CN114409278A

CN114409278A - Antifog cavity glass processing apparatus

Info

Publication number: CN114409278A
Application number: CN202210002665.0A
Authority: CN
Inventors: 唐道会; 庞松涛
Original assignee: Anhui Qianhui Energy Glass Technology Co ltd
Current assignee: Anhui Qianhui Energy Glass Technology Co ltd
Priority date: 2022-01-04
Filing date: 2022-01-04
Publication date: 2022-04-29
Anticipated expiration: 2042-01-04
Also published as: CN114409278B

Abstract

The present disclosure provides an antifog cavity glass processing apparatus, includes: the inner side of the round drying cylinder is provided with an interval heat-preservation interlayer, and the inner side of the interval heat-preservation interlayer is provided with an inner annular wall; the horizontal conveying frame is arranged on the outer side of the feeding opening; the annular rotating frame is arranged inside the sealed drying bin, and annular gear rings are arranged around the front side and the rear side of the annular rotating frame; and the horizontal bearing frame is circumferentially and uniformly arranged on the outer side of the annular rotating frame in a surrounding manner. According to the invention, the circular drying cylinder is used as a drying space of the glass plate, the glass plate can be conveyed into the circular drying cylinder, and the horizontal bearing frame arranged on the annular rotating frame arranged in the circular drying cylinder in a surrounding manner is used for bearing, so that the glass plate is conveyed in the circular drying cylinder in a surrounding manner through the annular rotating frame, the whole volume of the circular drying cylinder can be greatly reduced while the conveying and drying time is ensured, the occupied area of the circular drying cylinder is conveniently reduced, and the heat loss is reduced so as to reduce the energy consumption.

Description

Antifog cavity glass processing apparatus

Technical Field

The disclosure relates to the technical field of hollow glass processing, in particular to an antifogging hollow glass processing device.

Background

The hollow glass is made up by using several glass sheets and using high-strength high-air-tightness composite adhesive to make the glass sheets be adhered with aluminium alloy frame containing drying agent, and is made into high-efficiency sound-insulating and heat-insulating glass, and is formed from two layers or several layers of plate glass, and the periphery of the hollow glass is adhered with two sheets or several sheets of glass, sealing strip and glass strip by using high-strength high-air-tightness composite adhesive, and the hollow glass can be filled with drying gas in the middle in order to prevent fog from producing in internal sandwich layer, and the frame is filled with drying agent so as to ensure the dryness of air between glass sheets and prevent fog from producing in the hollow glass.

The applicant finds that in the production process of hollow glass, a glass plate needs to be treated before production, the surface of the glass plate is ensured to have no water vapor which is cleaned before, the surface of the glass plate is ensured to be in a dry and clean state, the glass plate needs to be dried, when the glass plate is dried at present, the upper surface and the lower surface of the glass plate are cleaned and dried by high-pressure air when the glass plate is conveyed, but the treatment device needs to convey the glass plate in drying equipment for a longer time in order to keep the drying quality, so that the problems that the whole size of a drying box is large, the occupied space is large, and the energy consumption is high are solved.

Disclosure of Invention

In view of the above, the present disclosure is directed to an anti-fog hollow glass processing and processing device, so as to solve the problems that a glass plate needs to be conveyed in a drying oven for a longer time in order to maintain the drying quality, and the drying oven has a larger overall size, occupies a larger space, and consumes more energy.

Based on the above-mentioned purpose, this disclosure provides an antifog cavity glass processing apparatus, includes:

the drying device comprises a circular drying cylinder, wherein a spaced heat-insulating interlayer is arranged on the inner side of the circular drying cylinder, an inner annular wall is arranged on the inner side of the spaced heat-insulating interlayer, an annular guide rail is arranged on the inner side wall of the inner annular wall, a sealed drying bin is arranged inside the inner annular wall, a feeding opening is horizontally arranged on the side surface of the circular drying cylinder, and a discharging opening is arranged on the lower side of the feeding opening in parallel;

the horizontal conveying frame is arranged on the outer side of the feeding opening, a conveying chute is arranged in the middle of the horizontal conveying frame, a plurality of bearing rollers are uniformly arranged on the inner side of the conveying chute in parallel, and a plurality of lateral rollers are uniformly arranged in the middle of the conveying chute in parallel;

the air outlet is arranged on the front side of the circular drying cylinder, an air exhaust fan is arranged on the inner side of the air outlet, an air inlet is arranged on the rear side of the circular drying cylinder, a filtering protective net is arranged in the middle of the air inlet, an annular heating fin is arranged on the inner side of the air inlet, and a plurality of electric heating pipes are arranged in the middle of the annular heating fin;

the annular rotating frame is arranged inside the sealed drying bin, annular gear rings are arranged around the front side and the rear side of the annular rotating frame, a central rotating shaft is arranged in the center of the annular rotating frame, a spacing bearing is arranged at the shaft end of the central rotating shaft, a bearing support is arranged outside the spacing bearing, a driving motor is arranged at the bottom of the bearing support, and a driving gear is arranged at the shaft end of the driving motor;

the horizontal bearing frame is circumferentially and uniformly arranged on the outer side of the annular rotating frame in a surrounding manner, an embedding chute is arranged in the middle of the horizontal bearing frame, a plurality of clamping rollers are uniformly and parallelly arranged on the inner side of the embedding chute, a plurality of limiting rollers are uniformly and parallelly arranged in the middle of the embedding chute, and guide rollers are arranged on the outer side of the horizontal bearing frame;

the unloading leading truck set up in ejection of compact open-ended inboard, the centre of unloading leading truck is provided with unloading friction area, the inboard in unloading friction area is provided with the unloading drive roller, the axle head of unloading drive roller is provided with the unloading motor.

In some optional embodiments, a horizontal conveying frame is also arranged outside the discharging opening, and the horizontal conveying frame arranged outside the discharging opening are parallel to each other.

In some alternative embodiments, the horizontal centerline of the conveying chute is perpendicular to the axial centerline of the carrier roller, and the axial centerline of the lateral roller is perpendicular to the axial centerline of the carrier roller.

In some optional embodiments, the shaft end of the lateral roller is provided with a synchronous belt pulley, the outer side of the synchronous belt pulley is provided with a transmission belt, the rear end of the transmission belt is provided with a driving belt pulley, and the shaft end of the driving belt pulley is provided with a conveying motor.

In some alternative embodiments, the horizontal center line of the circular drying cylinder and the horizontal center line of the air draft fan are located on the same straight line, the horizontal center line of the annular heating fin and the horizontal center line of the air draft fan are located on the same straight line, and the horizontal center line of the air inlet and the horizontal center line of the air outlet are located on the same straight line.

In some alternative embodiments, the annular rotating frame is rotatably connected with the supporting bracket through the central rotating shaft and the spacing bearing, and the annular gear ring and the driving gear are meshed with each other to form a transmission mechanism.

In some optional embodiments, a touch top plate is arranged at the rear end of the embedding chute, a return spring is arranged at the rear side of the touch top plate, and embedding push rods are symmetrically arranged on the left side and the right side of the touch top plate.

In some optional embodiments, the outer end of the horizontal bearing frame is provided with a limit sleeve, the inner side of the limit sleeve is provided with a limit stop in a sliding fit mode, the middle of the limit stop is provided with a fit clamping groove, and the rear side of the limit stop is provided with a locking spring.

In some optional embodiments, the inner side surface of the touch top plate is perpendicular to the horizontal center line of the engaging sliding groove, and the engaging ejector rod and the engaging clamping groove are matched with each other in size.

In some optional embodiments, arc-shaped unlocking magnets are symmetrically arranged on the left side and the right side of the blanking guide frame, linkage magnets are arranged at the rear ends of the limit stops, and adjacent magnetic poles of the arc-shaped unlocking magnets are different from those of the linkage magnets.

From the above, it can be seen that the antifogging hollow glass processing and processing device provided by the present disclosure, wherein the circular drying cylinder is used as a drying space for the glass plate, the glass plate can be conveyed into the interior of the circular drying cylinder, and is supported by the horizontal bearing frame arranged on the annular rotating frame arranged in the circular drying cylinder in a surrounding manner, so that the glass plate can be conveyed in the circular drying cylinder in a surrounding manner through the annular rotating frame, thereby greatly reducing the overall volume of the circular drying cylinder while ensuring the conveying and drying time, so as to reduce the floor area of the circular drying cylinder, reduce the external surface area of the circular drying cylinder, reduce heat loss and reduce energy consumption, meanwhile, the glass plate can be conveyed into the circular drying cylinder or conveyed out of the circular drying cylinder through the double-layer horizontal conveying frame arranged at the same side, the horizontal conveying frame can clamp the side edge of the glass plate through the conveying chute, and support and convey the glass plate through the bearing roller and the lateral roller, the glass plate and the horizontal conveying frame only have contact at the edge, so the glass plate can be conveyed without scratching the front and back surfaces of the glass plate, and the glass plate conveying device is more convenient and flexible to use.

Drawings

In order to more clearly illustrate the technical solutions in the present disclosure or related technologies, the drawings needed to be used in the description of the embodiments or related technologies are briefly introduced below, and it is obvious that the drawings in the following description are only embodiments of the present disclosure, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic front view of an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of the internal structure of a circular drying cylinder according to an embodiment of the disclosure;

FIG. 3 is a schematic cross-sectional view of a circular drying cylinder according to an embodiment of the disclosure;

FIG. 4 is a schematic structural diagram of a horizontal transfer rack according to an embodiment of the disclosure;

FIG. 5 is an exploded schematic view of an annular turret according to an embodiment of the disclosure;

FIG. 6 is a schematic front view of a toroidal rotating turret according to an embodiment of the disclosure;

FIG. 7 is a cross-sectional structural schematic view of a horizontal carrier of an embodiment of the present disclosure;

fig. 8 is a partial structural schematic view of a horizontal carrier of an embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, the present disclosure is further described in detail below with reference to specific embodiments.

It is to be noted that technical terms or scientific terms used in the embodiments of the present disclosure should have a general meaning as understood by those having ordinary skill in the art to which the present disclosure belongs, unless otherwise defined. The use of "first," "second," and similar terms in the embodiments of the disclosure is not intended to indicate any order, quantity, or importance, but rather to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

The utility model discloses an antifog cavity glass processing apparatus, includes:

the drying device comprises a circular drying cylinder 1, wherein an interval heat-preservation interlayer 101 is arranged on the inner side of the circular drying cylinder 1, an inner annular wall 102 is arranged on the inner side of the interval heat-preservation interlayer 101, an annular guide rail 103 is arranged on the inner side wall of the inner annular wall 102, a sealed drying bin 104 is arranged inside the inner annular wall 102, a feeding opening 105 is horizontally arranged on the side surface of the circular drying cylinder 1, and a discharging opening 106 is arranged in parallel on the lower side of the feeding opening 105;

the horizontal conveying frame 2 is arranged outside the feeding opening 105, a conveying chute 201 is arranged in the middle of the horizontal conveying frame 2, a plurality of bearing rollers 202 are uniformly arranged on the inner side of the conveying chute 201 in parallel, and a plurality of lateral rollers 203 are uniformly arranged in the middle of the conveying chute 201 in parallel;

the air outlet 3 is arranged on the front side of the circular drying cylinder 1, an air exhaust fan 301 is arranged on the inner side of the air outlet 3, an air inlet 302 is arranged on the rear side of the circular drying cylinder 1, a filtering protective net 303 is arranged in the middle of the air inlet 302, an annular heating fin 304 is arranged on the inner side of the air inlet 302, and a plurality of electric heating pipes 305 are arranged in the middle of the annular heating fin 304;

the annular rotating frame 4 is arranged inside the sealed drying bin 104, annular gear rings 401 are arranged around the front side and the rear side of the annular rotating frame 4, a central rotating shaft 402 is arranged at the center of the annular rotating frame 4, a spacing bearing 403 is arranged at the shaft end of the central rotating shaft 402, a bearing support 404 is arranged outside the spacing bearing 403, a driving motor 405 is arranged at the bottom of the bearing support 404, and a driving gear 406 is arranged at the shaft end of the driving motor 405;

the horizontal bearing frame 5 is circumferentially and uniformly arranged on the outer side of the annular rotating frame 4 in a surrounding manner, the middle of the horizontal bearing frame 5 is provided with an embedding sliding groove 501, the inner side of the embedding sliding groove 501 is uniformly provided with a plurality of clamping rollers 502 in parallel, the middle of the embedding sliding groove 501 is uniformly provided with a plurality of limiting rollers 503 in parallel, and the outer side of the horizontal bearing frame 5 is provided with a guide roller 504;

the blanking guide frame 7 is arranged on the inner side of the discharging opening 106, a blanking friction belt 701 is arranged in the middle of the blanking guide frame 7, a blanking driving roller 702 is arranged on the inner side of the blanking friction belt 701, and a blanking motor 703 is arranged at the shaft end of the blanking driving roller 702.

Referring to fig. 1 to 8, as an embodiment of the present invention, an anti-fog hollow glass processing apparatus includes: the drying device comprises a circular drying cylinder 1, wherein an interval heat-preservation interlayer 101 is arranged on the inner side of the circular drying cylinder 1, an inner annular wall 102 is arranged on the inner side of the interval heat-preservation interlayer 101, an annular guide rail 103 is arranged on the inner side wall of the inner annular wall 102, a sealed drying bin 104 is arranged inside the inner annular wall 102, a feeding opening 105 is horizontally arranged on the side surface of the circular drying cylinder 1, and a discharging opening 106 is arranged in parallel on the lower side of the feeding opening 105; the horizontal conveying frame 2 is arranged outside the feeding opening 105, a conveying chute 201 is arranged in the middle of the horizontal conveying frame 2, a plurality of bearing rollers 202 are uniformly arranged on the inner side of the conveying chute 201 in parallel, and a plurality of lateral rollers 203 are uniformly arranged in the middle of the conveying chute 201 in parallel; the air outlet 3 is arranged on the front side of the circular drying cylinder 1, an air exhaust fan 301 is arranged on the inner side of the air outlet 3, an air inlet 302 is arranged on the rear side of the circular drying cylinder 1, a filtering protective net 303 is arranged in the middle of the air inlet 302, an annular heating fin 304 is arranged on the inner side of the air inlet 302, and a plurality of electric heating pipes 305 are arranged in the middle of the annular heating fin 304; the annular rotating frame 4 is arranged inside the sealed drying bin 104, annular gear rings 401 are arranged around the front side and the rear side of the annular rotating frame 4, a central rotating shaft 402 is arranged at the center of the annular rotating frame 4, a spacing bearing 403 is arranged at the shaft end of the central rotating shaft 402, a bearing support 404 is arranged outside the spacing bearing 403, a driving motor 405 is arranged at the bottom of the bearing support 404, and a driving gear 406 is arranged at the shaft end of the driving motor 405; the horizontal bearing frame 5 is circumferentially and uniformly arranged on the outer side of the annular rotating frame 4 in a surrounding manner, the middle of the horizontal bearing frame 5 is provided with an embedding sliding groove 501, the inner side of the embedding sliding groove 501 is uniformly provided with a plurality of clamping rollers 502 in parallel, the middle of the embedding sliding groove 501 is uniformly provided with a plurality of limiting rollers 503 in parallel, and the outer side of the horizontal bearing frame 5 is provided with a guide roller 504; the blanking guide frame 7 is arranged on the inner side of the discharging opening 106, a blanking friction belt 701 is arranged in the middle of the blanking guide frame 7, a blanking driving roller 702 is arranged on the inner side of the blanking friction belt 701, and a blanking motor 703 is arranged at the shaft end of the blanking driving roller 702.

Referring to fig. 1 to 8, optionally, the apparatus finishes drying and surface cleaning of a cleaned glass plate before processing a hollow glass by using a circular drying cylinder 1, a feeding opening 105 and a discharging opening 106 are horizontally arranged on a side surface of the circular drying cylinder 1, the feeding opening 105 and the discharging opening 106 are both arranged on one side of the circular drying cylinder 1 for loading and unloading, the glass plate can be fed into or discharged from the circular drying cylinder 1 through the feeding opening 105 and the discharging opening 106, a horizontal conveying frame 2 for conveying the glass plate is arranged on an outer side of the feeding opening 105, a horizontal conveying frame 2 is also arranged on an outer side of the discharging opening 106, the horizontal conveying frame 2 arranged on the outer side of the feeding opening 105 and the horizontal conveying frame 2 arranged on the outer side of the discharging opening 106 are parallel to each other, a conveying chute 201 is arranged in the middle of the horizontal conveying frame 2, and a plurality of bearing rollers 202 and lateral rollers 203 are uniformly arranged in the conveying chute 201, the horizontal center line of the conveying chute 201 is perpendicular to the axial center line of the bearing roller 202, the axial center line of the lateral roller 203 is perpendicular to the axial center line of the bearing roller 202, the bearing roller 202 and the lateral roller 203 which are symmetrically arranged up and down can provide supporting limit for the edge of the glass plate, the shaft end of the lateral roller 203 is provided with a synchronous belt pulley 204, the outer side of the synchronous belt pulley 204 is provided with a transmission belt 205, the rear end of the transmission belt 205 is provided with a driving belt pulley 206, the shaft end of the driving belt pulley 206 is provided with a conveying motor 207, so that all the lateral rollers 203 can be driven to synchronously rotate through a belt transmission structure, the lateral rollers 203 can drive the glass plate to be conveyed along the conveying chute 201 for loading and unloading, meanwhile, the middle area of the glass plate can be kept suspended and is not contacted with any supporting conveying structure, can carry the glass plate, it is more convenient to use.

Referring to fig. 1 to 8, optionally, the device finishes drying and surface cleaning of a cleaned glass plate before processing a hollow glass through a circular drying cylinder 1, the circular drying cylinder 1 is of a cylindrical structure, and a hollow-structure interval heat-preservation interlayer 101 is arranged between a shell of the circular drying cylinder 1 at the outer side and an inner annular wall 102 at the inner side so as to provide heat insulation and heat preservation for the circular drying cylinder 1, maintain the temperature of a sealed drying chamber 104 inside the circular drying cylinder 1 constant, improve drying efficiency and reduce energy consumption, the front side and the rear side of the circular drying cylinder 1 are respectively provided with an air outlet 3 and an air inlet 302, the inner sides of the air outlet 3 and the air inlet 302 are respectively provided with an air exhaust fan 301 and an annular heating fin 304, meanwhile, the horizontal center line of the circular drying cylinder 1 and the horizontal center line of the air exhaust fan 301 are located on the same straight line, the horizontal center line of the annular heating fin 304 and the horizontal center line of the air exhaust fan 301 are located on the same straight line, the horizontal central line of air intake 302 and the horizontal central line of air outlet 3 are located same straight line, so can be with outside air by the sealed dry storehouse 104 of air intake 302 suction circular drying cylinder 1 inside through exhaust fan 301, carry out by air outlet 3 again, the air is when getting into sealed dry storehouse 104 through air intake 302, alright annular heating fin 304 through a plurality of concentric circles structures, and be provided with a plurality of electric heating pipe 305 in the middle of annular heating fin 304, electric heating pipe 305 alright with heating annular heating fin 304, and then heat the air that passes through, make hot-air can get into and flow through the inside glass sheet of circular drying cylinder 1, in order to carry out drying process to the glass sheet.

Referring to fig. 1 to 8, optionally, the apparatus performs drying and surface cleaning on a glass pane cleaned before processing a hollow glass by using a circular drying cylinder 1, wherein a circular rotating frame 4 is disposed inside the circular drying cylinder 1, a plurality of horizontal carriers 5 are disposed around the circular rotating frame 4, each horizontal carrier 5 can carry one glass pane, the circular rotating frame 4 is rotatably connected with a supporting bracket 404 by a central rotating shaft 402 and a spacing bearing 403, and a transmission mechanism is formed by the mutual engagement between a ring gear 401 and a driving gear 406, so that the horizontal carriers 5 can be driven to rotate along the central rotating shaft 402 by the ring gear 401 and the driving gear 406, and all the horizontal carriers 5 disposed thereon are driven to rotate, so that the horizontal carriers 5 can pass through a feeding opening 105 and a discharging opening 106 one by one, so that the glass pane can be horizontally inserted into the horizontal carriers 5 for feeding and conveying, or bear the frame 5 by the level and go out the completion unloading, and a plurality of glass boards alright carry out the swivelling joint with following annular rotating frame 4, thereby can reduce circular drying cylinder 1's whole volume greatly when guaranteeing to carry dry time, so as to reduce its area, simultaneously because annular rotating frame 4 bears the frame 5 level with the level and sets up inside circular drying cylinder 1, so the hot-air of circulation around can be better contact the glass board that bears on it, in order to improve drying efficiency.

Referring to fig. 1 to 8, optionally, the apparatus can separately carry and convey glass plates by a horizontal carrier 5, a jogged sliding chute 501 is correspondingly arranged in the middle of the horizontal carrier 5, and a plurality of clamping rollers 502 and limiting rollers 503 are uniformly arranged in the middle of the jogged sliding chute 501, after the edges of the glass plates are embedded in the jogged sliding chute 501, the glass plates can be supported and fixed by the clamping rollers 502 and the limiting rollers 503, and can slide along the jogged sliding chute 501 by the clamping rollers 502 and the limiting rollers 503 to carry out feeding and discharging, a touch top plate 505 is arranged at the rear end of the jogged sliding chute 501, a return spring 506 is arranged at the rear side of the touch top plate 505, jogged push rods 507 are symmetrically arranged at the left side and the right side of the touch top plate 505, so that when the glass plates are conveyed to the inner side of the horizontal carrier 5 along the jogged sliding chute 501, the front end of the glass plates can touch the touch top plate 505, and push the jogged push rods 507 connected at the two sides to move synchronously to the rear side, meanwhile, the outer end of the horizontal bearing frame 5 is provided with a limit sleeve 6, the inner side of the limit sleeve 6 is provided with a limit stop 601 in a jogged sliding manner, the middle of the limit stop 601 is provided with a jogged clamping groove 603, the rear side of the limit stop 601 is provided with a locking spring 604, the inner side surface of the touch top plate 505 and the horizontal central line of the jogged sliding groove 501 are mutually vertical, the size of the jogged ejector rod 507 is mutually matched with that of the jogged clamping groove 603, so that when a glass plate is conveyed along the jogged sliding groove 501 to enter the horizontal bearing frame 5 to touch the touch top plate 505, the touch top plate 505 and the jogged ejector rod 507 connected with the two sides of the touch top plate can be pushed to synchronously move towards the rear side, the jogged ejector rod 507 is separated from the jogged clamping groove 603, the limit stop 601 can be pushed by the locking spring 604 to extend out of the limit sleeve 6 so as to stop the rear end of the glass plate, the loading and locking work of the glass plate is finished, and the glass plate is prevented from falling off from the horizontal bearing frame 5 when the glass plate rotates along with the annular rotating frame 4, the reliability of the whole processing is improved, the annular rotary frame 4 rotates clockwise, when the horizontal bearing frame 5 is driven to pass through the feeding opening 105, the horizontal conveying frame 2 can enable the glass plate to pass through the circular drying cylinder 1 from the feeding opening 105, and the glass plate is conveyed into the horizontal bearing frame 5, so that the plurality of horizontal bearing frames 5 sequentially pass through the feeding opening 105 to complete the feeding work when rotating, when the horizontal conveying frame 2 rotates one circle along with the annular rotary frame 4, the glass plate can pass through the discharging opening 106, the discharging guide frame 7 is correspondingly arranged on the inner side of the discharging opening 106, the arc-shaped unlocking magnets 704 are symmetrically arranged on the left side and the right side of the discharging guide frame 7, the linkage magnet 602 is arranged at the rear end of the limit stop 601, the adjacent magnetic poles between the arc-shaped unlocking magnets 704 and the linkage magnet 602 are different, so that when the horizontal conveying frame 2 reaches the discharging opening 106, the arc-shaped unlocking magnets 704 can attract the linkage magnet 602, and then make limit stop 601 move to the rear side and reset, avoid limit stop 601 to block the glass sheet rear side, in order to carry out unblock work, still be provided with unloading friction area 701 on the unloading leading truck 7 simultaneously, unloading friction area 701 can be through unloading drive roller 702 and unloading motor 703 drive removal, and horizontal carriage 2 is when reacing ejection of compact opening 106, the outside of spacing gyro wheel 503 on it is convenient for unloading friction area 701 to contact each other, thereby through unloading friction area 701 drive spacing gyro wheel 503 rotation, and then through spacing gyro wheel 503 drive glass sheet along horizontal carriage 2 move the transport, make glass sheet can be carried to the horizontal carriage 2 outside ejection of compact opening 106 in by horizontal carriage 2, accomplish unloading work, thereby can continuously carry out drying process to the glass sheet, use convenient and fast more, processing drying efficiency is higher.

When the glass plate cleaning machine is used, a cleaned glass plate is conveyed along the horizontal conveying frame 2 outside the feeding opening 105, the edges of two sides of the glass plate are embedded into the conveying chute 201 in the middle of the horizontal conveying frame 2 and are clamped, supported and conveyed by the bearing rollers 202 symmetrically arranged at the upper side and the lower side, meanwhile, the conveying motor 207 drives the driving belt pulley 206 to rotate, the driving belt pulley 206 drives all the synchronous belt pulleys 204 and the lateral rollers 203 to synchronously rotate through the transmission belt 205, the lateral rollers 203 drive the glass plate to slide along the conveying chute 201 and convey the glass plate into the sealed drying bin 104 through the feeding opening 105, the driving motor 405 drives the driving gear 406 to rotate, the driving gear 406 drives the horizontal bearing frame 5 to rotate along the central rotating shaft 402 through the annular gear ring 401, and further drives all the horizontal bearing frames 5 arranged on the driving gear ring to rotate, so that the corresponding horizontal bearing frames 5 move to the inner side of the feeding opening 105, so that the glass plate enters the horizontal bearing frame 5 positioned at the inner side of the feeding opening 105 and is conveyed towards the inner side of the horizontal bearing frame 5 along the embedding chute 501, when the glass plate is conveyed in place, the front end of the glass plate touches the touch top plate 505 and pushes the touch top plate 505 and the embedding push rods 507 connected with the two sides of the touch top plate to synchronously move towards the rear side, so that the embedding push rods 507 are separated from the embedding clamping grooves 603, the limit stop 601 is pushed by the locking spring 604 to extend out of the limit sleeve 6 so as to block the rear end of the glass plate, the glass plate is prevented from falling off from the horizontal bearing frame 5 when rotating along with the annular rotating frame 4, meanwhile, the annular rotating frame 4 rotates to drive the plurality of horizontal bearing frames 5 to sequentially pass through the feeding opening 105 to finish feeding work, meanwhile, the outside air is sucked into the sealed drying bin 104 inside the circular drying cylinder 1 from the air inlet 302 through the air draft fan 301 and then is conveyed out from the air outlet 3, when the air enters the sealed drying bin 104 through the air inlet 302, the glass plate is dried and processed by heating through the electric heating pipe 305 and the annular heating fin 304, so that hot air can enter and flow through the glass plate inside the circular drying cylinder 1, when the horizontal conveying frame 2 rotates one circle along the annular rotating frame 4 and then can pass through the discharging opening 106, when the horizontal conveying frame 2 reaches the discharging opening 106, the arc-shaped unlocking magnet 704 attracts the linkage magnet 602 to enable the limit stop 601 to move and reset towards the rear side, the limit stop 601 is prevented from blocking the rear side of the glass plate, meanwhile, the discharging friction belt 701 is driven to move through the discharging driving roller 702 and the discharging motor 703, the outer sides of the limit rollers 503 on the horizontal conveying frame 2 are convenient for the discharging friction belt 701 to contact with each other, the limit rollers 701 are driven to rotate through the discharging friction belt 701, and then the glass plate is driven to move and convey along the horizontal conveying frame 2 through the limit rollers 503, so that the glass plate can be conveyed to the horizontal conveying frame 2 outside the discharging opening 106 through the horizontal conveying frame 2, and finishing the blanking work, and further finishing the drying and surface cleaning treatment of the cleaned glass plate.

The invention provides an antifogging hollow glass processing and processing device, which uses a round drying cylinder 1 as a drying space of a glass plate, the glass plate can be conveyed into the interior of the glass plate, and is supported by a horizontal bearing frame 5 arranged on an annular rotating frame 4 arranged in the round drying cylinder 1 in a surrounding way, so that the glass plate can be conveyed in the round drying cylinder 1 in the surrounding way through the annular rotating frame 4, thereby greatly reducing the whole volume of the round drying cylinder 1 while ensuring the conveying and drying time, being convenient for reducing the occupied area and the external surface area thereof, reducing heat loss and reducing energy consumption, meanwhile, the glass plate can be conveyed into the round drying cylinder 1 or conveyed out from the round drying cylinder through a double-layer horizontal conveying frame 2 arranged at the same side, the horizontal conveying frame 2 can clamp the side edge of the glass plate through a conveying chute 201, and can support and convey the glass plate through a bearing roller 202 and a lateral roller 203, the glass plate and the horizontal conveying frame 2 only have the edge to have the contact, so can carry the glass plate, can not scratch the glass plate two sides just, it is more convenient nimble to use.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to suggest that the scope of embodiments of the present disclosure (including the claims) is limited to these examples; within the idea of embodiments of the present disclosure, also technical features in the above embodiments or in different embodiments may be combined, steps may be implemented in any order, and there are many other variations of the different aspects of the embodiments of the present disclosure as described above, which are not provided in detail for the sake of brevity.

While the present disclosure has been described in conjunction with specific embodiments thereof, many alternatives, modifications, and variations of these embodiments will be apparent to those of ordinary skill in the art in light of the foregoing description.

The disclosed embodiments are intended to embrace all such alternatives, modifications and variances which fall within the broad scope of the appended claims. Therefore, any omissions, modifications, equivalents, improvements, and the like that may be made within the spirit and principles of the embodiments of the disclosure are intended to be included within the scope of the disclosure.

Claims

1. An antifogging cavity glass processing apparatus which characterized in that includes:

2. The anti-fog hollow glass processing device according to claim 1, wherein a horizontal conveying rack is also arranged outside the discharging opening, and the horizontal conveying rack arranged outside the discharging opening are parallel to each other.

3. The anti-fog hollow glass processing device according to claim 1, wherein a horizontal center line of the conveying chute and an axial center line of the carrying roller are perpendicular to each other, and an axial center line of the lateral roller and an axial center line of the carrying roller are perpendicular to each other.

4. The anti-fog hollow glass processing device according to claim 1, wherein a synchronous pulley is arranged at the shaft end of the lateral roller, a transmission belt is arranged on the outer side of the synchronous pulley, a driving pulley is arranged at the rear end of the transmission belt, and a conveying motor is arranged at the shaft end of the driving pulley.

5. The anti-fog hollow glass processing device according to claim 1, wherein the horizontal center line of the circular drying cylinder and the horizontal center line of the exhaust fan are located on the same straight line, the horizontal center line of the annular heating fin and the horizontal center line of the exhaust fan are located on the same straight line, and the horizontal center line of the air inlet and the horizontal center line of the air outlet are located on the same straight line.

6. The anti-fog hollow glass processing and treating device as claimed in claim 1, wherein the annular rotating frame is rotatably connected with the bearing support through the central rotating shaft and the spacing bearing, and the annular gear ring and the driving gear are meshed with each other to form a transmission mechanism.

7. The processing device for the antifogging hollow glass according to claim 1, wherein a touch top plate is arranged at the rear end of the embedding chute, a return spring is arranged at the rear side of the touch top plate, and embedding push rods are symmetrically arranged on the left side and the right side of the touch top plate.

8. The anti-fog hollow glass processing and treating device as claimed in claim 1, wherein the outer end of the horizontal bearing frame is provided with a limit sleeve, the inner side of the limit sleeve is provided with a limit stop in a sliding fit manner, the middle of the limit stop is provided with a fit clamping groove, and the rear side of the limit stop is provided with a locking spring.

9. The anti-fog hollow glass processing device according to claim 8, wherein the inner side surface of the touch top plate is perpendicular to the horizontal center line of the tabling chute, and the tabling ejector rod and the tabling clamping groove are matched in size.

10. The anti-fog hollow glass processing device according to claim 8, wherein arc-shaped unlocking magnets are symmetrically arranged on the left side and the right side of the blanking guide frame, linkage magnets are arranged at the rear ends of the limit stops, and adjacent magnetic poles of the arc-shaped unlocking magnets and the linkage magnets are different.