CN204296163U - Built-in blooming applying system - Google Patents

Built-in blooming applying system Download PDF

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Publication number
CN204296163U
CN204296163U CN201420696619.6U CN201420696619U CN204296163U CN 204296163 U CN204296163 U CN 204296163U CN 201420696619 U CN201420696619 U CN 201420696619U CN 204296163 U CN204296163 U CN 204296163U
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blooming
conveying device
buffering
downstream
substrate
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由良友和
木村功儿
大泽曜彰
长广一平
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Nitto Denko Corp
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Nitto Denko Corp
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Abstract

The utility model provides a kind of built-in blooming applying system, it is the device manufacturing optical substrate to glass substrate laminating blooming, be set to be connected continuously with downstream unit, there is glass substrate supply unit, glass substrate transport path, the first blooming transport path, the second blooming transport path, buffer part, described buffer part is connected between described glass substrate transport path and described downstream unit, when described downstream unit blocking, store optical substrate.According to this structure, the performance of built-in blooming applying system can be given full play to.

Description

Built-in blooming applying system
Technical field
The utility model relates to a kind of built-in blooming applying system.
Background technology
In recent years, constantly universal along with display, the manufacturing technology as the optical display of one of the critical component of display also receives increasing concern.
Wherein, for the novel optical film applying system be widely used (being called that roller is for plate system or RTP system), mostly used by as independently production line because its production efficiency is high.This system is not connected with the production line of display manufacturer, but independently produces.
Such as, as shown in Figure 1, in novel optical film applying system, carry out the operation to glass substrate laminating blooming.After end blooming bonding process, be mounted in storing mechanism by the glass substrate completing blooming laminating, the optical display manufacturing installation to downstream is carried.But, in such an embodiment, due to needs moving glass substrate back and forth, so the production efficiency of optical display can be affected.
Therefore, have developed the built-in novel optical film applying system (being called that built-in roller is to plate system or RTP system) be connected with the optical display manufacturing installation in downstream in recent years.Thus, the glass substrate completing blooming laminating is eliminated storage, the handling process of glass substrate directly to the optical display manufacturing installation conveying in downstream.
But, for this structure, because novel optical film applying system is compared with traditional blooming applying system, production efficiency accelerates, if so directly novel optical film applying system is connected with the optical display manufacturing installation in downstream, then the problem that the productive capacity before and after existing between operation there are differences.Therefore, on direct optical display manufacturing installation novel optical film applying system being connected to downstream, there is the problem that cannot give full play to the performance of novel optical film applying system.
Patent documentation 1: Japanese Unexamined Patent Publication 2005-037417 publication
Utility model content
The utility model is made in view of the above problems, its object is to provide a kind of and is connected continuously with optical display manufacturing installation and can gives full play to the built-in blooming applying system of the productive capacity of blooming applying system.
To achieve these goals, one side of the present utility model provides a kind of built-in blooming applying system, and it is the device manufacturing optical substrate to glass substrate laminating blooming, is set to be connected continuously with downstream unit, have: glass substrate supply unit, it supplies glass substrate; Glass substrate transport path, itself and described glass substrate supply unit are connected in series and form main transport path and from described glass substrate supply unit to described downstream unit feeding optical substrate, its midway is provided with the first blooming sticking part and the second blooming sticking part, at described first blooming sticking part, the first blooming is fitted on described glass substrate, at described second blooming sticking part, the second blooming is fitted on described glass substrate; First blooming transport path, its bypass as main transport path carries the first blooming to the first blooming sticking part of described glass substrate transport path; Second blooming transport path, its bypass as main transport path carries the second blooming to the second blooming sticking part of described glass substrate transport path; The feature of described built-in blooming applying system is also have buffer part, and described buffer part is connected between described glass substrate transport path and described downstream unit, when described downstream unit blocking, stores optical substrate.
Preferably, described buffer part is provided with the first delivery section, substrate supply unit and form usual transport path along the throughput direction of described glass substrate transport path with being sequentially connected in series, with to described downstream unit feeding optical substrate, described buffer part also has: substrate storage unit, it is formed as the buffer path different from described usual transport path, and be connected with described first delivery section, store optical substrate; Buffering control device, it is busy at described downstream unit, when stopping, controlling described first delivery section and optical substrate is transferred load to described buffer path from described usual transport path, temporarily store optical substrate.
Preferably, described first delivery section has: the first downstream conveying device, and it is roller conveying device, to described substrate supply unit feeding optical substrate; First buffering conveying device, it is roller conveying device, to described substrate storage unit feeding optical substrate; First switching device shifter, it switches described first buffering conveying device and described first downstream conveying device;
First downstream conveying device is configured in directly over the first buffering conveying device,
The diameter forming the conveying roller of described first buffering conveying device is greater than the diameter of the conveying roller forming described first downstream conveying device, when described downstream unit is idle, the upper surface of the conveying roller of described first downstream conveying device is higher than the upper surface of conveying roller forming described first buffering conveying device, thus utilize described first downstream conveying device along described usual transport path feeding optical substrate
Busy at described downstream unit, stop time, described buffering control device controls described first switching device shifter, promote described first buffering conveying device, to make the upper surface of the conveying roller of described first buffering conveying device higher than the upper surface of the conveying roller of described first downstream conveying device, thus utilize described first buffering conveying device from described usual transport path to described buffer path feeding optical substrate
When the upstream device of the upstream being positioned at described buffer part stops, described buffering control device controls described first switching device shifter, promote described first buffering conveying device, to make the upper surface of the conveying roller of described first buffering conveying device higher than the upper surface of the conveying roller of described first downstream conveying device, thus return from described buffer path to described usual transport path and remove optical substrate.
Preferably, described first delivery section has: the first downstream conveying device, and it is roller conveying device, to described substrate supply unit feeding optical substrate; First buffering conveying device, it is mechanical arm, to described substrate storage unit feeding optical substrate;
When described downstream unit is idle, described buffering control device controls described first downstream conveying device, along described usual transport path feeding optical substrate,
Busy at described downstream unit, when stopping, described buffering control device controls described first buffering conveying device, from described usual transport path to described buffer path feeding optical substrate,
When described upstream device stops, described buffering control device controls described first buffering conveying device, returns remove optical substrate from described buffer path to described usual transport path.
Preferably, described buffer part also has substrate buffering unit, described substrate buffering unit is roller conveying device, be connected in series between described first delivery section and described substrate storage unit, from described first delivery section, via described substrate buffering unit, to described substrate storage unit feeding optical substrate.
Preferably, described buffer part is provided with the first delivery section with being sequentially connected in series along the throughput direction of described glass substrate transport path, second delivery section, substrate supply unit and form usual transport path, with to described downstream unit feeding optical substrate, described buffer part also has: substrate buffering unit, it is multiple and the connection that is one another in series, be formed as the buffer path different from described usual transport path, the substrate buffering unit of the most upstream of this buffer path is connected with described first delivery section, and the substrate buffering unit of the most downstream of this buffer path is connected with described second delivery section, buffering control device, it is busy at described downstream unit, when stopping, control described first delivery section and optical substrate is transferred load to described buffer path from described usual transport path, when described upstream device stops, controlling described second delivery section and return from described buffer path to described usual transport path and remove optical substrate.
Preferably, described first delivery section has: the first downstream conveying device, and it is roller conveying device, to described second delivery section feeding optical substrate; First buffering conveying device, it is roller conveying device, to described substrate buffering unit feeding optical substrate; First switching device shifter, it switches described first buffering conveying device and described first downstream conveying device;
First downstream conveying device is configured in directly over the first buffering conveying device,
The diameter forming the conveying roller of described first buffering conveying device is greater than the diameter of the conveying roller forming described first downstream conveying device, when described downstream unit is idle, the upper surface of the conveying roller of described first downstream conveying device is higher than the upper surface of the conveying roller of described first buffering conveying device, thus utilize described first downstream conveying device along described usual transport path feeding optical substrate
Busy at described downstream unit, stop time, described buffering control device controls described first switching device shifter, promote described first buffering conveying device, to make the upper surface of the conveying roller of described first buffering conveying device higher than the upper surface of the conveying roller of described first downstream conveying device, thus utilize described first buffering conveying device from described usual transport path to described buffer path feeding optical substrate.
Preferably, described first delivery section has: the first downstream conveying device, and it is roller conveying device, to described second delivery section feeding optical substrate; First buffering conveying device, it is mechanical arm, to described substrate buffering unit feeding optical substrate;
When described downstream unit is idle, described buffering control device controls described first downstream conveying device, along described usual transport path feeding optical substrate,
Busy at described downstream unit, when stopping, described buffering control device controls described first buffering conveying device, from described usual transport path to described buffer path feeding optical substrate.
Preferably, described second delivery section has: the second downstream conveying device, and it is roller conveying device, to described substrate supply unit feeding optical substrate; Second buffering conveying device, it is roller conveying device, returns remove optical substrate from described substrate buffering unit; Second switching device shifter, it switches described second buffering conveying device and described second downstream conveying device;
Second downstream conveying device is configured in directly over the second buffering conveying device,
The diameter forming the conveying roller of described second buffering conveying device is greater than the diameter of the conveying roller forming described second downstream conveying device, when described downstream unit is idle, the upper surface of the conveying roller of described second downstream conveying device is higher than the upper surface of conveying roller forming described second buffering conveying device, utilize described second downstream conveying device along described usual transport path feeding optical substrate
When described upstream device stops, described buffering control device controls described second switching device shifter, promote described second buffering conveying device, to make the upper surface of the conveying roller of described second buffering conveying device higher than the upper surface of the conveying roller of described second downstream conveying device, utilize described second buffering conveying device to return from described buffer path to described usual transport path and remove optical substrate.
Preferably, described second delivery section has: the second downstream conveying device, and it is roller conveying device, to described substrate supply unit feeding optical substrate; Second buffering conveying device, it is mechanical arm, returns remove optical substrate from described substrate buffering unit;
When described downstream unit is idle, described buffering control device controls described second downstream conveying device, along described usual transport path feeding optical substrate,
When described upstream device stops, described buffering control device controls described second buffering conveying device, returns remove optical substrate from described buffer path to described usual transport path.
Preferably, described substrate supply unit is roller conveying device or mechanical arm.
Preferably, described first blooming transport path has: the first blooming supply unit, and it is configured in the most upstream of described first blooming transport path, supplies described first blooming; First blooming cutting portion, itself and described first blooming supply unit are connected in series, and cut off described first blooming from described first blooming supply unit supply; First carrier film winder, it is configured in the most downstream of described first blooming transport path, and winding has been fitted the first carrier film of the first blooming.
Preferably, described second blooming transport path has: the second blooming supply unit, and it is configured in the most upstream of described second blooming transport path, supplies described second blooming; Second blooming cutting portion, itself and described second blooming supply unit are connected in series, and cut off described second blooming from described second blooming supply unit supply; Second support film winder, it is configured in the most downstream of described second blooming transport path, and winding has been fitted the Second support film of the second blooming.
Preferably, described glass substrate transport path also has: the first glass substrate rotary turning portion, and it is configured in the downstream of described first blooming sticking part, and the glass substrate of blooming of one side having been fitted rotates and overturns; First blooming paste position determination part, it is configured in the downstream in described first glass substrate rotary turning portion, measures the paste position of the first blooming; Second glass substrate turning part, it is configured in the downstream of described second blooming sticking part, and two-sided glass substrate of fitting blooming is rotated and overturn; Second blooming paste position determination part, it is configured in the downstream of described second glass substrate turning part, measures the paste position of the second blooming; Optical substrate inspection portion, it is configured in the downstream of described second blooming paste position determination part, checks optical substrate.
Preferably, described downstream unit is display panels driving chip erecting device.
According to structure of the present utility model, because built-in blooming applying system is connected with downstream unit via buffer part, therefore, even if the speed of production of this built-in blooming applying system is faster than the speed of production of the optical display manufacturing installation in downstream, also this buffer part can be utilized, the optical substrate flowed out from this built-in blooming applying system is stored, thus the productive capacity of this built-in blooming applying system can be played fully.
In addition, when upstream device stops, the optical substrate be stored in buffer part can be moved into downstream unit, thus the production and processing of downstream unit can not be affected.
In addition, even if when downstream unit stops, optical substrate can being moved in buffer part, thus optical substrate is stored in buffer part, therefore, it is possible to ensure the production of built-in blooming applying system.
Accompanying drawing explanation
Fig. 1 is the schematic diagram representing the existing novel optical film applying system used as independent line.
Fig. 2 is the schematic diagram representing built-in novel optical film applying system of the present utility model.
Fig. 3 is the brief configuration figure of the display panels buffer part representing embodiment 1.
Fig. 4 is the side cutaway view of the first delivery section of the display panels buffer part representing the embodiment 1 using downstream conveying device.
Fig. 5 is the side cutaway view of the first delivery section of the display panels buffer part representing the embodiment 1 using buffering conveying device.
Fig. 6 is the brief configuration figure of the display panels buffer part representing embodiment 2.
Fig. 7 is the brief configuration figure of the display panels buffer part representing embodiment 3.
Description of reference numerals
1 liquid crystal cells manufacturing installation
2 LCD board manufacturing apparatus
3 first blooming supply units
4 first blooming cutting portions
5 first blooming sticking parts
6 first carrier film winders
7 liquid crystal cells rotary turning portions
8 first blooming paste position determination parts
9 second blooming supply units
10 second blooming cutting portions
11 second blooming sticking parts
12 Second support film winders
13 display panels turning part
14 second blooming paste position determination parts
15 display panels inspection portions
16 display panels buffer part
The built-in blooming applying system of R
A liquid crystal cells supply unit
B glass substrate transport path
C first blooming transport path
D second blooming transport path
16a first delivery section
16b substrate supply unit
16c substrate storage unit
16d cushioning control portion
16e substrate buffering unit
16f second delivery section
17,17a, 17c buffering conveying device
17b substrate transfer unit
18,18c downstream conveying device
Embodiment
Below, with reference to accompanying drawing, embodiment of the present utility model is described in detail.
It should be noted that, in the following embodiments, be set forth in liquid crystal cells laminating blooming and be described to manufacture the situation of display panels.
As shown in Figure 2, described blooming applying system has liquid crystal cells supply unit A, glass substrate transport path B, the first blooming transport path C and the second blooming transport path D, described glass substrate transport path B and described liquid crystal cells supply unit A and is connected in series and forms main transport path and from described liquid crystal cells supply unit A to downstream unit and LCD board manufacturing apparatus 2 conveying liquid LCD panel.
Described glass substrate transport path B has: the first blooming sticking part 5, and described first blooming is fitted on described liquid crystal cells by it; Liquid crystal cells rotary turning portion 7, the downstream of the described first blooming sticking part 5 of its configuration, the liquid crystal cells of blooming of one side having been fitted rotates and overturns; First blooming paste position determination part 8, it is configured in the downstream in described liquid crystal cells rotary turning portion 7, measures the paste position of the first blooming; Second blooming sticking part 11, it is configured in the downstream of described first blooming paste position determination part 8, is fitted on described liquid crystal cells by described second blooming; Display panels turning part 13, it is configured in the downstream of described second blooming sticking part 11, double-sided adhesive is posted the display panels upset of blooming; Second blooming paste position determination part 14, it is configured in the downstream of described display panels turning part 13, measures the paste position of the second blooming; Display panels inspection portion 15, it is configured in the downstream of described second blooming paste position determination part 14, checks the display panels being pasted with blooming.
Described first blooming transport path C has: the first blooming supply unit 3, and it is configured in the most upstream of described first blooming transport path C, supplies described first blooming; First blooming cutting portion 4, it is configured in the downstream of described first blooming supply unit 3, cuts off described first blooming supplied from described first blooming supply unit 3; First carrier film winder 6, it is configured in the most downstream of described first blooming transport path C, and winding has been fitted the first carrier film of the first blooming.
Described second blooming transport path D has: the second blooming supply unit 9, and it is configured in the most upstream of described second blooming transport path D, supplies described second blooming; Second blooming cutting portion 10, it is configured in the downstream of described second blooming feedway 9, cuts off described second blooming supplied from described second blooming feedway 9; Second support film winder 12, it is configured in the most downstream of described second blooming transport path D, and winding has been fitted the Second support film of the second blooming.
In addition, this blooming applying system is connected continuously with the LCD board manufacturing apparatus as downstream unit, thus is configured to built-in blooming applying system.Here, the LCD board manufacturing apparatus as downstream unit is such as display panels driving chip (TAB:Tape AotomatedBonding) erecting device.
Specifically, the liquid crystal cells of upstream equipment manufacture is supplied to this built-in blooming applying system R from liquid crystal cells supply unit A by this built-in blooming applying system R.
This built-in blooming applying system R also has display panels buffer part 16, described display panels buffer part 16 is connected between described glass substrate transport path B and described downstream unit, busy at described downstream unit, stop time, store optical substrate.Thus, the glass substrate transport path B of this built-in blooming applying system R is connected with downstream unit via display panels buffer part 16, thus display panels two sides having been pasted blooming is via display panels buffer part 16, carries to downstream unit.
Because built-in blooming applying system R is connected with downstream unit via display panels buffer part 16, therefore, even if the speed of production of this built-in blooming applying system R is faster than the speed of production of the LCD board manufacturing apparatus in downstream, also this display panels buffer part 16 can be utilized, the display panels flowed out from this built-in blooming applying system R is stored, thus the productive capacity of this built-in productive capacity of blooming applying system R and the LCD board manufacturing apparatus in downstream is matched, and the productive capacity of this built-in blooming applying system R can be played fully.
Specifically, such as, when the productive temp of downstream unit is greater than the productive temp of this built-in blooming applying system R, utilize the display panels buffer part 16 be arranged between display panels inspection portion and downstream unit of this built-in blooming applying system R, the display panels having completed blooming bonding process can be stored, thus can not be fast because of the speed of production of this built-in blooming applying system R, and the speed of production of downstream unit is slow, and cause downstream unit not catch up with the speed of production of this built-in blooming applying system R, the display panels completing blooming bonding process is made to be trapped in display panels inspection portion, slowed down the speed of production of this built-in blooming applying system R, and the productive capacity of this built-in blooming applying system R cannot be played fully.
< embodiment 1>
Below, with reference to Fig. 3, Fig. 4, the display panels buffer part 16 of the built-in blooming applying system R of embodiment 1 is described.
As shown in Figure 3, described display panels buffer part 16 has the first delivery section 16a, substrate supply unit 16b, substrate storage unit 16c and buffering control device 16d.
Specifically, described display panels buffer part 16 is provided with the first delivery section 16a, substrate supply unit 16b along the throughput direction of described glass substrate transport path and forms usual transport path with being sequentially connected in series, to be pasted with the display panels of blooming to described downstream unit 2 conveying.
Described substrate storage unit 16c is connected with described first delivery section 16a in the mode being formed as the buffer path different from described usual transport path.
Buffering control device 16d is busy at described downstream unit, when stopping, control described first delivery section 16a and the display panels being pasted with blooming is transferred load to described buffer path and described substrate storage unit 16c from described usual transport path, thus store the also display panels being pasted with blooming.
[the first delivery section]
First delivery section 16a is arranged on the downstream of glass substrate transport path B and for being carried to downstream unit via substrate supply unit 16b by display panels, and the first delivery section 16a is also connected with described substrate storage unit 16c and for being carried to substrate storage unit 16c by display panels.
As shown in Figure 4, Figure 5, the first delivery section 16a is the conveying device with dual roll structure.Specifically, the first delivery section 16a is the conveying device of the dual roll structure with the first buffering conveying device 17 and the first downstream conveying device 18.
Described first downstream conveying device 18 is the roller conveying devices be made up of conveying roller, display panels is carried to substrate supply unit 16b, the conveying roller of some can be arranged on rotationally on a conveying roll shaft and form conveying roller row, multiple conveying roller arranges and is set up in parallel along described usual transport path is with separating predetermined distance parallel, thus is carried to substrate supply unit by display panels along described usual transport path.
Described first buffering conveying device 17 is the roller conveying devices be made up of conveying roller, display panels is carried to substrate storage unit 16c or returned from substrate storage unit 16c and removes display panels, the conveying roller of some can be arranged on rotationally on a conveying roll shaft and form conveying roller row, multiple conveying roller Width arranged along described usual transport path separates that predetermined distance ground is parallel to be set up in parallel, thus by display panels to the substrate storage unit conveying of buffer path or the first delivery section 16a conveying from the substrate storage unit of buffer path to usual transport path.
That is, when overlooking, the conveying roller row of described first downstream conveying device 18 arrange with the conveying roller of described first buffering conveying device 17 and configure orthogonally with respect to one another.
In addition, spacing distance between the conveying roller row of described first downstream conveying device 18 is the distance of the thickness of the conveying roller being at least greater than described first buffering conveying device 17, that is, the conveying roller of described first buffering conveying device 17 can be made to pass between the conveying roller row of described first downstream conveying device 18.
Simultaneously, spacing distance between the conveying roller of described first buffering conveying device 17 is the distance of the diameter of the conveying roller being at least greater than described first downstream conveying device 18, that is, the conveying roller of described first downstream conveying device 18 can be made to pass between the conveying roller row of described first buffering conveying device 17.
Thus, described first buffering conveying device 17 can not rise interferingly, decline with described first downstream conveying device 18.
It should be noted that, the diameter forming the conveying roller of the first buffering conveying device 17 is greater than the diameter of the conveying roller of formation first downstream conveying device 18.
First delivery section 16a also has the first switching device shifter, for switching described first buffering conveying device 17 and described first downstream conveying device 18.
As shown in Figure 4, in the common display panels course of conveying of downstream unit 2 free time, first downstream conveying device 18 is positioned at the top of the first buffering conveying device 17, that is, the surface of the conveying roller of the first downstream conveying device 18 is formed all the time higher than the surface of the conveying roller of formation first buffering conveying device 17.Thereby, it is possible to utilize the first downstream conveying device 18 downstream transport display panels.
As shown in Figure 5, busy at downstream unit 2, stop time utilizing the first switching device shifter (not shown) to switch the dual roll structure of the first delivery section 16a, namely, the first switching device shifter is utilized to promote the position of the first buffering conveying device 17, to make the surface of surface higher than the conveying roller of the first downstream conveying device 18 of the conveying roller of formation first buffering conveying device 17, thus the first buffering conveying device 17 can be utilized from the first delivery section 16a of usual transport path to the substrate storage unit 16c conveying liquid LCD panel of buffer path
And when the upstream device of the upstream being positioned at display panels buffer part 16 stops, the first switching device shifter (not shown) is utilized to switch the dual roll structure of the first delivery section 16a, namely, the first switching device shifter is utilized to promote the position of the first buffering conveying device 17, to make the surface of surface higher than the conveying roller of the first downstream conveying device 18 of the conveying roller of formation first buffering conveying device 17, thus the first buffering conveying device 17 can be utilized to return from the substrate storage unit 16c of buffer path to the first delivery section 16a of usual transport path remove display panels.
Thereby, it is possible to utilize the first delivery section to realize the conveying along usual transport path and the conveying along buffer path simultaneously.
[substrate supply unit]
Substrate supply unit is roller conveying device or mechanical arm conveying device, is arranged between downstream unit and the first delivery section 16a, for downstream unit conveying liquid LCD panel.Such as, when there is no difference of height between the first delivery section 16a and substrate supply unit 16b, roller conveying device can be used as substrate supply unit 16b, when having difference of height between the first delivery section 16a and substrate supply unit 16b, mechanical arm conveying device can be used as substrate supply unit 16b.
[substrate storage unit]
Substrate storage unit 16c is formed as the buffer path different from described usual transport path, is connected with described first delivery section 16a, for storing the storage display panels needing buffering.
[buffering control device]
Buffering control device 16d, by control first delivery section 16a, controls the work of display panels buffer part 16.
Buffering control device 16d is such as microcomputer equal controller, has instruction reception portion and instruction sending part etc., thus controls the work of display panels buffer part 16.It should be noted that, the utility model enumerates the example of microcomputer as buffering control device 16d, but buffering control device 16d of the present utility model is not limited to microcomputer, as long as the device that can control the work of display panels buffer part 16.
Below, the work of buffering control device 16d is described.
First, the workflow before the display panels buffer part 16 of brief description built-in blooming applying system R.
To the liquid crystal cells supply unit supply liquid crystal cells of built-in blooming applying system R.Afterwards, according to the manufacturing procedure of common blooming applying system, the first blooming is pasted in a face of liquid crystal cells, will the liquid crystal cells 90-degree rotation of the first blooming will be pasted with and overturn, and measure the paste position of the first blooming.Next, the another side of this liquid crystal cells is pasted the second blooming, will the display panels upset of the first blooming and the second blooming have been pasted, and measure the paste position of the second blooming.Then, the display panels having pasted the first blooming and the second blooming is checked.
After display panels is checked, the display panels checked out is carried to downstream unit.At this moment, there is following situation.
First situation is that downstream unit is idle, namely, downstream unit waiting for the situation of the inflow of display panels.In this case, because buffering control device does not receive the display panels detection signal S that the display panels detecting sensor near the entrance being arranged at downstream unit sends, so do not send action command to the first switching device shifter, thus be in the state of use first downstream conveying device 18.Utilize the first downstream conveying device 18 to substrate supply unit 16b conveying liquid LCD panel, carry out normal production operation.
Thus, the display panels checked out is not moved in substrate storage unit 16c, and move into downstream unit.Thus continuous print processing operation can be carried out.
Second situation be downstream unit busy or stop, namely, downstream unit cannot move into the situation of new display panels.In this case, buffering control device receives the display panels detection signal S that the display panels detecting sensor near the entrance being arranged on downstream unit is sent, thus send action command to the first switching device shifter, rise the first buffering conveying device 17, utilize the first buffering conveying device 17 to the display panels of the substrate storage unit 16c conveying needs buffering of buffer path.
Thus, the display panels checked out can not be made to be trapped in display panels inspection portion, and can by display panels transfer in substrate storage unit 16c, thus the production of built-in blooming applying system R can not be affected, the performance of built-in blooming applying system R can be given full play to.
3rd situation is the situation that upstream device stops.That is, when upstream device stops, buffering control device receives halt instruction, action command is sent to the first switching device shifter, rise the first buffering by conveying device 17, utilize the first buffering conveying device 17 to return from the substrate storage unit 16c of buffer path to the first delivery section 16a of usual transport path and remove display panels.
Thus, when upstream device stops, the display panels be stored in substrate storage unit 16c is carried to the first delivery section 16a, carry to downstream unit via substrate supply unit 16b, thus the production and processing of downstream unit can not be affected.
Therefore, according to the display panels buffer part 16 of embodiment 1, when the flowing of the display panels of downstream unit stops, display panels can being accommodated in the substrate storage unit adjacent with the first delivery section.When the flowing of the display panels of downstream unit does not stop and not transporting substrate from upstream device, can from substrate storage unit to the first delivery section conveying liquid LCD panel.
According to the built-in blooming applying system R of the band display panels buffer part 16 of above-described embodiment 1, the performance of built-in blooming applying system R can be given full play to.
< embodiment 2>
Below, with reference to Fig. 6, the display panels buffer part 16 of the built-in blooming applying system R of embodiment 2 is described.The parts equal with embodiment 1 are represented with identical Reference numeral, and the repetitive description thereof will be omitted.
As shown in Figure 6, the display panels buffer part 16 of embodiment 2 also has the first delivery section 16a, substrate supply unit 16b, substrate storage unit 16c and buffering control device 16d.In addition, the display panels buffer part 16 of embodiment 2 also has substrate buffering unit 16e.
Identically with embodiment 1, the upstream of the first delivery section 16a of embodiment 2 is connected with described glass substrate transport path B, and the upstream of substrate supply unit 16b is connected with described first delivery section 16a, and downstream is connected with described downstream unit 2.Thus, described glass substrate transport path B, described first delivery section 16a, described substrate supply unit 16b usual transport path in series, to be pasted with the display panels of blooming to described downstream unit 2 conveying.
Difference from Example 1 is, described substrate storage unit 16c and substrate buffering unit 16e is connected in series and forms buffer path, and described substrate buffering unit 16e is connected with described first delivery section 16a.
Substrate buffering unit 16e is made up of roller conveying device or mechanical arm, is connected between the first delivery section 16a and substrate storage unit 16c.
[the first delivery section]
Identically with embodiment 1, the first delivery section 16a of embodiment 2 has the first buffering conveying device 17a and the first downstream conveying device 18.But, first downstream conveying device 18 of embodiment 2 is made up of roller conveying device, to substrate supply unit 16b conveying liquid LCD panel, first buffering conveying device 17a is made up of mechanical arm, utilizes the substrate transfer unit 17b be arranged on mechanical arm to be carried to substrate storage unit 16c by display panels.
Thereby, it is possible to utilize the first delivery section 16a to realize the conveying along usual transport path and the conveying along buffer path simultaneously.
[substrate buffering unit]
Substrate buffering unit 16e is made up of roller conveying device, is connected between the first delivery section 16a and substrate storage unit 16c.
[buffering control device]
Buffering control device 16d, by control first delivery section 16a, substrate buffering unit 16e, controls the work of display panels buffer part 16.
Next, the 26S Proteasome Structure and Function of buffering control device 16d is described.
Buffering control device 16d is such as microcomputer equal controller, has instruction reception portion and instruction sending part etc., thus controls the work of display panels buffer part 16.It should be noted that, the utility model enumerates the example of microcomputer as buffering control device 16d, but buffering control device 16d of the present utility model is not limited to microcomputer, as long as the device that can control the work of display panels buffer part 16.
Below, the work of buffering control device 16d is described.
Because the workflow before the display panels buffer part of the built-in blooming applying system R of the present embodiment is identical with embodiment 1, so omit the description.
After display panels is checked, the display panels checked out is carried to downstream unit.At this moment, there is following situation.
First situation is that downstream unit is idle, namely, downstream unit waiting for the situation of the inflow of display panels.In this case, because buffering control device 16d does not receive the display panels detection signal S that the display panels detecting sensor near the entrance being arranged at downstream unit sends, so be in the state of use first downstream conveying device 18.Utilize the first downstream conveying device 18 to substrate supply unit 16b conveying liquid LCD panel, carry out normal production operation.
Thus, the display panels checked out is not moved in substrate storage unit 16c, and move into downstream unit.Thus continuous print processing operation can be carried out.
Second situation be downstream unit busy or stop, namely, downstream unit cannot move into the situation of new display panels.In this case, buffering control device 16d receives the display panels detection signal S that the display panels detecting sensor near the entrance being arranged on downstream unit is sent, thus send action command to the first buffering conveying device 17a, the first buffering conveying device 17a is utilized to transport display panels to substrate buffering unit 16e, afterwards, via substrate buffering unit 16e, be stored in needing the display panels of buffering in substrate storage unit 16c.
Thus, the display panels checked out can not be made to be trapped in display panels inspection portion, and can by display panels transfer in substrate storage unit 16c, thus the production of built-in blooming applying system R can not be affected, the performance of built-in blooming applying system R can be given full play to.
3rd situation is the situation that upstream device stops.That is, when upstream device stops, buffering control device receives halt instruction, utilize substrate buffering unit 16e to return from substrate storage unit 16c and remove display panels, and send action command to the first buffering conveying device 17a, utilize the first buffering conveying device 17a to return from substrate buffering unit 16e to the first delivery section 16a and remove display panels.
Thus, when upstream device stops, the display panels be stored in substrate storage unit 16c is carried to the first delivery section 16a, carry to downstream unit via substrate supply unit 16b, thus the production and processing of downstream unit can not be affected.
Therefore, according to the display panels buffer part 16 of embodiment 2, when the flowing of the display panels of downstream unit stops, can utilize the substrate transfer unit be arranged on mechanical arm that display panels is moved into substrate buffering unit 16e from the first delivery section 16a, afterwards, display panels is accommodated in substrate storage unit 16c.When the flowing of the display panels of downstream unit does not stop and not transporting substrate from upstream device, display panels can be taken out of from substrate storage unit 16c to substrate buffering unit 16e, thus utilize the substrate transfer unit that is arranged on mechanical arm to be returned to the first delivery section 16a by display panels to remove.
According to the built-in blooming applying system R of the band display panels buffer part 16 of above-described embodiment 2, the performance of built-in blooming applying system R can be given full play to.
< embodiment 3>
Below, with reference to Fig. 7, the display panels buffer part 16 of the built-in blooming applying system R of embodiment 3 is described.The parts equal with embodiment 1 are represented with identical Reference numeral, and the repetitive description thereof will be omitted.
As shown in Figure 7, identically with embodiment 1, the display panels buffer part 16 of embodiment 3 also has the first delivery section 16a, substrate supply unit 16b and buffering control device 16d.In addition, difference from Example 1 is, the display panels buffer part 16 of embodiment 3 also has the second delivery section 16f, multiple substrate buffering unit 16e.
The upstream of the first delivery section 16a of embodiment 3 is connected with described glass substrate transport path B, the upstream of the second delivery section 16f is connected with described first delivery section 16a, the upstream of substrate supply unit 16b is connected with described second delivery section 16f, and downstream is connected with described downstream unit 2.Thus, described glass substrate transport path B, described first delivery section 16a, described second delivery section 16f, described substrate supply unit 16b usual transport path in series, to be pasted with the display panels of blooming to described downstream unit 2 conveying.
Multiple substrate buffering unit 16e is one another in series and connects into buffer path, make in the mode being formed as bypass the substrate buffering unit of the most upstream of this buffer path be connected with described first delivery section, and the substrate buffering unit of the most downstream of this buffer path is connected with described second delivery section.
[the first delivery section]
The structure of the first delivery section 16a of embodiment 3 is substantially the same manner as Example 1, is also to have the first buffering conveying device 17 and the first downstream conveying device 18.The first switching device shifter is utilized to switch the first buffering conveying device 17 and the first downstream conveying device 18.First downstream conveying device 18 is made up of roller conveying device, carried by display panels to the second delivery section 16f, and then carry to substrate supply unit 16b, thus carry to downstream unit.As different from Example 1, first buffering conveying device 17 is made up of roller conveying device, only by the substrate buffering unit 16e conveying liquid LCD panel of display panels to buffer path, and can not return from the substrate buffering unit 16e of buffer path and remove display panels.
The first delivery section 16a of the present embodiment is connected between upstream device and the second delivery section 16f, and is connected with side, the most upstream substrate buffering unit (hereinafter referred to as first substrate buffer cell) of buffer path.
The principle of work of the first delivery section 16a of embodiment 3 is compared with embodiment 1, and remove except display panels except not returning from the substrate buffering unit 16e of buffer path, other are substantially identical, therefore, in this description will be omitted.
[the second delivery section]
Second delivery section 16f is connected between the first delivery section 16a and substrate supply unit 16b, is carried to substrate supply unit 16b the display panels transported from the first delivery section 16a.The substrate buffering unit as most downstream side (hereinafter referred to as final substrate buffering unit) of the buffer path that the second delivery section 16f is also formed with by substrate buffering unit 16e is connected, and is carried to substrate supply unit 16b the display panels transported from substrate buffering unit 16e.
The structure of the second delivery section 16f is similar to the structure of the first delivery section 16a, has the second buffering conveying device 17c and the second downstream conveying device 18c.The second buffering conveying device 17c and the second downstream conveying device 18c is switched by the second switching device shifter, second downstream conveying device 18c is made up of roller conveying device, display panels is carried to substrate supply unit 16b, and then carries to downstream unit.Second buffering conveying device 17c is made up of roller conveying device, returns remove display panels from substrate buffering unit 16e.
Because the second delivery section 16f is compared with the principle of work of the first delivery section 16a, first delivery section 16a is to the substrate buffering unit 16e conveying liquid LCD panel of buffer path, and the second delivery section 16f returns from the substrate buffering unit 16e of buffer path and removes display panels, principle of work is in addition substantially identical, therefore, in this description will be omitted.
[substrate buffering unit]
Multiple substrate buffering unit 16e is made up of roller conveying device respectively, and multiple substrate buffering unit 16e is configured to series connection formation buffer path.Wherein, first substrate buffer cell 16e is connected with the first delivery section 16a, final substrate buffering unit 16e is connected with the second delivery section 16f, thus is formed from the first delivery section 16a, via multiple substrate buffering unit 16e, buffer path to the second delivery section 16f conveying liquid LCD panel.
Here, the quantity of substrate buffering unit 16e does not do special restriction, as long as can form the bypass from the first delivery section 16a to the second delivery section 16c.For convenience of description, at this, according to from upstream side (i.e. the first conveying device 16a side) to the order of downstream (the second conveying device 16f side), multiple substrate buffering unit 16e is called: first substrate buffer cell, second substrate buffer cell, the 3rd substrate buffering unit ..., final substrate buffering unit.
When the substrate flowing of downstream unit stops, from the first delivery section 16a to first substrate buffer cell 16e conveying liquid LCD panel, after this, if when the substrate flowing of downstream unit stops again, display panels is carried from first substrate buffer cell 16e to second substrate buffer cell 16e, and from the first delivery section 16a to first substrate buffer cell 16e, conveying needs the display panels of buffering again.When occurring that the substrate flowing of downstream unit stops again next time, by that analogy.
When upstream device stops, returning from final substrate buffering unit 16e to the second delivery section 16f and remove display panels, thus via substrate supply unit 16b to downstream unit conveying liquid LCD panel.
[buffering control device]
Buffering control device 16d, by control first delivery section 16a, the second delivery section 16f, substrate buffering unit 16e, controls the work of display panels buffer part 16.
Next, the 26S Proteasome Structure and Function of buffering control device 16d is described.
Buffering control device 16d is such as microcomputer equal controller, has instruction reception portion and instruction sending part etc., thus controls the work of display panels buffer part 16.It should be noted that, the utility model enumerates the example of microcomputer as buffering control device 16d, but buffering control device 16d of the present utility model is not limited to microcomputer, as long as the device that can control the work of display panels buffer part 16.
Below, the work of buffering control device is described.
Because the workflow before the display panels buffer part of the built-in blooming applying system R of the present embodiment is identical with embodiment 1, so omit the description.
After display panels is checked, the display panels checked out is carried to downstream unit.At this moment, there is following situation.
First situation is that downstream unit is idle, namely, downstream unit waiting for the situation of the inflow of display panels.In this case, because buffering control device does not receive the display panels detection signal S that the display panels detecting sensor near the entrance being arranged at downstream unit sends, so do not send action command to the switching device shifter of the first delivery section 16a and the second delivery section 16f, thus be in the state using first, second downstream conveying device 18,18c.Utilize first, second downstream conveying device 18,18c along usual transport path to substrate supply unit 16b conveying liquid LCD panel, carry out normal production operation.
Thus, the display panels checked out is not moved in substrate buffering unit 16e, and move into downstream unit.Thus continuous print processing operation can be carried out.
Second situation be downstream unit busy or stop, namely, downstream unit cannot move into the situation of new display panels.In this case, buffering control device 16d receives the display panels detection signal S that the display panels detecting sensor near the entrance being arranged on downstream unit is sent, thus send action command to first switching device shifter of the first delivery section 16a, rise the first buffering conveying device 17, utilize the first buffering conveying device 17 to the display panels of the first substrate buffer cell 16e conveying needs buffering of buffer path.
Thus, the display panels checked out can not be made to be trapped in display panels inspection portion, and can by display panels transfer in substrate buffering unit 16e, thus the production of built-in blooming applying system R can not be affected, the performance of built-in blooming applying system R can be given full play to.
3rd situation is the situation that upstream device stops.That is, when upstream device stops, buffering control device 16d receives halt instruction, thus send action command to second switching device shifter of the second delivery section 16f, rise the second buffering and use conveying device 17c, utilize the second buffering conveying device 17c to return from the final substrate buffering unit 16e of buffer path to the second delivery section 16f and remove display panels.
Thus, when upstream device stops, the display panels be stored in substrate buffering unit is carried to the second delivery section 16f, carry to downstream unit via substrate supply unit 16b, thus the production and processing of downstream unit can not be affected.
Therefore, according to the display panels buffer part 16 of embodiment 3, when the substrate flowing of downstream unit stops, from the first delivery section 16a to first substrate buffer cell 16e conveying liquid LCD panel, after this, if when the substrate flowing of downstream unit stops again, carried by display panels from first substrate buffer cell 16e to second substrate buffer cell 16e, and from the first delivery section 16a to first substrate buffer cell 16e, conveying needs the display panels of buffering again.When occurring that the substrate flowing of downstream unit stops again next time, by that analogy.When the flowing of the display panels of downstream unit does not stop and not transporting substrate from upstream device, from final substrate buffering unit 16e to the second delivery section 16f conveying liquid LCD panel, thus via substrate supply unit 16b to downstream unit conveying liquid LCD panel.
According to the built-in blooming applying system R of the band display panels buffer part 16 of above-described embodiment 3, the performance of built-in blooming applying system R can be given full play to.
Industrial applicibility
In the utility model, enumerate above-described embodiment 1, embodiment 2, display panels buffer part described in embodiment 3 be described, but, buffer part of the present utility model is not limited thereto, embodiment 1, embodiment 2, embodiment 3 effectively can be combined and combinationally use, as long as the buffer part that can play storage optical substrate and cushion the processing of downstream unit, without particular limitation of the structure of buffer part.
In addition, the utility model is not limited to above-mentioned concrete form, can make various change in the category of technological thought of the present utility model, and these changes are included in scope of the present utility model too.

Claims (16)

1. a built-in blooming applying system, it is the device manufacturing optical substrate to glass substrate laminating blooming, is set to be connected continuously with downstream unit, has:
Glass substrate supply unit, it supplies glass substrate;
Glass substrate transport path, itself and described glass substrate supply unit are connected in series and form main transport path and from described glass substrate supply unit to described downstream unit feeding optical substrate, its midway is provided with the first blooming sticking part and the second blooming sticking part, at described first blooming sticking part, the first blooming is fitted on described glass substrate, at described second blooming sticking part, the second blooming is fitted on described glass substrate;
First blooming transport path, its bypass as main transport path carries the first blooming to the first blooming sticking part of described glass substrate transport path;
Second blooming transport path, its bypass as main transport path carries the second blooming to the second blooming sticking part of described glass substrate transport path;
The feature of described built-in blooming applying system is also have buffer part,
Described buffer part is connected between described glass substrate transport path and described downstream unit, when described downstream unit blocking, stores optical substrate.
2. built-in blooming applying system as claimed in claim 1, it is characterized in that, described buffer part is provided with the first delivery section, substrate supply unit and form usual transport path along the throughput direction of described glass substrate transport path with being sequentially connected in series, with to described downstream unit feeding optical substrate
Described buffer part also has:
Substrate storage unit, it is formed as the buffer path different from described usual transport path, and is connected with described first delivery section, stores optical substrate;
Buffering control device, it is busy at described downstream unit, when stopping, controlling described first delivery section and optical substrate is transferred load to described buffer path from described usual transport path, temporarily store optical substrate.
3. built-in blooming applying system as claimed in claim 2, is characterized in that, described first delivery section has:
First downstream conveying device, it is roller conveying device, to described substrate supply unit feeding optical substrate;
First buffering conveying device, it is roller conveying device, to described substrate storage unit feeding optical substrate;
First switching device shifter, it switches described first buffering conveying device and described first downstream conveying device;
First downstream conveying device is configured in directly over the first buffering conveying device,
The diameter forming the conveying roller of described first buffering conveying device is greater than the diameter of the conveying roller forming described first downstream conveying device, when described downstream unit is idle, the upper surface of the conveying roller of described first downstream conveying device is higher than the upper surface of conveying roller forming described first buffering conveying device, thus utilize described first downstream conveying device along described usual transport path feeding optical substrate
Busy at described downstream unit, stop time, described buffering control device controls described first switching device shifter, promote described first buffering conveying device, to make the upper surface of the conveying roller of described first buffering conveying device higher than the upper surface of the conveying roller of described first downstream conveying device, thus utilize described first buffering conveying device from described usual transport path to described buffer path feeding optical substrate
When the upstream device of the upstream being positioned at described buffer part stops, described buffering control device controls described first switching device shifter, promote described first buffering conveying device, to make the upper surface of the conveying roller of described first buffering conveying device higher than the upper surface of the conveying roller of described first downstream conveying device, thus return from described buffer path to described usual transport path and remove optical substrate.
4. built-in blooming applying system as claimed in claim 2, is characterized in that, described first delivery section has:
First downstream conveying device, it is roller conveying device, to described substrate supply unit feeding optical substrate;
First buffering conveying device, it is mechanical arm, to described substrate storage unit feeding optical substrate;
When described downstream unit is idle, described buffering control device controls described first downstream conveying device, along described usual transport path feeding optical substrate,
Busy at described downstream unit, when stopping, described buffering control device controls described first buffering conveying device, from described usual transport path to described buffer path feeding optical substrate,
When described upstream device stops, described buffering control device controls described first buffering conveying device, returns remove optical substrate from described buffer path to described usual transport path.
5. the built-in blooming applying system according to any one of claim 2 ~ 4, is characterized in that,
Described buffer part also has substrate buffering unit,
Described substrate buffering unit is roller conveying device, is connected in series between described first delivery section and described substrate storage unit, from described first delivery section, via described substrate buffering unit, to described substrate storage unit feeding optical substrate.
6. built-in blooming applying system as claimed in claim 1, it is characterized in that, described buffer part is provided with the first delivery section, the second delivery section, substrate supply unit and form usual transport path along the throughput direction of described glass substrate transport path with being sequentially connected in series, with to described downstream unit feeding optical substrate
Described buffer part also has:
Substrate buffering unit, it is multiple and the connection that is one another in series, be formed as the buffer path different from described usual transport path, the substrate buffering unit of the most upstream of this buffer path is connected with described first delivery section, and the substrate buffering unit of the most downstream of this buffer path is connected with described second delivery section;
Buffering control device, it is busy at described downstream unit, when stopping, controlling described first delivery section and optical substrate is transferred load to described buffer path from described usual transport path,
When described upstream device stops, controlling described second delivery section and return from described buffer path to described usual transport path and remove optical substrate.
7. built-in blooming applying system as claimed in claim 6, is characterized in that, described first delivery section has:
First downstream conveying device, it is roller conveying device, to described second delivery section feeding optical substrate;
First buffering conveying device, it is roller conveying device, to described substrate buffering unit feeding optical substrate;
First switching device shifter, it switches described first buffering conveying device and described first downstream conveying device;
First downstream conveying device is configured in directly over the first buffering conveying device,
The diameter forming the conveying roller of described first buffering conveying device is greater than the diameter of the conveying roller forming described first downstream conveying device, when described downstream unit is idle, the upper surface of the conveying roller of described first downstream conveying device is higher than the upper surface of the conveying roller of described first buffering conveying device, thus utilize described first downstream conveying device along described usual transport path feeding optical substrate
Busy at described downstream unit, stop time, described buffering control device controls described first switching device shifter, promote described first buffering conveying device, to make the upper surface of the conveying roller of described first buffering conveying device higher than the upper surface of the conveying roller of described first downstream conveying device, thus utilize described first buffering conveying device from described usual transport path to described buffer path feeding optical substrate.
8. built-in blooming applying system as claimed in claim 6, is characterized in that, described first delivery section has:
First downstream conveying device, it is roller conveying device, to described second delivery section feeding optical substrate;
First buffering conveying device, it is mechanical arm, to described substrate buffering unit feeding optical substrate;
When described downstream unit is idle, described buffering control device controls described first downstream conveying device, along described usual transport path feeding optical substrate,
Busy at described downstream unit, when stopping, described buffering control device controls described first buffering conveying device, from described usual transport path to described buffer path feeding optical substrate.
9. the built-in blooming applying system according to any one of claim 6 ~ 8, is characterized in that, described second delivery section has:
Second downstream conveying device, it is roller conveying device, to described substrate supply unit feeding optical substrate;
Second buffering conveying device, it is roller conveying device, returns remove optical substrate from described substrate buffering unit;
Second switching device shifter, it switches described second buffering conveying device and described second downstream conveying device;
Second downstream conveying device is configured in directly over the second buffering conveying device,
The diameter forming the conveying roller of described second buffering conveying device is greater than the diameter of the conveying roller forming described second downstream conveying device, when described downstream unit is idle, the upper surface of the conveying roller of described second downstream conveying device is higher than the upper surface of conveying roller forming described second buffering conveying device, utilize described second downstream conveying device along described usual transport path feeding optical substrate
When described upstream device stops, described buffering control device controls described second switching device shifter, promote described second buffering conveying device, to make the upper surface of the conveying roller of described second buffering conveying device higher than the upper surface of the conveying roller of described second downstream conveying device, utilize described second buffering conveying device to return from described buffer path to described usual transport path and remove optical substrate.
10. the built-in blooming applying system according to any one of claim 6 ~ 8, is characterized in that, described second delivery section has:
Second downstream conveying device, it is roller conveying device, to described substrate supply unit feeding optical substrate;
Second buffering conveying device, it is mechanical arm, returns remove optical substrate from described substrate buffering unit;
When described downstream unit is idle, described buffering control device controls described second downstream conveying device, along described usual transport path feeding optical substrate,
When described upstream device stops, described buffering control device controls described second buffering conveying device, returns remove optical substrate from described buffer path to described usual transport path.
11. built-in blooming applying systems as claimed in claim 5, is characterized in that,
Described substrate supply unit is roller conveying device or mechanical arm.
12. built-in blooming applying systems according to any one of claim 6 ~ 8, is characterized in that,
Described substrate supply unit is roller conveying device or mechanical arm.
13. built-in blooming applying systems as claimed in claim 1, is characterized in that, described first blooming transport path has:
First blooming supply unit, it is configured in the most upstream of described first blooming transport path, supplies described first blooming;
First blooming cutting portion, itself and described first blooming supply unit are connected in series, and cut off described first blooming from described first blooming supply unit supply;
First carrier film winder, it is configured in the most downstream of described first blooming transport path, and winding has been fitted the first carrier film of the first blooming.
14. built-in blooming applying systems as claimed in claim 1, is characterized in that, described second blooming transport path has:
Second blooming supply unit, it is configured in the most upstream of described second blooming transport path, supplies described second blooming;
Second blooming cutting portion, itself and described second blooming supply unit are connected in series, and cut off described second blooming from described second blooming supply unit supply;
Second support film winder, it is configured in the most downstream of described second blooming transport path, and winding has been fitted the Second support film of the second blooming.
15. built-in blooming applying systems as claimed in claim 1, it is characterized in that, described glass substrate transport path also has:
First glass substrate rotary turning portion, it is configured in the downstream of described first blooming sticking part, and the glass substrate of blooming of one side having been fitted rotates and overturns;
First blooming paste position determination part, it is configured in the downstream in described first glass substrate rotary turning portion, measures the paste position of the first blooming;
Second glass substrate turning part, it is configured in the downstream of described second blooming sticking part, by two-sided glass substrate upset of fitting blooming;
Second blooming paste position determination part, it is configured in the downstream of described second glass substrate turning part, measures the paste position of the second blooming;
Optical substrate inspection portion, it is configured in the downstream of described second blooming paste position determination part, checks optical substrate.
16. built-in blooming applying systems as described in claim 1, is characterized in that,
Described downstream unit is display panels driving chip erecting device.
CN201420696619.6U 2014-11-19 2014-11-19 Built-in blooming applying system Active CN204296163U (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105093585A (en) * 2015-08-19 2015-11-25 武汉华星光电技术有限公司 System and method for detecting liquid crystal display module
CN106826368A (en) * 2016-12-30 2017-06-13 北京源著智能科技有限公司 System of processing
CN107111407A (en) * 2015-09-18 2017-08-29 日东电工株式会社 To the method for touch sensor component affixing optical film
CN111148624A (en) * 2017-09-26 2020-05-12 株式会社Lg化学 Optical film attachment system
CN113877974A (en) * 2021-10-20 2022-01-04 华帝股份有限公司 Automatic punching line connecting operation process layout and method

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105093585A (en) * 2015-08-19 2015-11-25 武汉华星光电技术有限公司 System and method for detecting liquid crystal display module
CN107111407A (en) * 2015-09-18 2017-08-29 日东电工株式会社 To the method for touch sensor component affixing optical film
CN107111407B (en) * 2015-09-18 2021-02-09 日东电工株式会社 Method for adhering optical film to touch sensor element
CN106826368A (en) * 2016-12-30 2017-06-13 北京源著智能科技有限公司 System of processing
CN111148624A (en) * 2017-09-26 2020-05-12 株式会社Lg化学 Optical film attachment system
CN111148624B (en) * 2017-09-26 2022-02-08 杉金光电(苏州)有限公司 Optical film attachment system
CN113877974A (en) * 2021-10-20 2022-01-04 华帝股份有限公司 Automatic punching line connecting operation process layout and method

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