CN220986288U - Glass converging device and glass production line - Google Patents

Abstract

The utility model belongs to the field of glass production, and particularly relates to a glass converging device and a glass production line. The glass converging device is used for converging and transmitting glass plates on the second processing line to the first processing line and comprises a transmission mechanism, a lifting mechanism, a traveling mechanism, a monitoring mechanism and a supporting mechanism, wherein the lifting mechanism is movably connected to the traveling mechanism, the supporting mechanism is movably connected to the lifting mechanism, the supporting mechanism is used for supporting the glass plates on the transmission mechanism, the monitoring mechanism is used for monitoring the positions of the glass plates on the first processing line, the traveling mechanism is used for driving the lifting mechanism to move to the conveying surface of the first processing line by the transmission mechanism, and the lifting mechanism is used for driving the supporting mechanism to move up and down along the conveying surface vertical to the first processing line so that the glass plates of the supporting mechanism fall on the conveying surface of the first processing line. The utility model can solve the problem of how to improve the efficiency of conveying the glass plate from the first processing line to the next process.

Description

Glass converging device and glass production line

Technical Field

The utility model belongs to the field of glass production, and particularly relates to a glass converging device and a glass production line.

Background

The glass production and processing generally requires a plurality of procedures such as cutting, edging, coating, tempering and the like, and the procedures are transmitted through a roller way and the like. The glass processing transmission line is used for carrying out preamble processing and transmission on glass, and then conveying the glass to a tempering furnace for tempering. In order to ensure the production efficiency, a plurality of glass processing lines are usually arranged to process glass simultaneously and convey the glass to the next process before entering the next process. However, if each working section in the processing line fails or equipment of each working section is overhauled, the transmission speed of the whole processing line is greatly slowed down, so that the transmission of the processing line is in a non-full load state, and the production efficiency is seriously affected.

Disclosure of utility model

The embodiment of the application aims to provide a glass converging device, which aims to solve the problem of how to improve the efficiency of conveying glass plates from a first processing line to the next process so as to ensure the production efficiency of glass.

In order to achieve the above purpose, the application adopts the following technical scheme:

In a first aspect, a glass confluence device is provided for confluence and transmission of glass plates on a second processing line to a first processing line, the glass confluence device comprises a transmission mechanism, a lifting mechanism, a traveling mechanism, a monitoring mechanism and a bearing mechanism, the transmission mechanism is respectively in butt joint with the second processing line and the first processing line, the lifting mechanism is movably connected to the traveling mechanism, the bearing mechanism is movably connected to the lifting mechanism, the bearing mechanism is used for supporting the glass plates on the transmission mechanism, the detection mechanism is used for monitoring the positions of the glass plates on the first processing line, the traveling mechanism is used for driving the lifting mechanism to move from the transmission mechanism to the conveying surface of the first processing line, and the lifting mechanism is used for driving the bearing mechanism to move up and down along the conveying surface vertical to the first processing line so that the glass plates of the bearing mechanism fall on the conveying surface of the first processing line.

In some embodiments, the glass sheets on the transport mechanism are transported in a first direction, and the glass sheets on the first and second processing lines are transported in a second direction, the first and second directions being perpendicular.

In some embodiments, the support mechanism includes a plurality of support arms spaced apart along the second direction, a plurality of support arms each extending along the first direction, the first processing line includes a plurality of transfer rollers spaced apart along the second direction, and the support arms pass through gaps between two adjacent transfer rollers when the support mechanism moves up and down along a transport plane perpendicular to the first processing line.

In some embodiments, the supporting mechanism further includes a connecting arm extending along the second direction, the connecting arm is connected to the lifting mechanism in a manner of moving up and down, one end of the supporting arm is connected to the connecting arm, and the other end of the supporting arm extends towards a direction close to the first processing line.

In some embodiments, the supporting mechanism has a first position below the conveying mechanism and a second position above the conveying mechanism, the lifting mechanism is further used for driving the supporting mechanism to move from the first position to the second position so that the supporting mechanism lifts the glass plate on the conveying mechanism, the conveying mechanism comprises a plurality of conveying devices which are arranged at intervals in the second direction, and when the supporting mechanism moves from the first position to the second position, the supporting arm passes through a gap between two adjacent conveying devices.

In some embodiments, the glass confluence device further comprises a longitudinal beam arranged below the transmission mechanism and extending along the first direction, the walking structure is movably mounted on the longitudinal beam, the walking mechanism comprises a mounting plate, a driving assembly, a first sliding block and a first guide rail, the mounting plate is arranged on the longitudinal beam, the driving assembly is arranged on the mounting plate, the driving assembly is used for driving the mounting plate to move along the extending direction of the longitudinal beam, the first guide rail extends along the first direction, the first sliding block is fixed at the bottom of the mounting plate, and the first sliding block is in sliding connection with the first guide rail.

In some embodiments, the driving assembly comprises a rotation driving gear, a rotation power piece and a rack, wherein the rotation driving gear is arranged on the surface of the mounting plate facing the longitudinal beam, the rotation power piece is fixed on the top surface of the mounting plate, the rotation driving gear is connected with a rotation output end of the rotation power piece, the rotation power piece drives the rotation driving gear to rotate, a rotation axis of the rotation driving gear is perpendicular to a horizontal plane, the rack is fixed on one side of the longitudinal beam, the rack extends along the first direction, and the rotation driving gear is meshed with the rack.

In some embodiments, the lifting mechanism comprises a lifting seat, a lifting power piece, a connecting plate, a second sliding block and a second guide rail, wherein the lifting seat is fixed on the mounting plate, the bearing structure is mounted on the mounting plate, the connecting plate is connected with the output end of the lifting power piece, the lifting power piece is used for driving the connecting plate to move along the vertical horizontal direction, the second guide rail is mounted on the lifting seat, the second guide rail extends along the vertical direction, the second sliding block is fixed on the connecting plate, and the second guide rail is in sliding connection with the second sliding block.

In some embodiments, the glass confluence device further comprises a first frame body and a second frame body, wherein the first frame body and the second frame body are located at different heights and are connected with each other, the second frame body is located above the first frame body, the longitudinal beam is arranged on the first frame body, the first frame body comprises two opposite cross beams, two ends of the longitudinal beam are respectively connected with two cross beams, and the second frame body is used for installing the transmission mechanism.

In a second aspect, a glass production line is provided, which comprises the glass confluence device of the scheme, and the glass production line further comprises a first processing line and at least one second processing line, wherein the glass confluence device is used for confluently transmitting glass plates on the two processing lines to the first processing line.

The application has the beneficial effects that: according to the application, the lifting mechanism is driven by the travelling mechanism to drive the glass plates to move to the conveying surface of the first processing line and wait, when the monitoring mechanism monitors that a larger interval exists between the front glass plate and the rear glass plate on the first processing line, the lifting mechanism starts to drive the glass plates to move downwards along the conveying surface vertical to the first processing line so as to drop the glass plates on the conveying surface of the first processing line and fall in the interval between the front glass plate and the rear glass plate, thereby completing the aggregation of the glass plates of the second processing line on the first processing line and outputting the glass plates to the next process, effectively ensuring the full-load transmission of the glass plates on the first processing line, obviously improving the efficiency of conveying the glass plates from the first processing line to the next process, and guaranteeing the production efficiency of glass.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments or exemplary technical descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained according to these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a schematic view of a glass manifold and a first processing line according to an embodiment of the present application;

FIG. 2 is a schematic view of a glass bus device according to an embodiment of the present application;

FIG. 3 is a schematic view of a part of a glass bus device according to an embodiment of the present application;

Fig. 4 is a schematic structural diagram of a lifting mechanism according to an embodiment of the present application.

Wherein, each reference sign in the figure:

10. A transmission mechanism; 11. a transfer device; 20. a walking mechanism; 21. a rotary power member; 22. a rotary gear; 23. a rack; 24. a mounting plate; 25. a first slider; 26. a first guide rail; 27. a drag chain; 30. a lifting mechanism; 31. lifting the power piece; 32. a connecting plate; 33. a second slider; 34. a second guide rail; 35. a lifting seat; 40. a bearing knot hook; 41. a connecting arm; 42. a support arm; 51. a first frame; 52. a second frame; 53. a protection plate; 54. a longitudinal beam; 60. an air source assembly; 70. a junction box assembly; 200. a first processing line; 210. and a conveying roller.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model. Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present utility model, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

Referring to fig. 1 to 4, an embodiment of the present application provides a glass collecting device for collecting and transferring glass sheets on a second processing line to a first processing line 200. The glass confluence device comprises a transmission mechanism 10, a lifting mechanism 30, a traveling mechanism 20, a monitoring mechanism and a bearing mechanism, wherein the transmission mechanism 10 is respectively connected with a conveying section of a second processing line and a conveying section of a first processing line 200 in a butt joint mode, the lifting mechanism 30 is movably connected to the traveling mechanism 20, the bearing mechanism is movably connected to the lifting mechanism 30, the bearing mechanism is used for supporting glass plates on the transmission mechanism 10, the monitoring mechanism is used for monitoring the positions of the glass plates on the first processing line 200, the traveling mechanism 20 is used for driving the lifting mechanism 30 to move from the transmission mechanism 10 to the conveying surface of the first processing line 200, and the lifting mechanism 30 is used for driving the bearing mechanism to move up and down along the conveying surface vertical to the first processing line 200 so that the glass plates of the bearing mechanism fall on the conveying surface of the first processing line 200.

It should be noted that the second processing line may be provided with a plurality of processing lines, and the first processing line 200 and the second processing line are each used for processing glass. The first processing line 200 may be configured as a main processing line, an output end of which is used to be connected to a next process of glass production, such as a tempering process, etc., and the second processing line may be configured as a sub-processing line, an output end of at least one sub-processing line being connected to an output end of the main processing line so that glass of the sub-processing line is gathered at the main processing line to be output to the next process. According to the application, the traveling mechanism 20 drives the lifting mechanism 30 to drive the glass plates to move from the conveying mechanism 10 to the conveying surface of the first processing line 200 and wait, when the monitoring mechanism monitors that a larger interval exists between the front glass plate and the rear glass plate on the first processing line 200, the lifting mechanism 30 starts to drive the glass plates to move downwards along the conveying surface vertical to the first processing line 200 so as to drop the glass plates on the conveying surface of the first processing line 200 and fall into the interval between the front glass plate and the rear glass plate, thereby completing the collection of the glass plates of the second processing line on the first processing line 200 and outputting the glass plates to the next process, effectively ensuring the full-load conveying of the glass plates on the first processing line 200, obviously improving the efficiency of conveying the glass plates to the next process by the first processing line 200, and guaranteeing the production efficiency of glass.

In the present application, as shown in fig. 1, the glass sheet on the transfer mechanism 10 is transferred in the first direction a, and the glass sheets on the first processing line 200 and the second processing line are transferred in the second direction b, that is, the first processing line 200 and the second processing line are parallel and spaced apart, and the transfer mechanism 10 is disposed between the first processing line 200 and the second processing line. The plurality of second processing lines may be located on the same side of the first processing line 200, or may be located on two sides of the first processing line 200, which is not limited in the present application. In the present application, the monitoring mechanism is electrically connected to the elevating mechanism 30 and the traveling mechanism 20, and the monitoring mechanism may be a photoelectric sensor or the like.

Preferably, as shown in fig. 2 and 3, the supporting mechanism includes a plurality of supporting arms 42 spaced apart along the second direction b, each of the plurality of supporting arms 42 extends along the first direction a, and the first processing line 200 includes a plurality of conveying rollers 210 spaced apart along the second direction, and when the lifting mechanism 30 moves up and down along the conveying surface perpendicular to the first processing line 200, the supporting arms 42 pass through the gap between two adjacent conveying rollers 210. When the travelling mechanism 20 drives the lifting mechanism 30 to move to the conveying surface position of the first processing line 200, the plurality of supporting arms 42 are located right above the conveying surface of the first processing line 200, then the lifting mechanism 30 drives the supporting mechanism to move downwards along the conveying surface of the first processing line 200, the plurality of supporting arms 42 can pass through the gap between two adjacent conveying rollers 210 of the conveying section of the first processing line 200 and stay in the gap between two adjacent conveying rollers 210, and when the glass plate of the supporting mechanism falls on the conveying surface of the first processing line 200, the travelling mechanism 20 drives the supporting mechanism to retract along the first direction without interference.

In this embodiment, the supporting mechanism further includes a connecting arm 41 extending along the second direction b, the connecting arm 41 is connected to the lifting mechanism 30 in a manner of being able to move up and down, one end of the supporting arm 42 is connected to the connecting arm 41, and the other end of the supporting arm 42 extends toward a direction approaching the first processing line 200. The fixing of the plurality of support arms 42 can be realized through the connecting arms 41, the consistency and stability of the movement of the plurality of support arms 42 are ensured, and the plurality of support arms 42 support the glass plate together, so that the support of the glass plate is more stable, and the damage to the glass plate is avoided. In addition, the top surface of the supporting arm 42 is also provided with a gasket, and the gasket can be made of sponge or rubber, and the like, so that when the supporting arm 42 jacks up the glass plate upwards, a certain buffering effect can be achieved, and the glass plate is prevented from being damaged.

In this embodiment, the support mechanism has a first position below the conveyor 10 and a second position above the conveyor 10, and the lift mechanism 30 is further configured to drive the support mechanism from the first position to the second position to lift the glass sheet on the conveyor 10 and separate the glass sheet from the conveying surface of the conveyor 10 for better transfer of the glass sheet. Specifically, the conveying mechanism 10 includes a plurality of conveying devices 11 arranged at intervals along the second direction b, and when the supporting mechanism moves from the first position to the second position, the supporting arm 42 passes through the gap between two adjacent conveying devices 11, so that the supporting arm is not interfered. In fact, the plurality of conveying devices 11 of the conveying mechanism 10 may be disposed to correspond to the plurality of conveying rollers 210 of the first processing line 200, that is, the gap between two adjacent conveying devices 11 of the conveying mechanism 10 and the gap between two adjacent conveying rollers 210 of the first processing line 200 are opposite to and communicate with each other, so that when the supporting mechanism drops the glass sheet smoothly onto the conveying surface of the first processing line 200 and retreats in the first direction a, the supporting mechanism can be retreated smoothly to the first position without interference. Alternatively, the conveyor 11 of the present application is a belt conveyor 11 to make the conveyance of the glass sheet smoother.

Further, the glass confluence device further comprises a longitudinal beam 54 arranged below the transmission mechanism 10 and extending along a first direction a, the traveling structure is movably mounted on the longitudinal beam 54, the traveling mechanism 20 comprises a mounting plate 24, a driving assembly, a first sliding block 25 and a first guide rail 26, the mounting plate 24 is arranged on the longitudinal beam 54, the driving assembly is arranged on the mounting plate 24, the driving assembly is used for driving the mounting plate 24 to move along the extending direction of the longitudinal beam 54, the first guide rail 26 extends along the first direction a, the first sliding block 25 is fixed at the bottom of the mounting plate 24, and the first sliding block 25 is in sliding connection with the first guide rail 26. Optionally, the number of the first guide rails 26 is two, and the number of the first sliding blocks 25 is correspondingly two, so that the first sliding blocks 25 on two sides of the mounting plate 24 are respectively in sliding connection with the two first guide rails 26, and the movement of the mounting plate 24 is smoother. The positions of the two first guide rails 26 can be symmetrical relative to the central axis of the mounting plate 24, so that the moving stability of the mounting plate 24 is further improved, and the mounting plate 24 is prevented from tilting to one side in the moving process.

Specifically, the glass bus device of the present application includes a first frame 51 and a second frame 52 that are located at different heights and are connected to each other, the second frame 52 is located above the first frame 51, a longitudinal beam 54 is disposed on the first frame 51, the first frame 51 includes two opposite cross beams, two ends of the longitudinal beam 54 are respectively connected to the two cross beams, and the second frame 52 is used for installing the transmission mechanism 10. The protection plates 53 are also installed on two sides of the second frame 52, so as to play a role in protection. A drag chain 27 is also connected between the mounting plate 24 and the first frame 51, and the drag chain 27 can pull and protect the built-in cable, oil pipe, air pipe, and the like. The first frame 51 is further fixed with an air source assembly 60 and a junction box assembly 70, the air source assembly 60 is used for providing an air source, and the junction box assembly 70 is used for connecting wires and protecting wires.

In some embodiments, as shown in fig. 3, the driving assembly includes a rotation driving gear, a rotation driving member 21 and a rack 23, the rotation driving gear is disposed on a plate surface of the mounting plate 24 facing the longitudinal beam 54, the rotation driving member 21 is fixed on a top surface of the mounting plate 24, the rotation driving gear is connected to a rotation output end of the rotation driving member 21, the rotation driving gear is driven to rotate by the rotation driving member 21, a rotation axis of the rotation driving gear is perpendicular to a horizontal plane, the rack 23 is fixed on one side of the longitudinal beam 54, the rack 23 extends along the first direction a, and the rotation driving gear is meshed with the rack 23, so that when the rotation driving gear rotates, the rack 23 can drive the rotation driving gear and the mounting plate 24 to make a linear motion. In the present application, the rotary power member 21 may be a rotary motor, a rotary cylinder, or the like.

In some embodiments, as shown in fig. 4, the lifting mechanism 30 includes a lifting seat 35, a lifting power member 31, a connecting plate 32, a second slider 33, and a second guide rail 34, where the lifting seat 35 is fixed on the mounting plate 24, the bearing structure is mounted on the connecting plate 32, the connecting plate 32 is connected to an output end of the lifting power member 31, the lifting power member 31 is used for driving the mounting plate 24 to move along a vertical horizontal direction, the second guide rail 34 is mounted on the lifting seat 35, the second guide rail 34 extends along a vertical direction, the second slider 33 is fixed on the connecting plate 32, and the second guide rail 34 is slidably connected with the second slider 33.

Optionally, the number of the second guide rails 34 is two, the number of the second sliding blocks 33 is correspondingly two, and the second sliding blocks 33 on two sides of the connecting plate 32 are respectively in sliding connection with the two second guide rails 34, so that the movement of the connecting plate 32 is smoother. The positions of the two second guide rails 34 can be symmetrical relative to the central axis of the lifting seat 35, so that the moving stability of the connecting plate 32 is further improved, and the connecting plate 32 is prevented from tilting to one side in the moving process. In the present application, the lifting power member 31 may be a lifting cylinder, a lifting motor, or the like.

In the actual use process of the glass confluence device, the conveying mechanism 10 receives the glass plates conveyed by the second processing line, at this time, the supporting mechanism is located at a first position, then the lifting mechanism 30 drives the supporting mechanism to move from the first position to a second position, so that the supporting mechanism lifts the glass plates on the conveying mechanism 10 to separate the glass plates from the conveying surface of the conveying mechanism 10, then the travelling mechanism 20 drives the lifting mechanism 30 and the supporting mechanism to move to the conveying surface position of the first processing line 200 together, at this time, the supporting mechanism 30 is located above the conveying surface of the first processing line 200 and waits for a proper time, when a gap is detected, the lifting mechanism 30 drives the supporting mechanism to move downwards along the conveying surface of the first processing line 200, a plurality of supporting arms 42 penetrate through gaps between two adjacent conveying rollers 210 of the conveying section of the first processing line 200 and stay in the gaps between the two adjacent conveying rollers 210, at this time, the glass plates of the supporting mechanism fall on the conveying surface of the first processing line 200, the transfer of the glass plates is completed, and then the travelling mechanism 20 drives the supporting mechanism to withdraw the supporting mechanism to move the next glass plate along the first direction a, so that the transfer of the glass plates is circulated.

The utility model also provides a glass production line, which comprises a glass converging device, and the specific structure of the glass converging device refers to the embodiment, and because the glass production line adopts all the technical schemes of all the embodiments, the glass production line also has all the beneficial effects brought by the technical schemes of the embodiments, and the detailed description is omitted.

The glass production line further includes a first processing line 200 and at least one second processing line, and a glass manifold device is used to manifold the glass sheets on the two processing lines onto the first processing line 200.

In summary, the traveling mechanism 20 drives the lifting mechanism 30 to drive the glass plates to move from the conveying mechanism 10 to the conveying surface of the first processing line 200 and wait, when the monitoring mechanism monitors that a large interval exists between the front glass plate and the rear glass plate on the first processing line 200, the lifting mechanism 30 starts to drive the glass plates to move downwards along the conveying surface vertical to the first processing line 200 so as to drop the glass plates on the conveying surface of the first processing line 200 and fall into the interval between the front glass plate and the rear glass plate, thereby completing the collection of the glass plates of the second processing line on the first processing line 200 and outputting the glass plates to the next process, effectively ensuring the full-load conveying of the glass plates on the first processing line 200, obviously improving the efficiency of conveying the glass plates to the next process by the first processing line 200, and guaranteeing the production efficiency of the glass.

The foregoing is merely an alternative embodiment of the present application and is not intended to limit the present application. Various modifications and variations of the present application will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. The utility model provides a glass converging device for with the glass board on the second processing line converging the transmission to first processing line (200), its characterized in that, glass converging device includes transport mechanism (10), elevating system (30), running gear (20), monitoring mechanism and supporting mechanism, transport mechanism (10) respectively with second processing line with first processing line (200) dock, elevating system (30) movably connect in on running gear (20), supporting mechanism movably connect in elevating system (30), supporting mechanism is used for supporting glass board on transport mechanism (10), monitoring mechanism is used for monitoring the position of glass board on first processing line (200), running gear (20) are used for driving elevating system (30) are by transport mechanism (10) remove to the transport face of first processing line (200), elevating system (30) are used for driving supporting mechanism along perpendicular on the transport face of first processing line (200) remove, so that glass board falls on the transport face of first processing line (200).

2. The glass manifold device according to claim 1, wherein: the glass sheets on the conveying mechanism (10) are conveyed along a first direction, and the glass sheets on the first processing line (200) and the second processing line are conveyed along a second direction, wherein the first direction and the second direction are perpendicular.

3. The glass manifold device according to claim 2, wherein: the bearing mechanism comprises a plurality of bearing arms (42) which are arranged at intervals along the second direction, the bearing arms (42) extend along the first direction, the first processing line (200) comprises a plurality of transmission rollers (210) which are arranged at intervals along the second direction, and when the bearing mechanism moves up and down along the conveying surface vertical to the first processing line (200), the bearing arms (42) penetrate through gaps between two adjacent transmission rollers (210).

4. The glass manifold device as claimed in claim 3, wherein: the bearing mechanism further comprises a connecting arm (41) extending along the second direction, the connecting arm (41) is connected to the lifting mechanism (30) in a vertically movable mode, one end of the bearing arm (42) is connected to the connecting arm (41), and the other end of the bearing arm (42) extends towards the direction close to the first processing line (200).

5. The glass manifold device as claimed in claim 3, wherein: the bearing mechanism is provided with a first position located below the transmission mechanism (10) and a second position located above the transmission mechanism (10), the lifting mechanism (30) is further used for driving the bearing mechanism to move from the first position to the second position, so that the bearing mechanism lifts the glass plate on the transmission mechanism (10), the transmission mechanism (10) comprises a plurality of conveying devices (11) which are distributed at intervals in the second direction, and when the bearing mechanism moves from the first position to the second position, the bearing arm (42) penetrates through the gap between two adjacent conveying devices (11).

6. The glass manifold device according to any one of claims 2 to 5, wherein: the glass confluence device further comprises a longitudinal beam (54) which is arranged below the transmission mechanism (10) and extends along the first direction, the travelling mechanism (20) is movably mounted on the longitudinal beam (54), the travelling mechanism (20) comprises a mounting plate (24), a driving assembly, a first sliding block (25) and a first guide rail (26), the mounting plate (24) is arranged on the longitudinal beam (54), the driving assembly is arranged on the mounting plate (24), the driving assembly is used for driving the mounting plate (24) to move along the extending direction of the longitudinal beam (54), the first guide rail (26) extends along the first direction, the first sliding block (25) is fixed at the bottom of the mounting plate (24), and the first sliding block (25) is in sliding connection with the first guide rail (26).

7. The glass manifold device according to claim 6, wherein: the driving assembly comprises a rotary driving gear, a rotary power piece (21) and a rack (23), wherein the rotary driving gear is arranged on the surface of the mounting plate (24) facing the longitudinal beam (54), the rotary power piece (21) is fixed on the top surface of the mounting plate (24), the rotary driving gear is connected with a rotary output end of the rotary power piece (21), the rotary power piece (21) drives the rotary driving gear to rotate, the rotary axis of the rotary driving gear is perpendicular to the horizontal plane, the rack (23) is fixed on one side of the longitudinal beam (54), the rack (23) extends along the first direction, and the rotary driving gear is meshed with the rack (23).

8. The glass manifold device according to claim 6, wherein: elevating system (30) are including lifting seat (35), lift power spare (31), connecting plate (32), second slider (33) and second guide rail (34), lifting seat (35) are fixed on mounting panel (24), bearing mechanism install in on mounting panel (24), connecting plate (32) with the output of lift power spare (31) is connected, lift power spare (31) are used for the drive connecting plate (32) are followed the vertical horizontal direction and are removed, second guide rail (34) install in lifting seat (35), second guide rail (34) are along vertical direction extension, second slider (33) are fixed in connecting plate (32), second guide rail (34) with second slider (33) sliding connection.

9. The glass manifold device according to claim 6, wherein: the glass confluence device further comprises a first frame body (51) and a second frame body (52) which are located at different heights and are mutually connected, the second frame body (52) is located above the first frame body (51), longitudinal beams (54) are arranged on the first frame body (51), the first frame body (51) comprises two opposite cross beams, two ends of each longitudinal beam (54) are respectively connected with two cross beams, and the second frame body (52) is used for installing the transmission mechanism (10).

10. A glass production line comprising a glass fusion device according to any one of claims 1-9, further comprising a first processing line (200) and at least one second processing line, said glass fusion device being adapted to fusion transfer glass sheets on said two processing lines onto said first processing line (200).