CN112901033A - Hollow glass polyisobutylene rubber line sealing system - Google Patents

Abstract

The invention relates to the technical field of glass products, in particular to a hollow glass polyisobutylene rubber line sealing system which comprises a shell, wherein a shell through groove is horizontally formed in the front end surface of the shell, an internal transmission groove is formed in the shell through groove along the left and right directions, at least two feeding rollers are rotatably arranged on the side wall of the lower end of the shell through groove, two motors are fixedly arranged on the rear section of the shell, and a workbench through groove is forwards formed in the center of the rear end surface of the shell along the horizontal direction; the transmission mechanism comprises a workbench which is arranged in the through groove of the workbench in a sliding manner along the vertical direction; the coating mechanism comprises a fixed plate fixedly arranged on the transmission mechanism, and solves the problems that in the existing hollow glass coating device, wire drawing phenomenon is formed between glass side rubber and a grinding plate rubber, and rubber at a vertex angle is accumulated due to movement along the glass side in the coating process.

Description

Hollow glass polyisobutylene rubber line sealing system

Technical Field

The invention relates to the technical field of glass products, in particular to a hollow glass polyisobutylene rubber line sealing system.

Background

The hollow glass is a glass product which is formed with a dry gas space between glass layers by effectively supporting and uniformly separating two or more pieces of glass and bonding and sealing the peripheries of the glass, at present, when side gluing is carried out on the hollow glass, a discharging gun moves along the side edge of the glass, the gluing material is not uniform due to the fact that the two pieces of glass are not well overlapped, the gluing material at a vertex angle is accumulated due to the fact that the two pieces of glass move along the side edge of the glass in the gluing process, in the using process of an existing gluing device, wire drawing phenomenon can be formed between the glass side edge gluing material and a ground flat gluing material plate due to the fact that the two pieces of glass are well overlapped, after glue sealing is carried out on the bottom side of the overlapped glass, if the bottom side of the glass continuously moves in a reciprocating mode on a conveying roller.

Disclosure of Invention

The invention aims to provide a hollow glass polyisobutylene rubber line sealing system to solve the problems that in the prior hollow glass gluing device in the background art, a wire drawing phenomenon is formed between a glass side rubber material and a ground flat rubber material plate, and rubber materials at a vertex angle are accumulated due to movement along the glass side in the gluing process.

The technical scheme of the invention is as follows: a sealing system of hollow glass polyisobutylene rubber line comprises a shell, wherein a shell through groove is horizontally arranged on the front end surface of the shell, an internal transmission groove is arranged inside the through groove of the shell along the left-right direction, at least two feeding rollers are rotatably arranged on the side wall of the lower end of the through groove of the shell, a plurality of feeding rollers are symmetrically arranged along the vertical central line of the through groove of the shell in two groups, each group of feeding rollers are arranged at equal intervals along the left-right direction of the shell, one end of each feeding roller penetrates through the side wall of the through groove of the shell and is positioned in the workbench, a gear belt is sleeved on the circumferential surface of each group of feeding rollers, the rear section of the shell is fixedly provided with two motors, the output ends of the two motors are respectively and fixedly connected with the feeding rollers at the end corners of each group of feeding rollers, and the center of the rear end face of the shell is provided with a workbench through groove forward along the horizontal direction; the transmission mechanism comprises a workbench which is arranged in the through groove of the workbench in a sliding manner along the vertical direction; the coating mechanism comprises a fixing plate fixedly arranged on the transmission mechanism.

As a preferred scheme in the present invention, the transmission mechanism further includes first electromagnetic chutes respectively formed in left and right side end surfaces of the through groove of the workbench, a first electromagnetic slide rail is fixedly disposed inside the first electromagnetic chute along a vertical direction, first electromagnetic sliders are respectively fixedly disposed on the left and right side end surfaces of the workbench, second electromagnetic chutes are formed inside the workbench along a front and rear direction, second electromagnetic slide rails are fixedly disposed on a circumferential side wall of the second electromagnetic chute along a circumferential direction, a cross is rotatably disposed inside the second electromagnetic chute, second electromagnetic sliders are respectively and fixedly connected to four end surfaces of the cross, the second electromagnetic sliders slide along a circumferential direction of the second electromagnetic slide rails, and a first cylinder is sleeved inside the cross along the front and rear direction. When the device is needed to be used, a motor is started, a plurality of feeding rollers are driven to rotate through the transmission of a gear belt, hollow glass needing to be coated is placed on the feeding rollers, the glass is driven to move from right to left through the rotation of the feeding rollers, then a first electromagnetic slide block is controlled to drive a workbench to move along the vertical direction, after the left side of the hollow glass is coated with glue, the workbench is controlled to move into the bottom surface of a through groove of the workbench through groove, then a second electromagnetic slide block is controlled to drive a cross frame to rotate, at the moment, the hollow glass is driven to move left through the starting motor, then the lower edge of the hollow glass is coated with glue, after the hollow glass moves to the left side, the workbench is driven to move upwards along the vertical direction through the control of the first electromagnetic slide block, the right side of the hollow glass is coated with the glue, then the workbench is stopped through the control of the first electromagnetic slide block, the cross is adjusted to rotate by controlling the second electromagnetic slide block, and then the motor is started to drive the hollow glass to move rightwards to glue the upper edge of the hollow glass.

As a preferred scheme in the invention, the coating mechanism further comprises a feeding supporting block fixedly arranged on the right end face of the fixed plate, a feeding through groove is formed in the upper end face of the feeding supporting block along the vertical direction, a roller slider sliding groove is formed in the feeding supporting block along the horizontal direction, the roller slider sliding groove is vertically communicated with the feeding through groove in a T shape, a roller through groove is formed in the feeding supporting block along the front-back direction, the roller through groove is communicated with the roller slider sliding groove, and the side end face of the fixed plate is fixedly connected with the output end of the first air cylinder. When the hollow glass is not glued, the feeding through groove is communicated with the polyisobutylene adhesive in a feeding mode, when the side edge of the hollow glass is glued, the first air cylinder is started to drive the fixing plate to move to the side wall of the hollow glass, and the side edge, provided with the roller through groove, of the feeding supporting block is in contact with the gluing edge of the hollow glass.

As a preferred scheme in the invention, the coating mechanism further comprises a roller shaft slide block slidably arranged in a roller shaft slide block sliding groove, a first spring is connected between a side end face of the roller shaft slide block and a side wall of the roller shaft slide block sliding groove, a slide block rotating groove is formed in the roller shaft slide block along the front-back direction, a roller inner shaft is rotatably arranged in the slide block rotating groove along the front-back direction, a feeding roller is sleeved on the circumferential surface of the roller inner shaft, at least two feeding roller clamping grooves are formed in the outer circumferential surface of the feeding roller along the axial direction, a plurality of feeding roller clamping grooves are arranged at equal intervals along the circumferential direction of the feeding roller, the feeding roller is clamped in the roller through groove in the initial state, and the outer circumferential surface of the feeding roller is in contact with the. When the rubber coating begins, through contacting the feeding running roller with glass's edge, through the direction motion and the first spring of extrusion feeding running roller propelling movement roller to roller slider spout, make the feeding running roller break away from the contact of leading to the groove with the running roller, when the feeding running roller is in relative glass motion, the feeding running roller drives the interior rotation of running roller, thereby make the rotatory drive of leading to inslot portion of feeding polyisobutene glue through the feeding running roller come out, and the inside at the feeding running roller draw-in groove is glued to the rotatory polyisobutene along with the feeding running roller card, along with the rotatory edge department of painting at cavity glass of feeding running roller, and utilize feeding running roller draw-in groove polyisobutene glue to avoid the polyisobutene glue to keep in and splash out.

As a preferable scheme in the present invention, the coating mechanism further includes a driving gear fixedly connected to front and rear end surfaces of an inner shaft of the roller, the front end surface of the roller slider chute is fixedly provided with a fixed rack in a vertical direction, the driving gear is engaged with the fixed rack in an initial state, the front and rear end surfaces of the feeding through groove are respectively provided with a gear rotating groove, a first gear, a second gear, a third gear, and a fourth gear are arranged inside the gear rotating groove in a manner of rotating at equal intervals in the vertical direction from top to bottom, and the fourth gear can be engaged with the driving gear. Drive driving gear and fourth gear intermeshing through the connection of axle in the running roller when feeding running roller compressed, it is rotatory along with the rotatory fourth gear that drives of driving gear, it is rotatory to drive the third gear at the meshing that utilizes fourth gear and third gear, it is rotatory to drive the second gear at the meshing that utilizes third gear and second gear, it is rotatory to drive first gear at the meshing that utilizes second gear and first gear, it dials the synchronous rotation in the board to drive along with the rotatory drive of first gear, thereby drive and dial the board and dial board circular slot internal rotation, the stirring of leading to is glued to the polyisobutylene that the logical groove of feeding got into through to the rotation of dialling the board.

As a preferable scheme in the invention, the coating mechanism further comprises dial plate circular grooves formed in the front side wall and the rear side wall of the feeding through groove, a dial plate inner shaft is fixedly connected in the axial direction of the first gear, three dial plates are fixedly arranged on the outer circumferential surface of the dial plate inner shaft and are arranged at equal intervals in the circumferential direction of the dial plate inner shaft, the three dial plates are rotatably arranged in the dial plate circular grooves, a triangular scraping block is fixedly connected to the right end surface of the feeding supporting block, the length distance of the triangular scraping block in the front-rear direction is smaller than the axial distance of the feeding roller, scraping block inner grooves are formed in the triangular scraping block in the front-rear direction, a baffle sliding groove is formed in the feeding supporting block in the vertical direction and is communicated with the scraping block inner grooves and the dial plate circular grooves, a baffle is slidably arranged in the baffle sliding groove, and the upper end surface of the baffle is connected with the top surface of the baffle sliding groove through, the shifting plate is contacted with the lower end surface of the baffle plate in the rotating process. When the gluing operation is started, the triangular scraping block is clamped at the gap of the hollow glass, when the feeding roller and the hollow glass move relatively, the triangular scraping block scrapes the polyisobutylene rubber at the gap of the hollow glass, so that the polyisobutylene rubber in the gap of the hollow glass is in a parallel and uniform state, the accumulation of rubber materials at the side edge and the vertex angle of the glass in the gluing process is avoided, redundant rubber materials are temporarily stored in the inner groove of the scraping block in the moving process of the triangular scraping block relative to the hollow glass, meanwhile, the shifting plate drives the baffle to move along the vertical direction in the rotating process of the shifting plate, the baffle is pushed to extrude the second spring, the baffle reciprocates in the baffle sliding groove, the removal of redundant polyisobutylene rubber in the inner groove of the scraping block is avoided, and the redundant rubber materials in the inner groove of the scraping block enter the feeding through groove again to be collected under the driving of the shifting plate, the sizing material is saved, and the waste is avoided.

According to the preferable scheme, the coating mechanism further comprises a supporting plate fixedly connected to the right end face of the fixing plate, a second air cylinder is fixedly connected to the rear end face of the supporting plate, a transmission plate is fixedly connected to the output end of the second air cylinder, a scraper shaft groove is formed in the rear end face of the transmission plate in the vertical direction, a scraper shaft is rotatably arranged in the scraper shaft groove, a scraper is rotatably arranged on the rear end face of the transmission plate, the scraper is fixedly connected with the circumferential side wall of the scraper shaft, an inner scraper groove is formed in the scraper, an opening of the inner scraper groove is located on the right end face of the scraper, a first torsion spring is arranged between the scraper shaft and the scraper shaft groove, and an included angle formed by the right end face of the scraper in the initial state and the right end face of the. When one side edge of the hollow glass is in gluing contact, the second cylinder is started to push the transmission plate to move towards the edge of the hollow glass, the scraper plate is made to contact with the edge vertex angle of the hollow glass, then the second cylinder is reset, the side edge, close to the transmission plate, of the scraper plate is made to contact with the edge, then the polyisobutylene at the corner is ground flat by the scraper plate under the pulling of the second cylinder, meanwhile, the scraper plate collects the residual polyisobutylene in the scraper plate after being ground flat along with the retraction of the scraper plate in the transmission plate, and meanwhile, the scraper plate is reset and overturned under the action of the torsion spring, so that the phenomenon of wire drawing formed between the rubber material and the ground flat rubber material plate is avoided.

Advantageous effects

The invention provides a hollow glass polyisobutylene rubber line sealing system through improvement, compared with the prior art, the hollow glass polyisobutylene rubber line sealing system has the following improvements and advantages:

1. through setting up coating mechanism, realized when feeding running roller and cavity glass relative movement, the triangle is scraped the piece and is scraped the polyisobutylene glue of cavity glass clearance department to make the polyisobutylene glue in the cavity glass clearance be in under the parallel even state, avoid the rubber coating in-process to cause glass side and apex angle department sizing material to pile up.

2. Through setting up coating mechanism, still realize that the polyisobutene of contained angle department is ground flat at the drawing lower scraper blade of second cylinder, simultaneously along with the scraper blade is collected the unnecessary polyisobutene after grinding flat in the scraper blade inside groove at the retraction in-process scraper blade of driving plate, the scraper blade resets the upset under the effect of torsional spring simultaneously to avoid sizing material and grinding to form the wire drawing phenomenon and take place between the sizing material board.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a top view of the present invention.

Fig. 3 is a cross-sectional view taken at a-a in fig. 2.

Fig. 4 is a partially enlarged view of a portion Q in fig. 3.

Fig. 5 is a schematic view of the coating mechanism of the present invention.

Fig. 6 is a top view of the coating mechanism of the present invention.

Fig. 7 is a side view of the coating mechanism of the present invention.

Fig. 8 is a cross-sectional view taken at D-D in fig. 6.

Fig. 9 is a sectional view taken at S-S in fig. 6.

Fig. 10 is a partially enlarged view of W in fig. 9.

Fig. 11 is a perspective view of the cross-section at S-S in fig. 6.

Fig. 12 is a cross-sectional view at F-F in fig. 7.

Fig. 13 is a partially enlarged view of a portion E in fig. 12.

In the figure, a housing 10, a housing through groove 11, a feeding roller 12, a workbench through groove 13, a first electromagnetic chute 14, a first electromagnetic slide rail 15, a first electromagnetic slide block 16, a workbench 17, a second electromagnetic slide block 18, a feeding roller slot 19, a cross 20, a first cylinder 21, a fixing plate 22, a support plate 23, a second cylinder 24, a feeding support block 25, a second electromagnetic chute 26, a second electromagnetic slide rail 27, a roller shaft slide block 28, a fixing rack 29, a driving gear 30, a first gear 31, a second gear 32, a third gear 33, a fourth gear 34, a roller through groove 35, a roller inner shaft 36, a feeding roller 37, a triangular scraping block 38, a scraping block inner groove 39, a shifting plate inner shaft 40, a shifting plate 41, a shifting plate circular groove 42, a baffle plate sliding groove 43, a baffle plate 44, a feeding through groove 45, a driving plate 46, a scraping plate shaft groove 47, a scraping plate shaft 48, a scraping plate 49, a scraping plate inner groove 50, a slide block rotating groove 51, gear rotating groove 52, roller shaft slide block sliding groove 53, motor 54, gear belt 55 and transmission inner groove 56.

Detailed Description

The present invention will be described in detail with reference to fig. 1 to 13, and the technical solutions in the embodiments of the present invention will be clearly and completely described, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. 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.

As shown in figure 1 of the drawings, in which, as shown in fig. 2 and 3, the invention is a hollow glass polyisobutylene rubber line sealing system, which comprises a casing 10, wherein a casing through groove 11 is horizontally formed on the front end surface of the casing 10, an internal transmission groove 56 is formed in the casing through groove 11 along the left-right direction, at least two feeding rollers 12 are rotatably arranged on the side wall of the lower end of the casing through groove 11, a plurality of feeding rollers 12 are symmetrically arranged along the vertical central line of the casing through groove 11 in two groups, each group of feeding rollers 12 is arranged along the left-right direction of the casing 10 at equal intervals, one end of each feeding roller 12 penetrates through the side wall of the casing through groove 11 and is positioned in a workbench 17, a gear belt 55 is sleeved on the circumferential surface of each group of feeding rollers 12, two motors 54 are fixedly arranged on the rear section of the casing 10, the output ends of the two motors 54 are respectively and fixedly connected with the feeding rollers 12 at the end corners of each group of feeding rollers 12; the transmission mechanism comprises a workbench 17 which is arranged in the through groove 13 of the workbench in a sliding manner along the vertical direction; the coating mechanism comprises a fixing plate 22 fixedly arranged on the transmission mechanism.

As shown in fig. 3 and 4, the transmission mechanism further includes a first electromagnetic sliding slot 14 respectively formed in left and right end faces of the through slot 13 of the workbench, a first electromagnetic slide rail 15 is fixedly disposed inside the first electromagnetic sliding slot 14 along a vertical direction, a first electromagnetic slider 16 is fixedly disposed on each of the left and right end faces of the workbench 17, a second electromagnetic sliding slot 26 is formed inside the workbench 17 along a front-back direction, a second electromagnetic slide rail 27 is fixedly disposed on a circumferential side wall of the second electromagnetic sliding slot 26 along a circumferential direction, a cross 20 is rotatably disposed inside the second electromagnetic sliding slot 26, second electromagnetic sliders 18 are respectively and fixedly connected to four end faces of the cross 20, the second electromagnetic sliders 18 slide along the circumferential direction of the second electromagnetic slide rail 27, and a first cylinder 21 is sleeved inside the cross 20 along the front-back direction.

Further, when the device is needed, a motor 54 is started, a plurality of feeding rollers 12 are driven to rotate through the transmission of a gear belt 55, the hollow glass to be coated is placed on the feeding rollers 12, the glass is driven to move from right to left through the rotation of the feeding rollers 12, then the first electromagnetic slide block 16 is controlled to drive the workbench 17 to move along the vertical direction, after the left side edge of the hollow glass is coated with glue, the first electromagnetic slide block 16 is controlled to drive the workbench 17 to move into the bottom surface of the through groove 13 of the workbench, then the second electromagnetic slide block 18 is controlled to drive the cross 20 to rotate, at the moment, the motor 54 is started to drive the hollow glass to move left, then the lower edge of the hollow glass is coated with glue, after the hollow glass moves to the left side, at the moment, the first electromagnetic slide block 16 is controlled to drive the workbench 17 to move upwards along the vertical direction, so as to coat the right side of the hollow glass, then the workbench 17 is stopped by controlling the first electromagnetic slide block 16, the cross 20 is adjusted to rotate by controlling the second electromagnetic slide block 18, and then the motor 54 is started to drive the hollow glass to move rightwards to glue the upper edge of the hollow glass.

As shown in fig. 5, fig. 6 and fig. 7, the coating mechanism further includes a fixed feeding support block 25 disposed on the right end face of the fixed plate 22, a feeding through groove 45 is disposed on the upper end face of the feeding support block 25 along the vertical direction, a roller slider chute 53 is disposed in the feeding support block 25 along the horizontal direction, the roller slider chute 53 is vertically communicated with the feeding through groove 45 in a T shape, a roller through groove 35 is disposed in the feeding support block 25 along the front-back direction, the roller through groove 35 is communicated with the roller slider chute 53, and the side end face of the fixed plate 22 is fixedly connected with the output end of the first cylinder 21.

Further, before gluing the hollow glass, the feeding through groove 45 is communicated with the polyisobutylene adhesive in a feeding mode, when the side edge of the hollow glass is glued, the first air cylinder 21 is started to drive the fixing plate 22 to move to the side wall of the hollow glass, and the side edge of the feeding supporting block 25, provided with the roller through groove 35, is in contact with the gluing edge of the hollow glass.

As shown in fig. 8, 9 and 11, the coating mechanism further includes a roller slider 28 slidably disposed inside the roller slider chute 53, a first spring is connected between a side end surface of the roller slider 28 and a side wall of the roller slider chute 53, a slider rotating groove 51 is disposed inside the roller slider 28 along the front-back direction, a roller inner shaft 36 is rotatably disposed inside the slider rotating groove 51 along the front-back direction, a feeding roller 37 is sleeved on a circumferential surface of the roller inner shaft 36, at least two feeding roller slots 19 are disposed on an outer circumferential surface of the feeding roller 37 along the axial direction, the feeding roller slots 19 are disposed at equal intervals along the circumferential direction of the feeding roller 37, the feeding roller 37 is clamped in the roller through groove 35 in an initial state, and the outer circumferential surface of the feeding roller 37 is in contact with a circumferential side wall of the roller through groove 35.

Further, when glue coating starts, through contacting the feeding roller 37 with the edge of the glass, the feeding roller 37 is pushed to move towards the roller slider chute 53 and extrude the first spring, so that the feeding roller 37 is separated from the contact with the roller through groove 35, when the feeding roller 37 moves relative to the glass, the feeding roller 37 drives the roller inner shaft 36 to rotate, thereby the polyisobutylene glue in the feeding through groove 45 is driven out through the rotation of the feeding roller 37, and the polyisobutylene glue card is arranged in the feeding roller clamping groove 19 along with the rotation of the feeding roller 37, and the polyisobutylene glue is smeared at the edge of the hollow glass along with the rotation of the feeding roller 37, and the polyisobutylene glue is prevented from splashing out by utilizing the feeding roller clamping groove 19.

As shown in fig. 9 and 11, the painting mechanism further includes a driving gear 30 fixedly connected to the front and rear end surfaces of the roller shaft 36, a fixed rack 29 is fixedly disposed on the front end surface of the roller slider chute 53 along the vertical direction, the driving gear 30 is engaged with the fixed rack 29 in an initial state, gear rotating grooves 52 are disposed on the front and rear end surfaces of the feeding through groove 45, a first gear 31, a second gear 32, a third gear 33, and a fourth gear 34 are disposed inside the gear rotating grooves 52 in an equidistant manner along the vertical direction from top to bottom, and the fourth gear 34 can be engaged with the driving gear 30.

Further, when the feeding roller 37 is compressed, the driving gear 30 and the fourth gear 34 are driven to be meshed with each other through the connection of the roller inner shaft 36, the fourth gear 34 is driven to rotate along with the rotation of the driving gear 30, the third gear 33 is driven to rotate through the meshing of the fourth gear 34 and the third gear 33, the second gear 32 is driven to rotate through the meshing of the third gear 33 and the second gear 32, the first gear 31 is driven to rotate through the meshing of the second gear 32 and the first gear 31, the shifting plate inner shaft 40 is driven to synchronously rotate along with the rotation of the first gear 31, so that the shifting plate 41 is driven to rotate in the shifting plate circular groove 42, and the polyisobutylene adhesive entering the feeding through groove 45 is guided and stirred through the rotation of the shifting plate 41.

As shown in fig. 9, 10 and 11, the coating mechanism further includes a dial plate circular groove 42 formed on the front and rear side walls of the feeding through groove 45, a dial plate inner shaft 40 is fixedly connected to the first gear 31 in the axial direction, three dial plates 41 are fixedly arranged on the outer circumferential surface of the dial plate inner shaft 40, the three dial plates 41 are arranged at equal intervals in the circumferential direction of the dial plate inner shaft 40, the three dial plates 41 are rotatably arranged in the dial plate circular groove 42, a triangular scraper block 38 is fixedly connected to the right end surface of the feeding support block 25, the longitudinal length distance of the triangular scraper block 38 is smaller than the axial distance of the feeding roller 37, a scraper inner groove 39 is formed in the triangular scraper block 38 in the longitudinal direction, a baffle plate sliding groove 43 is formed in the feeding support block 25 in the vertical direction, the baffle plate sliding groove 43 is communicated with the scraper inner groove 39 and the dial plate circular groove 42, a baffle plate 44 is slidably arranged in the baffle plate sliding groove 43, the upper end surface of the baffle plate 44 is, the dial plate 41 is in contact with the lower end surface of the stopper 44 during rotation.

Further, when the glue coating operation starts, the triangular scraping block 38 is firstly clamped at the gap of the hollow glass, when the feeding roller 37 and the hollow glass move relatively, the triangular scraping block 38 scrapes the polyisobutylene rubber at the gap of the hollow glass, so that the polyisobutylene rubber in the gap of the hollow glass is in a parallel and uniform state, the accumulation of rubber materials at the side edge and the vertex angle of the glass in the gluing process is avoided, redundant rubber materials are temporarily stored in the scraping block inner groove 39 in the moving process of the triangular scraping block 38 relative to the hollow glass, meanwhile, the shifting plate 41 drives the baffle 44 to move along the vertical direction in the rotating process of the shifting plate 41, the baffle 44 is pushed to extrude the second spring, the baffle 44 performs reciprocating motion in the baffle sliding groove 43, so that the redundant polyisobutylene rubber in the scraping block inner groove 39 is prevented from being removed, and the redundant rubber in the scraping block inner groove 39 is enabled to enter the feeding through groove 45 again to be collected under the driving of the shifting plate 41, the sizing material is saved, and the waste is avoided.

As shown in fig. 12 and 13, the coating mechanism further includes a supporting plate 23 fixedly connected to the right end face of the fixing plate 22, a second cylinder 24 is fixedly connected to the rear end face of the supporting plate 23, a transmission plate 46 is fixedly connected to an output end of the second cylinder 24, a scraper shaft groove 47 is formed in the rear end face of the transmission plate 46 along the vertical direction, a scraper shaft 48 is rotatably arranged in the scraper shaft groove 47, a scraper 49 is rotatably arranged on the rear end face of the transmission plate 46, the scraper 49 is fixedly connected to the circumferential side wall of the scraper shaft 48, an inner scraper groove 50 is formed in the scraper 49, an opening of the inner scraper groove 50 is located on the right end face of the scraper 49, a first torsion spring is arranged between the scraper shaft 48 and the scraper shaft groove 47, and an included angle between the right end face of the scraper 49 in the initial.

Further, when one side edge of the hollow glass is in gluing contact, the second cylinder 24 is started to push the transmission plate 46 to move towards the edge of the hollow glass, the scraping plate 49 is in contact with the edge vertex angle of the hollow glass, then the second cylinder 24 is reset, the scraping plate 49 and the transmission plate 46 are in contact with the edge at the side edge close to each other, then the scraping plate 49 is pulled by the second cylinder 24 to grind flat polyisobutylene at the corner, meanwhile, the scraping plate 49 collects redundant polyisobutylene after being ground flat into the scraping plate inner groove 50 in the retraction process of the scraping plate 49 in the transmission plate 46, and meanwhile, the scraping plate 49 is reset and overturned under the action of the torsion spring, so that the phenomenon of wire drawing between the glue and the ground flat glue is avoided.

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

Claims (8)

1. The utility model provides a cavity glass polyisobutylene glue line driving fit system, includes casing (10), its characterized in that: the front end face of the shell (10) is horizontally provided with a shell through groove (11), the inside of the shell through groove (11) is provided with a transmission inner groove (56) along the left and right direction, the side wall of the lower end of the shell through groove (11) is rotatably provided with at least two feeding rollers (12), a plurality of the feeding rollers (12) are arranged symmetrically by the vertical central line of the shell through groove (11), each group of the feeding rollers (12) is arranged at equal intervals along the left and right direction of the shell (10), one end of each feeding roller (12) penetrates through the side wall of the shell through groove (11) and is positioned in a workbench (17), the circumferential surface of each group of the feeding rollers (12) is sleeved with a gear belt (55), the rear section of the shell (10) is fixedly provided with two motors (54), and the output ends of the two motors (54) are respectively and fixedly connected with the feeding rollers (12) at the end angle of each, a workbench through groove (13) is formed in the center of the rear end face of the shell (10) forwards along the horizontal direction;

the transmission mechanism comprises a workbench (17) which is arranged in the through groove (13) of the workbench in a sliding manner along the vertical direction;

the coating mechanism comprises a fixing plate (22) fixedly arranged on the transmission mechanism.

2. The hollow glass polyisobutylene glue line sealing system of claim 1, wherein: the transmission mechanism also comprises first electromagnetic chutes (14) respectively arranged on the left side end face and the right side end face of the through groove (13) of the workbench, a first electromagnetic slide rail (15) is fixedly arranged in the first electromagnetic slide groove (14) along the vertical direction, the left and right side end surfaces of the workbench (17) are respectively and fixedly provided with a first electromagnetic slide block (16), a second electromagnetic sliding groove (26) is arranged in the workbench (17) along the front-back direction, a second electromagnetic slide rail (27) is fixedly arranged on the circumferential side wall of the second electromagnetic chute (26) along the circumferential direction, a cross (20) is rotatably arranged in the second electromagnetic sliding groove (26), the four end surfaces of the cross (20) are respectively and fixedly connected with a second electromagnetic slide block (18), the second electromagnetic slide block (18) slides along the circumferential direction of a second electromagnetic slide rail (27), a first cylinder (21) is sleeved in the cross (20) along the front-back direction.

3. The hollow glass polyisobutylene glue line sealing system of claim 2, wherein: the coating mechanism further comprises a feeding supporting block (25) fixedly arranged on the right end face of the fixing plate (22), a feeding through groove (45) is formed in the upper end face of the feeding supporting block (25) in the vertical direction, a roller slider sliding groove (53) is formed in the feeding supporting block (25) in the horizontal direction, the second electromagnetic sliding rail (27) is vertically communicated with the feeding through groove (45) in a T shape, a roller through groove (35) is formed in the feeding supporting block (25) in the front-back direction, the roller through groove (35) is communicated with the roller slider sliding groove (53) mutually, and the side end face of the fixing plate (22) is fixedly connected with the output end of the first air cylinder (21).

4. The hollow glass polyisobutylene glue line sealing system of claim 3, wherein: the coating mechanism also comprises a roll shaft sliding block (28) which is arranged in the roll shaft sliding block sliding groove (53) in a sliding way, a first spring is connected between the side end surface of the roll shaft sliding block (28) and the side wall of the roll shaft sliding block sliding groove (53), a slide block rotating groove (51) is arranged in the roller shaft slide block (28) along the front-back direction, the inner part of the slide block rotary groove (51) is provided with a roller inner shaft (36) in a rotary way along the front and back direction, the circumferential surface of the roller inner shaft (36) is sleeved with a feeding roller (37), the outer circumferential surface of the feeding roller (37) is provided with at least two feeding roller clamping grooves (19) along the axial direction, a plurality of feeding roller clamping grooves (19) are arranged at equal intervals along the circumferential direction of the feeding roller (37), the feeding roller (37) is clamped in the roller through groove (35) in the initial state, the outer circumferential surface of the feeding roller (37) is contacted with the circumferential side wall of the roller through groove (35).

5. The hollow glass polyisobutylene glue line sealing system of claim 4, wherein: the coating mechanism further comprises driving gears (30) fixedly connected to the front end face and the rear end face of the roller shaft inner shaft (36) respectively, a fixed rack (29) is fixedly arranged on the front end face of the roller shaft sliding block sliding groove (53) in the vertical direction, the driving gears (30) are meshed with the fixed rack (29) in the initial state, gear rotating grooves (52) are formed in the front end face and the rear end face of the feeding through groove (45) respectively, first gears (31), second gears (32), third gears (33) and fourth gears (34) are arranged in the gear rotating grooves (52) in a rotating mode from top to bottom in the vertical direction at equal intervals, and the fourth gears (34) can be meshed with the driving gears (30).

6. The hollow glass polyisobutylene glue line sealing system of claim 5, wherein: the coating mechanism further comprises a shifting plate circular groove (42) formed in the front side wall and the rear side wall of the feeding through groove (45), a shifting plate inner shaft (40) is fixedly connected to the axial direction of the first gear (31), three shifting plates (41) are fixedly arranged on the outer circumferential surface of the shifting plate inner shaft (40), the three shifting plates (41) are arranged at equal intervals along the circumferential direction of the shifting plate inner shaft (40), the three shifting plates (41) are rotatably arranged in the shifting plate circular groove (42), a triangular scraping block (38) is fixedly connected to the right end face of the feeding supporting block (25), the length distance of the triangular scraping block (38) in the front-rear direction is smaller than the axial distance of the feeding roller (37), a scraping block inner groove (39) is formed in the triangular scraping block (38) in the front-rear direction, a baffle sliding groove (43) is formed in the feeding supporting block (25) in the vertical direction, and the baffle sliding groove (43) is communicated with the scraping block inner groove (39) and the shifting plate circular groove, the inner part of the baffle sliding groove (43) is provided with a baffle (44) in a sliding mode, and the upper end face of the baffle (44) is connected with the top face of the baffle sliding groove (43) through a second spring.

7. The hollow glass polyisobutylene glue line sealing system of claim 6, wherein: the coating mechanism poking plate (41) is in mutual contact with the lower end face of the baffle (44) in the rotating process.

8. The hollow glass polyisobutylene glue line sealing system of claim 3, wherein: the coating mechanism also comprises a supporting plate (23) fixedly connected with the right end surface of the fixing plate (22), the rear end face of the supporting plate (23) is fixedly connected with a second air cylinder (24), the output end of the second air cylinder (24) is fixedly connected with a transmission plate (46), a scraper shaft groove (47) is arranged in the rear end surface of the transmission plate (46) along the vertical direction, a scraper shaft (48) is rotatably arranged in the scraper shaft groove (47), a scraper (49) is rotatably arranged on the rear end face of the transmission plate (46), the scraper (49) is fixedly connected with the circumferential side wall of the scraper shaft (48), an inner scraper groove (50) is formed inside the scraper (49), the opening of the scraper inner groove (50) is positioned on the right end face of the scraper (49), a first torsion spring is arranged between the scraper shaft (48) and the scraper shaft groove (47), the right end face of the scraper (49) in the initial state forms a forty-five degree included angle with the right end face of the transmission plate (46).

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