CN211254412U - Online storage mechanism for glass - Google Patents

Abstract

The utility model discloses a glass on-line storage mechanism, which relates to the field of glass deep processing storage equipment, and comprises a first guide pulley module, a second guide pulley module, a third guide pulley module, an outer synchronous belt module, an inner synchronous belt module, a middle synchronous belt module, a glass support frame and a driving motor, wherein the first guide pulley module and the second guide pulley module are arranged side by side, the second guide pulley module is arranged at the lower side of the first guide pulley module and the second guide pulley module, and the outer synchronous belt module, the inner synchronous belt module and the middle synchronous belt module are respectively connected with the first guide pulley module, the second guide pulley module and a plurality of third guide pulley modules; the glass support frame is connected with outer hold-in range module, middle level hold-in range module and inlayer hold-in range module respectively, and driving motor is connected with first leading band pulley module drive, can satisfy glass piece FIFO's requirement.

Description

Online storage mechanism for glass

Technical Field

The utility model relates to glass deep-processing storage equipment field especially involves a glass online storage mechanism.

Background

In recent years, the glass deep processing industry in China has been greatly developed, and new functional glass, such as ultrathin glass, solar power generation glass and the like, is continuously emerged. In the production process, when local faults occur or the production line needs to be debugged in a whole line, a certain amount of glass plates need to be stored on line, particularly in the production line of cadmium telluride thin film solar cell substrate glass, the process requirement on-line storage equipment is higher, the functions of glass online first-in first-out and the like need to be achieved, otherwise, the glass stored firstly is easily polluted by the workshop environment due to the fact that the glass cannot be conveyed out in time, and the power generation function of the glass is further influenced. In the existing glass deep processing connecting line, most of on-line storage devices are realized by glass which is fed in first and then discharged out, and the technological requirements can not be met.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an online storage mechanism of glass for solve above-mentioned technical problem.

The utility model adopts the technical scheme as follows:

an in-line glass storage mechanism comprising:

a first guide belt wheel module;

the first guide belt pulley module and the second guide belt pulley module are transversely arranged side by side, and a gap is arranged between the first guide belt pulley module and the second guide belt pulley module;

the third guide belt pulley modules are transversely arranged at the lower sides of the first guide belt pulley module and the second guide belt pulley module side by side and are arranged at equal intervals;

the outer layer synchronous belt module is connected with the first guide belt pulley module, the second guide belt pulley module and the plurality of third guide belt pulley modules;

the inner-layer synchronous belt module is arranged on the inner side of the outer-layer synchronous belt module and is connected with the first guide belt wheel module, the second guide belt wheel module and the plurality of third guide belt wheel modules;

the middle-layer synchronous belt module is positioned between the outer-layer synchronous belt module and the inner-layer synchronous belt module and is connected with the first guide belt pulley module, the second guide belt pulley module and a plurality of third guide belt pulley modules;

each glass support frame is respectively connected with the outer layer synchronous belt module, the middle layer synchronous belt module and the inner layer synchronous belt module;

and the driving motor is in driving connection with the first guide belt wheel module.

Preferably, the outer layer synchronous belt module comprises two outer layer synchronous belt modules, the two outer layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two outer layer synchronous belt modules;

each of the outer belt modules includes:

the first synchronous belt pulley is arranged on one side, away from the second guide belt pulley module, of the first guide belt pulley module;

the second synchronous belt pulley is arranged on one side, far away from the first guide belt pulley module, of the second guide belt pulley module;

the lower sides of the first synchronous belt wheel and the second synchronous belt wheel are respectively provided with a third synchronous belt wheel, and each third synchronous belt wheel is respectively positioned on the upper sides of a plurality of third guide belt wheel modules;

the outer layer synchronous belt is connected with the first guide belt pulley module, the second guide belt pulley module, the first synchronous belt pulley, the second synchronous belt pulley, the third synchronous belt pulley and the third guide belt pulley module.

Preferably, the inner-layer synchronous belt module comprises two inner-layer synchronous belt modules, the two inner-layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two inner-layer synchronous belt modules;

each of the inner belt modules includes:

two fourth synchronous pulleys, wherein one of the fourth synchronous pulleys is arranged on the lower side of the first guide pulley module, the other fourth synchronous pulley is arranged on the lower side of the second guide pulley module, and each fourth synchronous pulley is respectively positioned on the upper sides of the plurality of third guide pulley modules;

an inlayer hold-in range, the inlayer hold-in range is connected first leading pulley module second leading pulley module, two fourth synchronous pulley and a plurality of third leading pulley module.

Preferably, the middle-layer synchronous belt module comprises two middle-layer synchronous belt modules, the two middle-layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two middle-layer synchronous belt modules;

each of the middle-layer timing belt modules includes:

two fifth synchronous pulleys, wherein one fifth synchronous pulley is arranged between the first guide pulley module and the first synchronous pulley, and the other fifth synchronous pulley is arranged between the second guide pulley module and the second synchronous pulley;

each sixth synchronous belt pulley is positioned at the lower side of one fifth synchronous belt pulley, and each sixth synchronous belt pulley is positioned at the upper sides of the third guide belt pulley modules;

the middle-layer synchronous belt is connected with the first guide belt pulley module, the second guide belt pulley module, the two fifth synchronous belt pulleys, the two sixth synchronous belt pulleys and the plurality of third guide belt pulley modules.

Preferably, one end of each of the two sides of each of the glass support frames is connected to the two outer-layer synchronous belts, the other end of each of the two sides of each of the glass support frames is connected to the two inner-layer synchronous belts, and the middle of each of the two sides of each of the glass support frames is connected to the two middle-layer synchronous belts.

As a further preferred aspect, the first guide pulley module, the second guide pulley module and each of the third guide pulley modules include:

a connecting shaft;

and the two synchronous belt wheels are arranged at two ends of the connecting shaft.

As a further preference, each of the timing pulleys includes:

the synchronous pulley main part, the outer fringe at the middle part of synchronous pulley main part is equipped with first teeth of a cogwheel module, the outer fringe of the one end of synchronous pulley main part is equipped with second teeth of a cogwheel module, the outer fringe of the other end of synchronous pulley main part is equipped with third teeth of a cogwheel module, outer hold-in range with third teeth of a cogwheel module is connected, the inlayer hold-in range with second teeth of a cogwheel module is connected, the middle level hold-in range with first teeth of a cogwheel module is connected.

As a further preferred aspect, the first guide pulley module, the second guide pulley module and each of the third guide pulley modules further include:

and the two guide smooth wheels are arranged at two ends of the connecting shaft and are respectively positioned between the two synchronous belt wheels.

The technical scheme has the following advantages or beneficial effects:

the utility model discloses in, through setting up the glass support frame on outer hold-in range, middle level hold-in range and inlayer hold-in range to drive the glass support frame through outer hold-in range, middle level hold-in range and inlayer hold-in range and carry out the circulation rotation, satisfied glass piece FIFO's requirement.

Drawings

FIG. 1 is a front view of the glass on-line storage mechanism of the present invention;

FIG. 2 is a perspective view of the glass on-line storage mechanism of the present invention;

fig. 3 is a perspective view of the synchronous pulley of the present invention;

fig. 4 is a schematic structural view of the glass support frame of the present invention.

In the figure: 1. a first guide pulley module; 2. a second guide pulley module; 3. a third guide pulley module; 4. a glass support frame; 401. a synchronous belt; 5. a first timing pulley; 6. a second timing pulley; 7. a third synchronous pulley; 8. an outer synchronous belt; 9. a fourth timing pulley; 10. an inner layer synchronous belt; 11. a fifth timing pulley; 12. a sixth timing pulley; 13. a middle-layer synchronous belt; 14. a connecting shaft; 15. a synchronous pulley; 151. a first gear tooth module; 152. a second gear tooth module; 153. a third gear tooth module; 154. a synchronous pulley body; 16. a guide light wheel; 17. a first rotary belt conveyor; 18. a second rotary belt conveyor; 19. a roller conveyor.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific embodiments, but the present invention is not limited thereto.

Fig. 1 is the front view of the glass online storage mechanism of the present invention, fig. 2 is the perspective view of the glass online storage mechanism of the present invention, fig. 3 is the perspective view of the middle synchronous pulley of the present invention, fig. 4 is the schematic structural diagram of the middle glass support frame of the present invention. Referring to fig. 1-4, a preferred embodiment is shown, showing an in-line glass storage mechanism comprising:

a first guide pulley module 1.

A second guiding belt wheel module 2, first guiding belt wheel module 1 and second guiding belt wheel module 2 transversely set up side by side, and are equipped with the interval between first guiding belt wheel module 1 and the second guiding belt wheel module 2.

A plurality of third leading pulley module 3, a plurality of third leading pulley module 3 transversely set up side by side at the downside of first leading pulley module 1 and second leading pulley module 2, and a plurality of third leading pulley module 3 equidistant setting.

An outer layer hold-in range module, first leading pulley module 1, second leading pulley module 2 and a plurality of third leading pulley module 3 are connected to outer layer hold-in range module.

An inlayer hold-in range module, inlayer hold-in range module set up the inboard at outer hold-in range module, and inlayer hold-in range module connects first leading pulley module 1, second leading pulley module 2 and a plurality of third leading pulley module 3.

A middle-level hold-in range module, middle-level hold-in range module are located between outer hold-in range module and the inlayer hold-in range module, and first leading pulley module 1, second leading pulley module 2 and a plurality of third leading pulley module 3 are connected to middle-level hold-in range module.

A plurality of glass support frames 4, each glass support frame 4 is connected with outer layer hold-in range module, middle level hold-in range module and inlayer hold-in range module respectively.

And a driving motor (not shown in the figure) which is in driving connection with the first guide pulley module 1. The first guide pulley module 1, the second guide pulley module 2 and the plurality of third guide pulley modules 3 in this embodiment are an integrated mechanism. When using, the glass piece enters into glass support frame 4 by the left side of the direction that figure 1 shows, the first leading pulley module of driving motor drive 1 rotates, first leading pulley module 1 can drive outer hold-in range module, inlayer hold-in range module and middle level hold-in range module synchronous operation, outer hold-in range module, inlayer hold-in range module and middle level hold-in range module drive 4 circulation operations of glass support frame, make the glass piece enter into in the glass piece online storage mechanism, when needs release glass piece, outer hold-in range module, inlayer hold-in range module and middle level hold-in range module can drive the glass piece and leave glass piece online storage mechanism by the right side of the direction that figure 1 shows. In this embodiment, the device further includes a supporting frame (not shown), wherein the first guide pulley module 1, the second guide pulley module 2, the third guide pulley module 3, the outer layer synchronous belt module, the inner layer synchronous belt module and the middle layer synchronous belt module are all mounted on the supporting frame. As shown in fig. 2, the outer layer synchronous belt module is sleeved outside the inner layer synchronous belt module, and the middle layer synchronous belt module is sleeved between the outer layer synchronous belt module and the inner layer synchronous belt module. In the present embodiment, four third leading pulley modules 3 are provided, wherein, as shown in fig. 1, two third leading pulley modules 3 located on the left side and the right side are located on the same horizontal plane, two third leading pulley modules 3 located in the middle position are located on the same horizontal plane, and the horizontal plane where the two third leading pulley modules 3 located in the middle position are located is lower than the horizontal plane where the two third leading pulley modules 3 located on the left side and the right side are located.

Further, as a preferred implementation mode, the outer layer synchronous belt module comprises two outer layer synchronous belt modules, the two outer layer synchronous belt modules are arranged in parallel, and an interval is arranged between the two outer layer synchronous belt modules.

Each outer belt module comprises:

a first synchronous belt pulley 5, the first synchronous belt pulley 5 is arranged on one side of the first guide belt pulley module 4 far away from the second guide belt pulley module 5.

And a second synchronous belt pulley 6, wherein the second synchronous belt pulley 6 is arranged on one side 1 of the second guide belt pulley module 2 far away from the first guide belt pulley module.

Two third synchronous pulleys 7, a third synchronous pulley 7 is respectively arranged on the lower side of the first synchronous pulley 5 and the lower side of the second synchronous pulley 6, and each third synchronous pulley 7 is respectively positioned on the upper sides of the plurality of third guide pulley modules 3.

An outer synchronous belt 8, outer synchronous belt 8 connect first leading pulley module 1, second leading pulley module 2, two first synchronous pulleys 5, second synchronous pulley 6, two third synchronous pulleys 7 and a plurality of third leading pulley module 3. As shown in fig. 1, the first synchronous pulley 5 is disposed on the left side of the first guide pulley module 1, the second synchronous pulley 6 is disposed on the right side of the second guide pulley module 2, the first synchronous pulley 5, the second synchronous pulley 6, the first guide pulley module 1 and the second guide pulley module 2 are on the same horizontal plane, the two third synchronous pulleys 7 are on the same horizontal plane, the third synchronous pulleys 7 are disposed on the lower sides of the first synchronous pulley 5 and the second synchronous pulley 6, and the clear distance between the two third synchronous pulleys 7 is greater than the clear distance between the first synchronous pulley 5 and the second synchronous pulley 6. During the use, first leading pulley module 1 drives outer hold-in range 8 operation, and outer hold-in range 8 drives first synchronous pulley 5, second synchronous pulley 6, third synchronous pulley 7, second leading pulley module 2 and the operation synchronous operation of third leading pulley module 3.

Further, as a preferred embodiment, the inner layer synchronous belt module comprises two inner layer synchronous belt modules, the two inner layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two inner layer synchronous belt modules;

each inner belt module comprises:

two fourth synchronous pulleys 9, wherein a fourth synchronous pulley 9 sets up the downside at first leading pulley module 1, and another fourth synchronous pulley 9 sets up the downside at second leading pulley module 2, and each fourth synchronous pulley 9 is located the upside of a plurality of third leading pulley modules 3 respectively.

An inlayer hold-in range 10, inlayer hold-in range 10 connect first leading pulley module 1, second leading pulley module 2, two fourth synchronous pulley 9 and a plurality of third leading pulley module 3. As shown in fig. 1, the two fourth synchronous pulleys 9 and the two third synchronous pulleys 7 are all located on the same horizontal plane, and the clear distance between the two fourth synchronous pulleys 9 is greater than the clear distance between the first guide pulley module 1 and the second guide pulley module 2. In this embodiment, the first guide pulley module 1 drives the inner layer synchronous belt 10 to run, and then the inner layer synchronous belt 10 drives the two fourth synchronous pulleys 9 and the plurality of third guide pulley modules 3 of the second guide pulley module 2 to run synchronously.

Further, as a preferred embodiment, the middle layer synchronous belt module comprises two middle layer synchronous belt modules, the two middle layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two middle layer synchronous belt modules.

Each middle-layer synchronous belt module comprises:

and two fifth synchronous pulleys 11, wherein one fifth synchronous pulley 11 is arranged between the first guide pulley module 1 and the first synchronous pulley 5, and the other fifth synchronous pulley 11 is arranged between the second guide pulley module 2 and the second synchronous pulley 6.

Two sixth synchronous belt wheels 12, wherein each sixth synchronous belt wheel 12 is respectively positioned at the lower side of a fifth synchronous belt wheel 11, and each sixth synchronous belt wheel 12 is respectively positioned at the upper side of a plurality of third guide belt wheel modules 3;

a middle-layer synchronous belt 13, the middle-layer synchronous belt 13 connects the first guide pulley module 1, the second guide pulley module 2, the two fifth synchronous pulleys 11, the two sixth synchronous pulleys 12 and the plurality of third guide pulley modules 3. As shown in fig. 1, the fifth synchronous pulleys 11, the first guide pulley module 1, the second guide pulley module 2, the first synchronous pulley 5 and the second synchronous pulley 6 are all located on the same horizontal plane, and the sixth synchronous pulleys 12, the third synchronous pulleys 7 and the fourth synchronous pulleys 9 are all located on the same horizontal plane. As shown in fig. 1, the sixth timing pulley 12 on the left side is disposed between the third timing pulley 7 and the fourth timing pulley 9 on the left side. The sixth timing pulley 12 on the right side is disposed between the third timing pulley 7 and the fourth timing pulley 9 on the right side. The clear distance between the sixth timing pulleys 12 in this embodiment is greater than the clear distance between the fifth timing pulleys 11. In this embodiment, the outer-layer timing belt 8, the inner-layer timing belt 10, and the middle-layer timing belt 13 are all double-sided tooth timing belts.

Further, as a preferred embodiment, one end of each glass support frame 4 is connected to two outer layer synchronous belts 8, the other end of each glass support frame 4 is connected to two inner layer synchronous belts 10, the middle of each glass support frame 4 is connected to two middle layer synchronous belts 13, and each glass support frame 4 is further provided with a synchronous belt 401 on each side. As shown in fig. 4, two ends and a middle portion of two sides of the glass support frame 4 are respectively provided with a connecting rod for connecting with an outer synchronous belt 8, an inner synchronous belt 10 and a middle synchronous belt 13, the first guide pulley module 1 and the second guide pulley module 2 drive the outer synchronous belt 8, the inner synchronous belt 10 and the middle synchronous belt 13 to run synchronously, and balance of the glass support frame 4 can be kept.

Further, as a preferred embodiment, the first guiding pulley module 1, the second guiding pulley module 2 and each third guiding pulley module 3 all include:

a connecting shaft 14.

Two synchronous pulleys 15, two synchronous pulleys 15 are arranged at two ends of the connecting shaft 14.

Further, as a preferred embodiment, each of the timing pulleys 15 includes:

synchronous pulley main part 154, the outer fringe at the middle part of synchronous pulley main part 154 is equipped with first teeth of a cogwheel module 151, and the outer fringe of the one end of synchronous pulley main part 154 is equipped with second teeth of a cogwheel module 152, and the outer fringe of the other end of synchronous pulley main part 154 is equipped with third teeth of a cogwheel module 153, and outer hold-in range 8 is connected with third teeth of a cogwheel module 153, and inlayer hold-in range 10 is connected with second teeth of a cogwheel module 152, and middle level hold-in range 13 is connected with first teeth of. As shown in fig. 3, in the present embodiment, the second gear tooth module 152 is disposed on the outer side of the timing pulley body 154 for connecting the outer-layer timing belt 8, and the third gear tooth module 153 is disposed on the inner side of the timing pulley body 154 for connecting the inner-layer timing belt 10.

Further, as an embodiment of preferred, first leading pulley module 1, second leading pulley module 2 and each third leading pulley module 3 still all include:

two guide smooth wheels 16, two guide smooth wheels 16 are arranged at two ends of the connecting shaft 14, and the two guide smooth wheels 16 are respectively positioned between the two synchronous belt wheels 15. The two guiding smooth wheels 16 in this embodiment function to guide the glass support frame 4, and when the glass support frame 4 passes through the guiding smooth wheels 16, the synchronous belt 401 slides on the guiding smooth wheels 16.

The above is merely an example of the preferred embodiments of the present invention, and the embodiments and the protection scope of the present invention are not limited thereby.

The utility model discloses still have following implementation mode on foretell basis:

as an implementation mode, the glass sheet storage device further comprises a first rotary belt conveyor 17 and a second rotary belt conveyor 18, wherein the first rotary belt conveyor 17 and the second rotary belt conveyor 18 are arranged on two sides of the outer layer synchronous belt module, as shown in the direction of fig. 1, the first rotary belt conveyor 17 is arranged on the left side of the outer layer synchronous belt module, the second rotary belt conveyor 18 is arranged on the right side of the outer layer synchronous belt module, when the glass sheet is required to be stored, the first rotary belt conveyor 17 is in a horizontal state, the glass sheet enters the glass support frame 4 from the first rotary belt conveyor 17, and enters the glass sheet online storage mechanism under the action of the outer layer synchronous belt 8, the inner layer synchronous belt 10 and the middle layer synchronous belt 13. When the glass sheet needs to be released, the second rotary belt conveyor 18 is in a horizontal position and the glass sheet is horizontally transferred from the glass sheet in-line storage mechanism onto the second rotary belt conveyor 18.

In one embodiment, a roller conveyor 19 is provided at the lower side of the third guiding pulley modules 3, and when the glass sheet is not required to be stored, the first rotating belt conveyor 17 and the second rotating belt conveyor 18 are both in a downward inclined state, and the glass sheet enters the roller conveyor 19 from the first rotating belt conveyor 17, then enters the second rotating belt conveyor 18, and finally enters the next process of the production line.

The above description is only an example of the preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and those skilled in the art should be able to realize the equivalent alternatives and obvious variations of the present invention.

Claims (8)

1. An online glass storage mechanism, comprising:

a first guide belt wheel module;

the first guide belt pulley module and the second guide belt pulley module are transversely arranged side by side, and a gap is arranged between the first guide belt pulley module and the second guide belt pulley module;

the third guide belt pulley modules are transversely arranged at the lower sides of the first guide belt pulley module and the second guide belt pulley module side by side and are arranged at equal intervals;

the outer layer synchronous belt module is connected with the first guide belt pulley module, the second guide belt pulley module and the plurality of third guide belt pulley modules;

the inner-layer synchronous belt module is arranged on the inner side of the outer-layer synchronous belt module and is connected with the first guide belt wheel module, the second guide belt wheel module and the plurality of third guide belt wheel modules;

the middle-layer synchronous belt module is positioned between the outer-layer synchronous belt module and the inner-layer synchronous belt module and is connected with the first guide belt pulley module, the second guide belt pulley module and a plurality of third guide belt pulley modules;

each glass support frame is respectively connected with the outer layer synchronous belt module, the middle layer synchronous belt module and the inner layer synchronous belt module;

and the driving motor is in driving connection with the first guide belt wheel module.

2. The glass online storage mechanism as claimed in claim 1, wherein the outer layer synchronous belt module comprises two outer layer synchronous belt modules, the two outer layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two outer layer synchronous belt modules;

each of the outer belt modules includes:

the first synchronous belt pulley is arranged on one side, away from the second guide belt pulley module, of the first guide belt pulley module;

the second synchronous belt pulley is arranged on one side, far away from the first guide belt pulley module, of the second guide belt pulley module;

the lower sides of the first synchronous belt wheel and the second synchronous belt wheel are respectively provided with a third synchronous belt wheel, and each third synchronous belt wheel is respectively positioned on the upper sides of a plurality of third guide belt wheel modules;

the outer layer synchronous belt is connected with the first guide belt pulley module, the second guide belt pulley module, the first synchronous belt pulley, the second synchronous belt pulley, the third synchronous belt pulley and the third guide belt pulley module.

3. The glass online storage mechanism as claimed in claim 2, wherein the inner layer synchronous belt module comprises two inner layer synchronous belt modules, the two inner layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two inner layer synchronous belt modules;

each of the inner belt modules includes:

two fourth synchronous pulleys, wherein one of the fourth synchronous pulleys is arranged on the lower side of the first guide pulley module, the other fourth synchronous pulley is arranged on the lower side of the second guide pulley module, and each fourth synchronous pulley is respectively positioned on the upper sides of the plurality of third guide pulley modules;

an inlayer hold-in range, the inlayer hold-in range is connected first leading pulley module second leading pulley module, two fourth synchronous pulley and a plurality of third leading pulley module.

4. The glass online storage mechanism as claimed in claim 3, wherein the middle layer synchronous belt module comprises two middle layer synchronous belt modules, the two middle layer synchronous belt modules are arranged in parallel, and a gap is arranged between the two middle layer synchronous belt modules;

each of the middle-layer timing belt modules includes:

two fifth synchronous pulleys, wherein one fifth synchronous pulley is arranged between the first guide pulley module and the first synchronous pulley, and the other fifth synchronous pulley is arranged between the second guide pulley module and the second synchronous pulley;

each sixth synchronous belt pulley is positioned at the lower side of one fifth synchronous belt pulley, and each sixth synchronous belt pulley is positioned at the upper sides of the third guide belt pulley modules;

the middle-layer synchronous belt is connected with the first guide belt pulley module, the second guide belt pulley module, the two fifth synchronous belt pulleys, the two sixth synchronous belt pulleys and the plurality of third guide belt pulley modules.

5. The glass online storage mechanism as claimed in claim 4, wherein one end of each of the two sides of each of the glass support frames is connected to the two outer layer synchronous belts, the other end of each of the two sides of each of the glass support frames is connected to the two inner layer synchronous belts, and the middle of each of the two sides of each of the glass support frames is connected to the two middle layer synchronous belts.

6. The glass online storage mechanism of claim 4, wherein the first guide pulley module, the second guide pulley module, and each of the third guide pulley modules comprise:

a connecting shaft;

and the two synchronous belt wheels are arranged at two ends of the connecting shaft.

7. The glass in-line storage mechanism of claim 6, wherein each of the timing pulleys comprises:

the synchronous pulley main part, the outer fringe at the middle part of synchronous pulley main part is equipped with first teeth of a cogwheel module, the outer fringe of the one end of synchronous pulley main part is equipped with second teeth of a cogwheel module, the outer fringe of the other end of synchronous pulley main part is equipped with third teeth of a cogwheel module, outer hold-in range with third teeth of a cogwheel module is connected, the inlayer hold-in range with second teeth of a cogwheel module is connected, the middle level hold-in range with first teeth of a cogwheel module is connected.

8. The glass online storage mechanism of claim 6, wherein the first guide pulley module, the second guide pulley module, and each of the third guide pulley modules further comprise:

and the two guide smooth wheels are arranged at two ends of the connecting shaft and are respectively positioned between the two synchronous belt wheels.

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