CN114308570A - Cavity glass seals glue production line - Google Patents

Abstract

The invention relates to the technical field of glass sealing adhesive production, in particular to a hollow glass sealing adhesive production line; the glass plate turning device has the advantages that the phenomenon of manual operation is reduced, the automation degree of equipment is improved, the phenomenon of manual surface turning of the glass plate is reduced, and the use convenience of the equipment is improved; the method comprises the following steps: a support frame; the first transmission device comprises a plurality of groups of first transmission shafts, a plurality of groups of first transmission wheels, two groups of moving frames, a first driving mechanism and a lifting mechanism; the second transmission device comprises a plurality of groups of second transmission shafts which are rotatably arranged in the first arrangement groove, second transmission wheels which are fixedly sleeved on the outer side walls of the plurality of groups of second transmission shafts and second driving mechanisms which are connected with the plurality of groups of second transmission shafts; the rotating device comprises rotating plates arranged on the upper sides of the plurality of groups of first transmission shafts and second transmission shafts and a third driving mechanism connected with the bottom ends of the rotating plates; loading attachment and unloader.

Description

Cavity glass seals glue production line

Technical Field

The invention relates to the technical field of glass sealing adhesive production, in particular to a hollow glass sealing adhesive production line.

Background

As is well known, a hollow glass sealing glue production line is a device used for sealing glue in the production process of hollow glass, and is widely used in the field of glass production; in the prior art, firstly, glass plates are cleaned, the cleaned glass plates are dried, a hollow support frame is placed between two groups of glass plates after drying, then an operator places the two groups of glass plates on the top end of an operation plate, a glue sealing device is used for sealing the edges of the glass plates, and in the glue sealing process, after one side of each glass plate is sealed, the operator needs to rotate the glass plates and sequentially perform glue sealing operations on four sides; the existing hollow glass sealing glue production line is found in use, two groups of glass plates after being placed need to be manually conveyed and subjected to surface turning, so that sealing glue is applied to the side walls of four surfaces, more manual operations are needed, the automation degree of equipment is low, and the use convenience of the equipment is poor.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a hollow glass sealing production line, which reduces the phenomenon of manual operation, improves the automation degree of equipment, reduces the phenomenon of manual surface turning of a glass plate, and improves the use convenience of the equipment.

(II) technical scheme

In order to achieve the purpose, the invention provides the following technical scheme: the invention relates to a hollow glass sealing production line, which comprises:

the rear side of the top end of the support frame is provided with a first setting groove, the left side and the right side of the top end of the support frame are provided with second setting grooves, and the rear side of the left end and the rear side of the right end of the support frame are provided with long holes; the first transmission device is movably arranged in the first setting groove and comprises a plurality of groups of first transmission shafts which can be vertically moved and arranged in the first setting groove, a plurality of groups of first transmission wheels which are fixedly sleeved on the outer side walls of the plurality of groups of first transmission shafts, two groups of moving frames arranged in the two groups of second setting grooves, a first driving mechanism connected with the input ends of the plurality of groups of first transmission shafts and a lifting mechanism connected with the two groups of moving frames, wherein the left end and the right end of each group of first transmission shafts are respectively rotatably connected with the two groups of moving frames after passing through the two groups of long holes; the second transmission device and the first transmission device are arranged in the first setting groove in a crossed manner, and the second transmission device comprises a plurality of groups of second transmission shafts which are rotatably arranged in the first setting groove, second transmission wheels which are fixedly sleeved on the outer side walls of the plurality of groups of second transmission shafts and second driving mechanisms which are connected with the plurality of groups of second transmission shafts; the rotating device comprises rotating plates arranged on the upper sides of the plurality of groups of first transmission shafts and second transmission shafts and a third driving mechanism connected with the bottom ends of the rotating plates; the feeding device is arranged on the support frame, a third setting groove is formed in the front end of the support frame, and the feeding device is rotatably arranged in the third setting groove; and the blanking device is arranged on the rear side of the right end of the support frame.

Preferably, the feeding device comprises a plurality of groups of feeding shafts rotatably arranged in the third setting groove and a fourth driving mechanism connected with the input ends of the plurality of groups of feeding shafts.

Preferably, the blanking device comprises a blanking frame fixedly arranged on the rear side of the right end of the support frame, a plurality of groups of blanking shafts rotatably connected with the blanking frame and a fifth driving mechanism connected with the input ends of the groups of blanking shafts.

Preferably, still include reinforcing mechanism, fixed the setting in the rotor plate lateral wall, reinforcing mechanism includes the multiunit reinforcing frame, and the multiunit reinforcing frame is fixed the setting in multiunit rotor plate lateral wall respectively.

Preferably, the first driving mechanism comprises a first chain wheel arranged on the left side of the left side moving frame, a first chain ring arranged on the outer side wall of the plurality of groups of first chain wheels in a meshed mode, and a first motor arranged on the right side moving frame, the left ends of the plurality of groups of first transmission shafts can rotatably penetrate through the left side moving frame and then are respectively connected with the plurality of groups of first chain wheels, and the right end of the first transmission shaft on the rear side can rotatably penetrate through the right side moving frame and then is connected with the output end of the first motor.

Preferably, elevating system sets up the first fixed plate in two sets of removal frame middle parts including fixed, with the second fixed plate that two sets of first fixed plates are connected and fixed set up in the first cylinder of two sets of second fixed plate bottoms.

Preferably, the second driving mechanism comprises a third chain wheel fixedly sleeved in the middle of the outer side wall of the plurality of groups of second transmission shafts, a fourth chain wheel rotatably arranged on the lower side of the plurality of groups of third chain wheels, a second chain ring in transmission connection with the third chain wheel and the fourth chain wheel, two groups of connecting shafts for connecting the plurality of groups of left fourth chain wheels and the plurality of groups of right fourth chain wheels, and a second motor connected with the rear ends of the two groups of connecting shafts.

Preferably, the third driving mechanism includes a rotating shaft fixedly disposed at the bottom end of the rotating plate, a second cylinder fixedly disposed at the bottom end of the rotating shaft, and a third motor fixedly disposed at the bottom end of the second cylinder.

Preferably, fourth drive mechanism sets up the first gear of multiunit that the groove front side was set up including setting up in the left side second, sets up the first rack circle that sets up with the meshing of the first gear of multiunit and sets up the fourth motor in the middle part of the groove in the right side second, and multiunit material loading axle left end passes behind the support frame left end and is connected with the first gear of multiunit, and the rotatable support frame right-hand member that passes of fourth motor output end is connected with rear side material loading axle.

Preferably, the fifth driving mechanism comprises a plurality of groups of second gears connected with the front ends of the plurality of groups of blanking shafts, a second rack ring meshed with the plurality of groups of second gears, and a fifth motor connected with the front end of the left second gear.

(III) advantageous effects

Compared with the prior art, the invention provides a hollow glass sealing glue production line, which has the following beneficial effects: during the glue sealing process, firstly, the glass plate is placed on a feeding device, the feeding device conveys the glass plate to the top end of a first conveying device, a plurality of groups of first conveying shafts rotate under the driving action of a first driving mechanism, a plurality of groups of first conveying wheels rotate along with the glass plate under the connecting action, the plurality of groups of first conveying wheels drive the glass plate to move backwards, the glass plate is subjected to glue sealing operation on the back side of the glass plate after moving to a proper position, after the glue sealing operation on the back side of the glass plate is finished, a rotating device drives a rotating plate and the glass plate at the top end of the rotating plate to move upwards to a proper position and rotate 90 degrees, the glue sealing surface is replaced, at the moment, the glue sealing operation is carried out again, the periphery of the glass plate is sealed through the circulating operation, after the glue sealing is finished, a lifting mechanism drives the glass plate and the plurality of groups of first conveying wheels to move downwards, and simultaneously, the rotating plate also moves downwards under the action of a third driving mechanism, until the bottom end of the glass plate is contacted with the top end of the second transmission device, the second driving mechanism drives the multiple groups of second transmission shafts and the multiple groups of second transmission wheels to rotate, the glass plate moves towards the right side along with the second transmission shafts under the contact action, the glass plate moves towards the right side to the top end of the blanking device, and the blanking device can perform blanking operation on the glass plate after the glass plate is sealed and glued.

Drawings

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

FIG. 2 is a schematic perspective view of a second transfer device according to the present invention;

FIG. 3 is a schematic perspective view of a first transfer device according to the present invention;

FIG. 4 is a schematic perspective view of FIG. 3 at a different angle;

FIG. 5 is a perspective view of the rotating device and the reinforcing frame according to the present invention;

in the drawings, the reference numbers: 1. a support frame;

2. a first transmission device; 21. a first transmission shaft; 22. a first transfer wheel; 23. a movable frame; 24. a first drive mechanism; 241. a first sprocket; 242. a first chain loop; 243. a first motor; 25. a lifting mechanism; 251. a first fixing plate; 252. a second fixing plate; 253. a first cylinder;

3. a second transmission device; 31. a second transmission shaft; 32. a second transfer wheel; 33. a second drive mechanism; 331. a fourth sprocket; 332. a second chain loop; 333. a connecting shaft; 334 a second motor;

4. a rotating device; 41. a rotating plate; 42. a third drive mechanism; 421. a rotating shaft; 422. a second cylinder; 423. a third motor;

5. a feeding device; 51. a feeding shaft; 52. a fourth drive mechanism; 521. a first gear; 522. a first rack ring; 523. a fourth motor;

6. a blanking device; 61. a blanking frame; 62. a blanking shaft; 63. a fifth drive mechanism; 631. a second gear; 632. a second rack ring; 633. a fifth motor;

7. and (7) reinforcing the frame.

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. 1-5, the present invention provides a hollow glass sealing production line, comprising:

the device comprises a support frame 1, wherein a first setting groove is formed in the rear side of the top end of the support frame 1, second setting grooves are formed in the left side and the right side of the top end of the support frame 1, and long holes are formed in the rear side of the left end and the rear side of the right end of the support frame 1;

the first transmission device 2 is movably arranged in the first setting groove, the first transmission device 2 comprises a plurality of groups of first transmission shafts 21 which can be vertically moved and arranged in the first setting groove, a plurality of groups of first transmission wheels 22 fixedly sleeved on the outer side walls of the plurality of groups of first transmission shafts 21, two groups of moving frames 23 arranged in two groups of second setting grooves, a first driving mechanism 24 connected with the input ends of the plurality of groups of first transmission shafts 21 and a lifting mechanism 25 connected with the two groups of moving frames 23, and the left end and the right end of the plurality of groups of first transmission shafts 21 respectively penetrate through the two groups of long holes and then are respectively rotatably connected with the two groups of moving frames 23;

the second transmission device 3 is crossed with the first transmission device 2 and arranged in the first setting groove, and the second transmission device 3 comprises a plurality of groups of second transmission shafts 31 which are rotatably arranged in the first setting groove, second transmission wheels 32 which are fixedly sleeved on the outer side walls of the plurality of groups of second transmission shafts 31 and second driving mechanisms 33 which are connected with the plurality of groups of second transmission shafts 31;

the rotating device 4 comprises a rotating plate 41 arranged on the upper sides of the plurality of groups of the first transmission shafts 21 and the second transmission shafts 31 and a third driving mechanism 42 connected with the bottom end of the rotating plate 41;

the feeding device 5 is arranged on the support frame 1, a third setting groove is formed in the front end of the support frame 1, and the feeding device 5 can be rotatably arranged in the third setting groove; and

and the blanking device 6 is arranged at the rear side of the right end of the support frame 1.

In the application, during the glue sealing process, firstly, the glass plate is placed on the feeding device 5, the feeding device 5 conveys the glass plate to the top end of the first conveying device 2, the plurality of groups of first conveying shafts 21 all rotate under the driving action of the first driving mechanism 24, the plurality of groups of first conveying wheels 22 rotate along with the glass plate under the connecting action, the plurality of groups of first conveying wheels 22 drive the glass plate to move towards the rear side, glue sealing operation is carried out on the rear side of the glass plate after the glass plate is moved to a proper position, after the glue sealing operation on the rear side of the glass plate is finished, the rotating device 4 drives the rotating plate 41 and the glass plate at the top end of the rotating plate 41 to move upwards to a proper position and rotate 90 degrees, so that the glue sealing surface is replaced, at the moment, glue sealing operation is carried out on the periphery of the glass plate again, after the glue sealing is finished, the lifting mechanism 25 drives the glass plate and the plurality of groups of first conveying wheels 22 to move downwards, meanwhile, the rotating plate 41 also moves downwards under the action of the third driving mechanism 42 until the bottom end of the glass plate contacts with the top end of the second transmission device 3, at this time, the second driving mechanism 33 drives the multiple groups of second transmission shafts 31 and the multiple groups of second transmission wheels 32 to rotate, under the contact action, the glass plate moves towards the right side to the top end of the blanking device 6, and the blanking device 6 can perform blanking operation on the glued glass plate.

Specifically, first setting groove is as shown in fig. 1, and first transmission device 2 and second transmission device 3 all set up in first setting groove, and first setting groove sets up according to first transmission device 2 and second transmission device 3's shape, provides rotatable fixed position to the multiunit second transmission axle 31 of second transmission device 3, improves stability, can provide first transmission device 2 and reciprocate the space simultaneously, improve equipment's reliability in utilization.

Specifically, when the first transfer device 2 is not moved downward, the height of the second transfer wheel 32 in the second transfer device 3 is lower than the height of the plurality of sets of first transfer wheels 22 in the first transfer device 2, so that the operation of transferring the glass sheet to the rear side by the first transfer device 2 during the transfer of the glass sheet can be ensured.

Specifically, the rotating plate 41 in the rotating device 4 is provided with a plurality of sets of holes, and after the rotating plate 41 is rotated by 90 degrees through the plurality of sets of holes, the first transmission wheel 22 and the second transmission wheel 32 can both extend out of the plurality of sets of holes, so that the normal use of the equipment is ensured.

Specifically, the height of the feeding device 5 is the same as the height of the plurality of groups of first transmission wheels 22 in the first transmission device 2, and the height of the discharging device 6 is the same as the height of the plurality of groups of second transmission wheels 32 in the second transmission device 3, so that the feeding process and the discharging process can be carried out without obstruction.

In the embodiment of the present application, the feeding device 5 includes a plurality of sets of feeding shafts 51 rotatably disposed in the third setting groove and a fourth driving mechanism 52 connected to input ends of the plurality of sets of feeding shafts 51.

In this application, when carrying out the material loading of glass board, place the glass board on multiunit material loading axle 51 top, fourth drive mechanism 52 can drive multiunit material loading axle 51 and rotate, and the rotation in-process of multiunit material loading axle 51 can drive the glass board and transmit.

Specifically, the both ends of multiunit material loading axle 51 pass through bearing rotatable coupling with first setting inslot lateral wall respectively, improve pivoted stability.

In the embodiment of the present application, the blanking device 6 includes a blanking frame 61 fixedly disposed at the rear side of the right end of the support frame 1, a plurality of groups of blanking shafts 62 rotatably connected to the blanking frame 61, and a fifth driving mechanism 63 connected to the input ends of the groups of blanking shafts 62.

In this application, after the glass board seals the gluing, under second transmission device 3's transmission effect, the glass board transmits to unloader 6 top, and fifth actuating mechanism 63 drives unloading axle 62 and rotates this moment, and unloading axle 62 drives the glass board and transmits to realize the output of glass board.

Specifically, the outer side walls of the plurality of groups of discharging shafts 62 and the plurality of groups of feeding shafts 51 are all sleeved with rubber rings, so that the phenomenon of collision and abrasion of glass plates in the transmission process can be reduced, friction force is increased, and slipping is reduced.

In the embodiment of the present application, still include reinforcing mechanism, fixed the setting in rotor plate 41 lateral wall, reinforcing mechanism includes multiunit reinforcing frame 7, and multiunit reinforcing frame 7 is fixed the setting respectively in multiunit rotor plate 41 lateral wall.

In this application, reinforcing frame 7 can strengthen rotating plate 41, reduces the phenomenon that rotating plate 41 broke under the weight effect of glass board.

In the embodiment of the present application, the first driving mechanism 24 includes a first chain wheel 241 disposed on the left side of the left moving frame 23, a first chain ring 242 engaged with the outer side walls of the plurality of groups of first chain wheels 241, and a first motor 243 disposed on the right side of the right moving frame 23, the left ends of the plurality of groups of first transmission shafts 21 rotatably penetrate through the left moving frame 23 and are respectively connected to the plurality of groups of first chain wheels 241, and the right end of the rear first transmission shaft 21 rotatably penetrates through the right moving frame 23 and is connected to the output end of the first motor 243.

In this application, when the first driving mechanism 24 drives the first transmission shafts 21 of multiple groups to rotate, the first motor 243 drives the first chain wheel 241 of one group to rotate, under the transmission action of the first chain ring 242, the first chain wheels 241 of multiple groups all rotate, under the connection action, the first transmission shafts 21 of multiple groups rotate therewith, and the first transmission wheels 22 of multiple groups rotate therewith, so that the driving operation of the first driving mechanism 24 on the first transmission device 2 can be realized.

Specifically, the plurality of sets of first sprockets 241, the first chain rings 242, and the first motor 243 are respectively disposed in the grooves of the two sets of moving frames 23, so that the first sprockets 241 and the like are not obstructed when the first transmission device 2 moves up and down.

In the embodiment of the present application, the lifting mechanism 25 includes a first fixing plate 251 fixedly disposed at the middle of the two sets of moving frames 23, a second fixing plate 252 connected to the two sets of first fixing plates 251, and a first cylinder 253 fixedly disposed at the bottom end of the two sets of second fixing plates 252.

In this application, when elevating system 25 drove first transmission device 2 and reciprocates, multiunit first cylinder 253 drove two sets of second fixed plates 252 respectively and moves down, and under the connection effect, two sets of first fixed plates 251 move down thereupon, and under the connection effect, first transmission device 2 moves down thereupon, can realize the downstream of glass board this moment.

Specifically, the bottom end of the first cylinder 253 of the multiple groups is fixedly connected with the bottom end of the first setting groove, so that the stability of the first cylinder 253 is improved.

In the embodiment of the present application, the second driving mechanism 33 includes a third sprocket fixedly sleeved on the middle portion of the outer side wall of the plurality of sets of second transmission shafts 31, a fourth sprocket 331 both rotatably disposed on the lower side of the plurality of sets of third sprockets, a second chain loop 332 in transmission connection with the third sprocket and the fourth sprocket 331, two sets of connection shafts 333 connecting the left plurality of sets of fourth sprockets 331 and the right plurality of sets of fourth sprockets 331, and a second motor 334 connected with the rear ends of the two sets of connection shafts 333.

In this application, when second transmission device 3 drives, second motor 334 drives connecting axle 333 and rotates, when two sets of connecting axles 333 all rotated, can drive multiunit fourth sprocket 331 and rotate thereupon, under the transmission action of second chain circle 332, multiunit third sprocket rotates thereupon, under the linkage action, multiunit second transmission axle 31 rotates thereupon, under the fixed connection effect, multiunit second transmission wheel 32 rotates thereupon, this moment multiunit second transmission wheel 32 can transmit glass board to unloader 6 on.

In the embodiment of the present application, the third driving mechanism 42 includes a rotating shaft 421 fixedly disposed at the bottom end of the rotating plate 41, a second cylinder 422 fixedly disposed at the bottom end of the rotating shaft 421, and a third motor 423 fixedly disposed at the bottom end of the second cylinder 422.

In this application, when third actuating mechanism 42 drives the glass board and rotates, at first second cylinder 422 drives rotor plate 41 and glass board rebound, removes to suitable position after, and third motor 423 drives second cylinder 422, rotor plate 41 and glass board and rotates, rotates 90 degrees after, can carry out the operation of sealing glue of different sides to the glass board.

Specifically, the third motor 423 is fixedly arranged at the bottom end of the support frame 1, and the output end of the third motor 423 is connected with the bottom end of the second cylinder 422.

In this embodiment, the fourth driving mechanism 52 includes a plurality of sets of first gears 521 disposed on the front side of the left second setting groove, a first rack ring 522 engaged with the plurality of sets of first gears 521, and a fourth motor 523 disposed in the middle of the right second setting groove, the left end of the plurality of sets of feeding shafts 51 passes through the left end of the support frame 1 and then is connected with the plurality of sets of first gears 521, and the output end of the fourth motor 523 can rotate to pass through the right end of the support frame 1 and then is connected with the rear feeding shaft 51.

In this application, when fourth actuating mechanism 52 operates, fourth motor 523 can drive rear side material loading axle 51 and rotate, and under the linkage action, the first gear 521 of rear side rotates thereupon, and under the transmission action of first rack circle 522, the first gear 521 of multiunit all rotates, and under the linkage action, multiunit material loading axle 51 all rotates to this material loading operation that can realize material loading axle 51 to the glass board.

Specifically, the fourth motor 523 is fixedly disposed on the second setting groove, and the fourth motor 523 is fixedly connected to the second setting groove wall.

In the embodiment of the present application, the fifth driving mechanism 63 includes a plurality of sets of second gears 631 connected to the front ends of the plurality of sets of discharging shafts 62, a second rack ring 632 engaged with the plurality of sets of second gears 631, and a fifth motor 633 connected to the front end of the left second gear 631.

In this application, when the fifth driving mechanism 63 operates, the fifth motor 633 drives the left second gear 631 to rotate, and under the meshing effect of the teeth, the second rack ring 632 rotates accordingly, so that the rotation of the multiple groups of second gears 631 can be realized, the rotation of the blanking shaft 62 can be driven, and the glass plate after being sealed by the sealant can be blanked.

When the glass plate adhesive sealing machine is used, in the adhesive sealing process, firstly, a glass plate is placed on the feeding device 5, when the fourth driving mechanism 52 operates, the fourth motor 523 can drive the rear feeding shaft 51 to rotate, under the connecting action, the rear first gear 521 rotates along with the glass plate, under the transmission action of the first rack ring 522, the multiple groups of first gears 521 rotate, under the connecting action, the multiple groups of feeding shafts 51 rotate, the feeding device 5 transmits the glass plate to the top end of the first transmission device 2, at the moment, the first motor 243 drives the first chain wheel 241 to rotate, under the transmission action of the first chain ring 242, the multiple groups of first chain wheels 241 rotate, under the connecting action, the multiple groups of first transmission shafts 21 rotate along with the first transmission shafts, the multiple groups of first transmission wheels 22 drive the glass plate to move towards the rear side, and after the glass plate adhesive sealing machine moves to a proper position, the rear side of the glass plate adhesive sealing machine is operated, after the rear side glue sealing operation of the glass plate is finished, the second cylinder 422 drives the rotating plate 41 and the glass plate to move upwards, after the rotating plate and the glass plate are moved to a proper position, the third motor 423 drives the second cylinder 422, the rotating plate 41 and the glass plate to rotate, after the rotating plate and the glass plate rotate 90 degrees, the glue sealing surface is changed, at the moment, the glue sealing operation is carried out again, the circulation operation is carried out, glue sealing is carried out on the periphery of the glass plate, after the glue sealing is finished, the plurality of groups of first cylinders 253 drive the two groups of second fixing plates 252 to move downwards respectively, under the connecting action, the two groups of first fixing plates 251 move downwards, under the connecting action, the first conveying device 2 moves downwards, at the moment, the downward movement of the glass plate can be realized, until the bottom end of the glass plate is contacted with the top end of the second conveying device 3, the second motor 334 drives the connecting shaft 333 to rotate, and the two groups of connecting shafts 333 both rotate, the multiple groups of fourth chain wheels 331 can be driven to rotate along with the rotation of the multiple groups of fourth chain wheels 331, the multiple groups of third chain wheels rotate along with the rotation of the multiple groups of third chain wheels 332 under the transmission action of the second chain wheel rings 332, the multiple groups of second transmission shafts 31 rotate along with the rotation of the multiple groups of second transmission wheels 32 under the connection action, the multiple groups of second transmission wheels 32 can transmit the glass plates to the blanking device 6 at the moment, the fifth motor 633 drives the left second gear 631 to rotate, the second chain wheel 632 rotates along with the rotation of the teeth under the meshing action of the teeth, and therefore the rotation of the multiple groups of second gears 631 can be achieved, the blanking shafts 62 can be driven to rotate, and the glass plates after being sealed with glue can be blanked.

It should be noted that references in the specification to "one embodiment," "an example embodiment," "some embodiments," etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is within the knowledge of one skilled in the art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.

It should be readily understood that "on … …", "above … …" and "above … …" in this disclosure should be interpreted in its broadest sense such that "on … …" means not only "directly on something", but also includes the meaning of "on something" with intervening features or layers therebetween, and "above … …" or "above … …" includes not only the meaning of "above something" or "above" but also includes the meaning of "above something" or "above" with no intervening features or layers therebetween (i.e., directly on something).

Furthermore, spatially relative terms, such as "below," "lower," "above," "upper," and the like, may be used herein for ease of description to describe one element or feature's illustrated relationship to another element or feature. Spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. The device may have other orientations (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly as well.

It is noted that, in this document, relational terms such as "first" and "second," and the like, may be 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. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a cavity glass seals and glues production line which characterized in that includes:

the device comprises a support frame (1), wherein a first setting groove is formed in the rear side of the top end of the support frame (1), second setting grooves are formed in the left side and the right side of the top end of the support frame (1), and long holes are formed in the rear sides of the left end and the right end of the support frame (1);

the first transmission device (2) is movably arranged in the first setting groove, the first transmission device (2) comprises a plurality of groups of first transmission shafts (21) which can be arranged in the first setting groove in a vertically moving mode, a plurality of groups of first transmission wheels (22) which are fixedly sleeved on the outer side wall of the plurality of groups of first transmission shafts (21), two groups of moving frames (23) which are arranged in two groups of second setting grooves, a first driving mechanism (24) connected with the input ends of the plurality of groups of first transmission shafts (21) and a lifting mechanism (25) connected with the two groups of moving frames (23), and the left end and the right end of the plurality of groups of first transmission shafts (21) are respectively connected with the two groups of moving frames (23) in a rotating mode after penetrating through the two groups of long holes;

the second transmission device (3) and the first transmission device (2) are arranged in the first setting groove in a crossed mode, and the second transmission device (3) comprises a plurality of groups of second transmission shafts (31) which are rotatably arranged in the first setting groove, second transmission wheels (32) which are fixedly sleeved on the outer side walls of the plurality of groups of second transmission shafts (31) and second driving mechanisms (33) connected with the plurality of groups of second transmission shafts (31);

the rotating device (4) comprises a rotating plate (41) arranged on the upper sides of the plurality of groups of first transmission shafts (21) and second transmission shafts (31) and a third driving mechanism (42) connected with the bottom end of the rotating plate (41);

the feeding device (5) is arranged on the support frame (1), a third setting groove is formed in the front end of the support frame (1), and the feeding device (5) can be rotatably arranged in the third setting groove; and

and the blanking device (6) is arranged on the rear side of the right end of the support frame (1).

2. The hollow glass sealing production line according to claim 1, wherein the feeding device (5) comprises a plurality of sets of feeding shafts (51) rotatably disposed in the third setting groove and a fourth driving mechanism (52) connected to input ends of the plurality of sets of feeding shafts (51).

3. The hollow glass sealing production line according to claim 2, wherein the blanking device (6) comprises a blanking frame (61) fixedly arranged at the rear side of the right end of the support frame (1), a plurality of groups of blanking shafts (62) rotatably connected with the blanking frame (61), and a fifth driving mechanism (63) connected with the input ends of the groups of blanking shafts (62).

4. The hollow glass sealing line according to claim 3, further comprising a reinforcing mechanism fixedly disposed on the side wall of the rotating plate (41), wherein the reinforcing mechanism comprises a plurality of sets of reinforcing frames (7), and the plurality of sets of reinforcing frames (7) are respectively fixedly disposed on the side walls of the plurality of sets of rotating plates (41).

5. The hollow glass sealing production line according to claim 4, wherein the first driving mechanism (24) comprises a first chain wheel (241) disposed on the left side of the left moving frame (23), a plurality of first chain rings (242) engaged with the outer side walls of the first chain wheels (241), and a first motor (243) disposed on the right side of the right moving frame (23), the left ends of the plurality of first transmission shafts (21) are rotatably connected with the plurality of first chain wheels (241) after passing through the left moving frame (23), and the right ends of the rear first transmission shafts (21) are rotatably connected with the output end of the first motor (243) after passing through the right moving frame (23).

6. The hollow glass sealing compound production line according to claims 1-5, wherein the lifting mechanism (25) comprises a first fixing plate (251) fixedly disposed at the middle of the two sets of moving frames (23), a second fixing plate (252) connected to the two sets of first fixing plates (251), and a first cylinder (253) fixedly disposed at the bottom end of the two sets of second fixing plates (252).

7. The hollow glass sealing production line according to claim 6, wherein the second driving mechanism (33) comprises a third sprocket fixedly sleeved at the middle of the outer side wall of the plurality of groups of second transmission shafts (31), a fourth sprocket (331) rotatably disposed at the lower side of the plurality of groups of third sprockets, a second chain ring (332) in transmission connection with the third sprocket and the fourth sprocket (331), two groups of connecting shafts (333) connecting the left plurality of groups of fourth sprockets (331) and the right plurality of groups of fourth sprockets (331), and a second motor (334) connected with the rear ends of the two groups of connecting shafts (333).

8. The hollow glass sealing production line according to claim 7, wherein the third driving mechanism (42) includes a rotating shaft (421) fixedly disposed at the bottom end of the rotating plate (41), a second cylinder (422) fixedly disposed at the bottom end of the rotating shaft (421), and a third motor (423) fixedly disposed at the bottom end of the second cylinder (422).

9. The hollow glass sealing production line according to claim 8, wherein the fourth driving mechanism (52) comprises a plurality of sets of first gears (521) arranged at the front side of the left second arrangement groove, a first rack ring (522) meshed with the plurality of sets of first gears (521), and a fourth motor (523) arranged at the middle part of the right second arrangement groove, the left ends of the plurality of sets of feeding shafts (51) penetrate through the left end of the support frame (1) and then are connected with the plurality of sets of first gears (521), and the output end of the fourth motor (523) can rotate to penetrate through the right end of the support frame (1) and is connected with the feeding shaft (51) at the rear side.

10. The hollow glass sealing line according to claims 1-9, characterized in that the fifth driving mechanism (63) comprises a plurality of sets of second gears (631) connected with the front ends of the plurality of sets of discharging shafts (62), a second rack ring (632) engaged with the plurality of sets of second gears (631), and a fifth motor (633) connected with the front end of the left second gear (631).

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