multi-layer glass which is firstly subjected to the gluing treatment is not subjected to the pressing treatment, then the multi-layer glass moves to one side, close to the discharge port 12, of the rotating plate 27 under the action of the hydraulic cylinder 23, and then the first multi-layer glass stays between the discharge port 12 and the rotating plate 27; then, a second piece of multi-layer glass enters through the feeding hole 11, after the second piece of multi-layer glass is coated with glue, the controller controls the sealing plate 13 to be closed, the sealing plate 13 is matched with the sealing strip on the rotating plate 27, the controller controls the air extracting pump to be started, the air extracting pump extracts air in the shell 1 outwards, the air in the shell 1 enters a pipeline through the air hole 261 and is conveyed into the air extracting pump through the pipeline, and air in the bonding surface of the multi-layer glass is exhausted; because the air in the shell 1 is discharged, the interior of the shell 1 is in a negative pressure state, the exterior of the shell 1 is in a normal pressure state, at this time, the multilayer glass on one side of the rotating plate 27 close to the discharge hole 12 extrudes the rotating plate 27 under the action of gravity, meanwhile, under the action of atmospheric pressure, the external air pressure also extrudes towards one side close to the rotating plate 27, and after the rotating plate 27 is extruded, the borne pressure is applied to the surface of the multilayer glass in the shell 1, so that the multilayer glass in the shell 1 is pressed and fixed in the process of removing bubbles on the bonding surface; after the multiple glass is bonded, the controller controls the sealing plate 13 to open, so that the normal pressure in the shell 1 is recovered, and then the controller controls the hydraulic cylinder 23 to move the multiple glass to the side close to the discharge hole 12.

As a specific embodiment of the invention, a rotating plate 27 is arranged on one side of the upper support frame 24 away from the lower support frame 25, and a blocking block is arranged on one side of the rotating plate 27 close to the push plate 22; a rotating plate 221 is hinged to two sides of the push plate 22, and a stop block is arranged on one side of the rotating plate 221 close to the hydraulic cylinder 23; the surface of the rotating plate 27 is provided with a sealing strip;

after the multiple layers of glass are bonded, the controller controls the hydraulic cylinder 23 to be started, the hydraulic cylinder 23 in the hydraulic cylinder 23 pushes the push plate 22 to move, the push plate 22 drives the multiple layers of glass to move towards one side far away from the hydraulic cylinder 23, the push plate 22 pushes the multiple layers of glass to move towards the discharge hole 12, the rotating plate 221 is driven to move in the moving process of the push plate 22, and the stop block is arranged at the bottom of the rotating plate 221, so that the multiple layers of glass can be lifted to move in the moving process of the rotating plate 221; when the multiple layers of glass move, the multiple layers of glass push the rotating plate 27 to rotate, the rotating plate 27 rotates towards one side close to the discharge port 12, after the rotating plate 27 rotates, the multiple layers of glass can be smoothly sent out from the supporting frame 21, when the push plate 22 moves to the upper side of the rotating plate 27, the rotating plate 27 loses support, then the rotating plate 27 resets, after the rotating plate 27 resets, the controller controls the hydraulic cylinder 23 to recover, the hydraulic cylinder 23 in the hydraulic cylinder 23 drives the push plate 22 to reset, in the process of resetting the push plate 22, the push plate 22 meets the blockage of the rotating plate 27, then the rotating plate 221 rotates under the action of the rotating plate 27, the rotating plate 221 rotates towards one side far away from the push plate 22, the rotating plate 221 rotates, so that the push plate 22 resets smoothly, when the rotating plate 221 leaves the surface of the rotating plate 27, then the rotating plate 221 resets, and the push plate 22 drives the rotating plate 221 to reset; after the push plate 22 is reset, the conveyed multiple layers of glass are pressed on the surface of the rotating plate 27, and the rotating plate 27 lifts the multiple layers of glass due to the blocking block arranged at the bottom of the rotating plate 27; the multilayer glass presses the sealing strips on the rotating plate 27, and the sealing performance of the interior of the shell 1 is improved. When the multilayer glass is placed on the surface of the rotating plate, the multilayer glass close to one side of the feeding hole is stacked one by one, and the glass above exerts certain gravity on the multilayer glass at the bottom, so that the pressure maintaining of the multilayer glass at the bottom is realized.

As a specific embodiment of the present invention, a telescopic clamping plate is arranged on one side of the upper support frame 24 and the lower support frame 25 close to the feed port 11, and a suction cup is arranged on one side of the telescopic clamping plate close to the feed port 11; an air pump is arranged outside the shell 1; the sucking disc is connected with an air pump through a pipeline.

As an embodiment of the present invention, the cleaning device 3 includes: the arc plates 31 are symmetrically arranged on the side wall of the support frame 21; the two arc-shaped bottom surfaces of the arc-shaped plates 31 are oppositely arranged, cleaning pushers 32 are arranged on the arc-shaped bottom surfaces of the arc-shaped plates 31, spray heads 33 are arranged on one sides, away from the feed inlet 11, of the cleaning pushers 32, a cleaning tank is arranged outside the shell 1, a water pump is arranged in the cleaning tank, and the spray heads 33 are communicated with the water pump through pipelines; a cleaning roller 34 is arranged at one end of the arc-shaped plate 31 far away from the feed inlet 11, and the cleaning roller 34 is rotatably connected with the arc-shaped plate 31;

when the upper layer glass and the lower layer glass move towards the inside of the shell 1, the controller controls the telescopic clamping plate (the telescopic clamping plate is composed of a plate, a sucker on the plate and a telescopic rod, the telescopic rod is driven by an electric cylinder, the sucker is communicated with an air pump through a pipeline), the telescopic clamping plate moves towards one side close to the feed port 11, after the sucker is contacted with the side walls of the upper layer glass and the lower layer glass, the controller controls the air pump to start, the air pump pumps air in the sucker outwards, so that the sucker firmly clamps the upper layer glass and the lower layer glass, when the upper layer glass and the lower layer glass move, the lower surface of the upper layer glass and the upper surface of the lower layer glass are contacted with the cleaning roller 34, and the cleaning roller 34 cleans dust and impurities on the lower surface of the upper layer glass and the upper surface of the lower layer glass;

after the upper layer glass and the lower layer glass move into the support frame 21, an external clamping device (belonging to the prior art) pushes by using a hydraulic cylinder, a transmission wheel is arranged at the bottom, the glass moves along the transmission wheel under the action of the hydraulic cylinder) to drive the middle layer glass to move towards the inside of the shell 1, the middle layer glass passes through between the two arc plates 31, the middle layer glass jacks the two arc plates 31 in the moving process of the middle layer glass, the two arc plates 31 move towards one side far away from the middle layer glass, in the moving process of the middle layer glass, a controller controls a water pump to be started, the water pump drives water in a cleaning tank to be conveyed, the cleaning water is conveyed to a spray head 33 through a pipeline, then the cleaning water is sprayed outwards through the spray head 33, the surface of the middle layer glass is cleaned by the sprayed cleaning water, and then when the middle layer glass moves, the surface of the middle layer glass is in contact with the cleaning push 32, and the cleaning push 32 scrapes off the residual cleaning water on the surface of the middle layer glass, so that the surface of the middle layer glass is clean; the cleaned middle glass layer enters a gap between the upper glass layer and the lower glass layer; and then the controller controls the air pump to start, and the air pump pumps the outside air into the sucker, so that the sucker is separated from the upper layer of glass and the lower layer of glass.

The working principle of the invention is as follows:

when the equipment starts, the multi-layer glass which is firstly subjected to the gluing treatment is not subjected to the pressing treatment, then the multi-layer glass moves to one side, close to the discharge port 12, of the rotating plate 27 under the action of the hydraulic cylinder 23, and then the first multi-layer glass stays between the discharge port 12 and the rotating plate 27; then enters a second piece of multi-layer glass through the feed inlet 11;

when the upper layer glass and the lower layer glass in the second piece of glass move towards the inside of the shell 1, the controller controls the telescopic clamping plate to start, the telescopic clamping plate moves towards one side close to the feeding hole 11, after the suction disc is contacted with the side walls of the upper layer glass and the lower layer glass, the controller controls the air pump to start, the air pump pumps air in the suction disc outwards, so that the suction disc firmly clamps the upper layer glass and the lower layer glass, in the moving process of the upper layer glass and the lower layer glass, the lower surface of the upper layer glass and the upper surface of the lower layer glass are contacted with the cleaning roller 34, and the cleaning roller 34 cleans dust and impurities on the lower surface of the upper layer glass and the upper surface of the lower layer glass;

when the upper layer glass and the lower layer glass move into the support frame 21, the middle layer glass is driven by the external clamping device to move towards the inside of the shell 1 and passes through the space between the two arc-shaped plates 31, the two arc-shaped plates 31 are pushed open by the middle layer glass in the moving process of the middle layer glass, the two arc-shaped plates 31 move towards one side far away from the middle layer glass, the controller controls the water pump to be started in the moving process of the middle layer glass, the water pump drives the water in the cleaning tank to be conveyed, the cleaning water is conveyed to the spray head 33 through a pipeline and then is sprayed outwards through the spray head 33, the sprayed cleaning water cleans the surface of the middle layer glass, and then when the middle layer glass moves, the surface of the middle layer glass is in contact with the cleaning push 32, and the cleaning push 32 scrapes off the residual cleaning water on the surface of the middle layer glass, so that the surface of the middle layer glass is clean;

the cleaned upper layer glass and the lower layer glass move under the driving of the telescopic clamping plate, the upper layer glass moves into the upper supporting frame 24, the lower layer glass moves into the lower supporting frame 25, a gap exists between the upper supporting frame 24 and the lower supporting frame 25 at the moment, when the middle layer glass moves towards the supporting frame 21, the arc-shaped plate 31 is pushed open towards two sides in the moving process of the middle layer glass, in the pushing open process of the arc-shaped plate 31, the arc-shaped plate 31 drives the upper supporting frame 24 and the lower supporting frame 25 to move, the upper supporting frame 24 and the lower supporting frame 25 drive the extension plate 211 to move along the inner wall of the shell 1, the upper supporting frame 24 and the lower supporting frame 25 respectively move towards one side far away from the supporting frame 21, and in the moving process of the upper supporting frame 24 and the lower supporting frame 25, the telescopic plate 26 is driven to move, so that the telescopic plates 26 are in a mutual contact state; the middle layer glass then enters the gap between the upper support frame 24 and the lower support frame 25; the cleaned middle glass layer enters a gap between the upper glass layer and the lower glass layer; then the controller controls the air pump to start, and the air pump pumps outside air into the sucker to separate the sucker from the upper layer of glass and the lower layer of glass;

in the process that the middle-layer glass moves into the shell 1, the side wall of the middle-layer glass is in contact with the spraying box 41, then when the middle-layer glass moves, the spraying box 41 is pushed to move, in the process that the spraying box 41 moves, the sliding rod 43 is driven to move, the sliding rod 43 moves along the sliding chute 44, and the sliding rod 43 moves towards one side far away from the feed port 11; when the spraying box 41 moves, the spraying box 41 pushes the conveying belt 46 to move, in the pushing process of the spraying box 41, the extrusion rod in the conveying belt 46 is extruded, the extrusion rod pushes the extrusion plate 451 under the action of the spraying box 41, the extrusion plate 451 moves to the side far away from the conveying belt 46, the extrusion plate 451 extrudes the glue storage box 45, at the moment, the pressure in the glue storage box 45 is increased, the bonding glue in the glue storage box 45 enters the pipeline in the conveying belt 46, the bonding glue enters the spraying box 41 through the pipeline, then is conveyed to the spraying groove 42 through the spraying box 41, and is coated on the lower surface of the upper layer glass and the upper surface of the lower layer glass through the spraying groove 42, so that the glue spraying is realized in the moving process of the glass; after the middle glass layer enters the support frame 21, the spraying box 41 moves to the farthest end away from the feeding hole 11;

after the second piece of multi-layer glass is coated with glue, the controller controls the sealing plate 13 to be closed, the sealing plate 13 is matched with the sealing strip on the rotating plate 27, the controller controls the air pump to be started, the air pump pumps air in the shell 1 outwards, the air in the shell 1 enters the pipeline through the air hole 261 and is conveyed into the air pump through the pipeline, and therefore the air in the bonding surface of the multi-layer glass is exhausted; because the air in the shell 1 is discharged, the interior of the shell 1 is in a negative pressure state, the exterior of the shell 1 is in a normal pressure state, at this time, the multilayer glass on one side of the rotating plate 27 close to the discharge hole 12 extrudes the rotating plate 27 under the action of gravity, meanwhile, under the action of atmospheric pressure, the external air pressure also extrudes towards one side close to the rotating plate 27, and after the rotating plate 27 is extruded, the borne pressure is applied to the surface of the multilayer glass in the shell 1, so that the multilayer glass in the shell 1 is pressed and fixed in the process of removing bubbles on the bonding surface; after the multilayer glass is bonded, the controller controls the sealing plate 13 to be opened, so that the normal pressure in the shell 1 is recovered, and then the controller controls the hydraulic cylinder 23 to move the multilayer glass to one side close to the discharge hole 12;

after the multiple layers of glass are bonded, the controller controls the hydraulic cylinder 23 to be started, the hydraulic cylinder 23 in the hydraulic cylinder 23 pushes the push plate 22 to move, the push plate 22 drives the multiple layers of glass to move towards one side far away from the hydraulic cylinder 23, the push plate 22 pushes the multiple layers of glass to move towards the discharge hole 12, the rotating plate 221 is driven to move in the moving process of the push plate 22, and the stop block is arranged at the bottom of the rotating plate 221, so that the multiple layers of glass can be lifted to move in the moving process of the rotating plate 221; when the multilayer glass moves, the multilayer glass pushes the rotating plate 27 to rotate, the rotating plate 27 rotates towards one side close to the discharge port 12, after the rotating plate 27 rotates, the multilayer glass can be smoothly sent out from the support frame 21, when the push plate 22 moves to the position above the rotating plate 27, the rotating plate 27 loses support, then the rotating plate 27 resets, after the rotating plate 27 resets, the controller controls the hydraulic cylinder 23 to recover, the hydraulic cylinder 23 in the hydraulic cylinder 23 drives the push plate 22 to reset, in the resetting process of the push plate 22, the push plate 22 meets the block of the rotating plate 27, then the rotating plate 221 rotates under the action of the rotating plate 27, the rotating plate 221 rotates towards one side far away from the push plate 22, the rotating plate 221 rotates, so that the push plate 22 resets smoothly, when the rotating plate 221 leaves the surface of the rotating plate 27, then the rotating plate 221 resets, and the push plate 22 drives the rotating plate 221 to reset; after the push plate 22 is reset, the conveyed multiple layers of glass are pressed on the surface of the rotating plate 27, and the rotating plate 27 lifts the multiple layers of glass due to the blocking block arranged at the bottom of the rotating plate 27; the multilayer glass presses the sealing strips on the rotating plate 27, and the sealing performance of the interior of the shell 1 is improved. When the multilayer glass is placed on the surface of the rotating plate, the multilayer glass close to one side of the feeding hole is stacked one by one, and the glass above exerts certain gravity on the multilayer glass at the bottom, so that the pressure maintaining of the multilayer glass at the bottom is realized.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides an irradiation resistant multiple glazing bonding device which characterized in that: the method comprises the following steps: the device comprises a shell (1), wherein a feed inlet (11) is formed in the side wall of the shell (1), a discharge outlet (12) is formed in the top of the shell (1), a sealing plate (13) is arranged on one side, away from the shell (1), of the feed inlet (11), and the sealing plate (13) is connected with the outer wall of the shell (1) in a sliding mode through a pulley; a bonding device (2) is arranged inside the shell (1), and the bonding device (2) is used for bonding the multilayer glass; a cleaning device (3) is arranged on one side, close to the feed port (11), of the shell (1); the cleaning device (3) is used for cleaning the glass surface.

2. The radiation-resistant multi-layer glass bonding apparatus of claim 1, wherein: the bonding device (2) comprises: the supporting frame (21) is arranged inside the shell (1), the side wall of the supporting frame (21) is symmetrically provided with extension plates (211), the inner wall of the shell (1) is provided with a slide way, the extension plates (211) are provided with springs, one ends of the springs are connected with the inner wall of the slide way, and the supporting frame (21) is connected with the shell (1) in a sliding mode through the extension plates (211) and the slide way; a push plate (22) is arranged at the bottom of the support frame (21), and a hydraulic cylinder (23) is arranged on one side, away from the support frame (21), of the push plate (22); the support frame (21) is of a C-shaped structure; the top of the supporting frame (21) is communicated with the discharge hole (12).

3. The radiation-resistant multi-layer glass bonding apparatus of claim 2, wherein: the support frame (21) comprises: the device comprises an upper support frame (24) and a lower support frame (25), wherein the upper support frame (24) and the lower support frame (25) are symmetrically arranged; a telescopic plate (26) is arranged on one side of the upper support frame (24) opposite to the lower support frame (25); the telescopic plate (26) is telescopic through a spring; a plurality of air holes (261) are formed in the surface of the expansion plate (26), an air suction pump is arranged outside the shell (1), and the air holes (261) are connected with the air suction pump through pipelines.

4. The radiation-resistant multi-layer glass bonding apparatus of claim 3, wherein: a gluing device (4) is arranged on one side of the upper support frame (24) and the lower support frame (25) close to the telescopic plate (26); the gluing device (4) comprises: the spraying device comprises a spraying box (41), wherein a micro pump is arranged in the spraying box (41), and the spraying box (41) is arranged between an upper support frame (24) and a lower support frame (25); the upper end and the lower end of the spraying box (41) are symmetrically provided with spraying grooves (42), and two sides of the spraying box (41) are symmetrically provided with sliding rods (43); the sliding rod (43) is of a telescopic structure; a sliding groove (44) is formed in the surface of one side, close to the telescopic plate (26), of the support frame (21), and the sliding rod (43) is connected with the sliding groove (44) in a sliding mode through a pulley.

5. The apparatus of claim 4, wherein: a glue storage box (45) is arranged on one side, away from the feed inlet (11), of the spraying box (41), a conveying belt (46) is arranged between the glue storage box (45) and the spraying box (41), an extrusion rod is arranged in the conveying belt (46), an extrusion plate (451) is arranged on the outer wall of the glue storage box (45), and the extrusion plate (451) is connected with the extrusion rod; a conveying pipe is arranged in the conveying belt (46); one end of the conveying pipe is communicated with the glue storage box (45), and the other end of the conveying pipe is communicated with the spraying box (41).

6. The radiation-resistant multi-layer glass bonding apparatus of claim 3, wherein: a rotating plate (27) is arranged on one side, away from the lower support frame (25), of the upper support frame (24), and a blocking block is arranged on one side, close to the push plate (22), of the rotating plate (27); a rotating plate (221) is hinged to two sides of the push plate (22), and a stop block is arranged on one side, close to the hydraulic cylinder (23), of the rotating plate (221); the surface of the rotating plate (27) is provided with a sealing strip.

7. The radiation-resistant multi-layer glass bonding apparatus of claim 6, wherein: one sides of the upper support frame (24) and the lower support frame (25) close to the feed port (11) are provided with telescopic clamping plates, and one sides of the telescopic clamping plates close to the feed port (11) are provided with suckers; an air pump is arranged outside the shell (1); the sucking disc is connected with an air pump through a pipeline.

8. The radiation-resistant multi-layer glass bonding apparatus of claim 2, wherein: the cleaning device (3) comprises: the arc plates (31), the arc plates (31) are symmetrically arranged on the side wall of the support frame (21); the two arc-shaped bottom surfaces of the arc-shaped plates (31) are oppositely arranged, a cleaning push (32) is arranged on the arc-shaped bottom surface of the arc-shaped plate (31), a spray head (33) is arranged on one side, away from the feed port (11), of the cleaning push (32), a cleaning tank is arranged outside the shell (1), a water pump is arranged in the cleaning tank, and the spray head (33) is communicated with the water pump through a pipeline; one end of the arc-shaped plate (31) far away from the feed inlet (11) is provided with a cleaning roller (34), and the cleaning roller (34) is rotatably connected with the arc-shaped plate (31).

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