JP2010276896A - Apparatus for producing information display panel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To propose an apparatus for producing an information display panel, which is provided with a particle recovery unit for suitably recovering unpacked particles and treating the recovered particles. <P>SOLUTION: The information display panel displays information such as an image, wherein a plurality of cells are formed/divided by partition walls in the space formed by opposing two substrate, at least one of that is transparent, to each other, a particle group being a display medium is enclosed in each of cells and the particle group is moved. The apparatus 10 for producing the information display panel is provided with: a particle group packing tank 14 for executing a particle group packing step of arranging a mask for packing the particle group on the substrate and dropping the particle group from above to pack the dropped particle group in each of cells; and the particle recovery unit for sucking/recovering the unpacked particles stuck to the mask MS for packing the particle group after the particle group packing step is completed. The particle recovery unit comprises: a first-stage particle collecting means 12 which has a built-in filter and is used for collecting the unpacked particles; and a second-stage particle collecting means 13 which is arranged between the particle group packing tank and the first-stage particle collecting means and used for separating a gas from the unpacked particles by a cyclone system. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an information display panel manufacturing apparatus for manufacturing an information display panel that displays information by driving a particle group as a display medium. More specifically, it has a structure for collecting particles that are not stored in the cell after the particle group filling step of filling the cell group on the panel substrate with the particle group disposed in the panel substrate facing space of the information display panel. The present invention relates to an apparatus for manufacturing an information display panel.

  A liquid crystal display (LCD) is widely used as an information display device. However, it is generally known that liquid crystal display devices have drawbacks such as large power consumption and narrow viewing angle. Therefore, as an alternative to the liquid crystal display device, a plurality of cells partitioned by partition walls are formed between two substrates (for example, glass substrates) at least one of which is transparent, and a display medium configured as a particle group in the cells is provided. There is a proposal for an information display panel that encloses and moves the display medium (particle group) to display information such as an image.

  For example, Patent Document 1 discloses a predetermined position when a particle group is filled in a plurality of cells partitioned by a partition wall on a substrate in the particle group filling step when manufacturing the information display panel as described above. The state of filling the particle group using a mask (particle group filling mask) having an opening formed therein is disclosed. In this particle group filling step, the particle group discharged from the nozzle installed above falls on the mother substrate. A plurality of information display screen areas (12 in FIGS. 4 and 5 of Patent Document 1) corresponding to a plurality of information display panels are set on the mother panel substrate. There are many. In the mask shown here, an opening is formed at a location corresponding to the information display screen area. Therefore, when a particle group filling mask is set at a predetermined position on the panel substrate and particles are ejected from the nozzle as described above, the dropped particle group passes through the opening of the mask and enters the cells in the cell on the substrate. Groups can be filled.

JP 2005-258240 A

However, when the particle group filling mask is set on the mother panel substrate as described above and the particle group is dropped from above, the particles are deposited on the region other than the mask opening (that is, the mask portion). . If the particles adhering to the mask without being used for filling are left as they are, they will drop and contaminate the peripheral part when the particle group filling mask is moved after the particle group filling step. For example, if unnecessary particles are mixed in a cell in which a predetermined particle group filling is completed, it causes a display defect. Therefore, an appropriate recovery process is desired for the particles that have adhered to the particle group filling mask and have not been filled, but there is no appropriate proposal for this.
Further, it is desired from the viewpoint of utilization efficiency that particles that have adhered to the mask and have not been filled are collected and reused. However, there has been no proposal for reuse of the collected particles.

Therefore, a first object of the present invention is to use a particle group filling mask to manufacture an information display panel that displays information by filling the particle group and using the particle group as a display medium. Proposes an apparatus for manufacturing an information display panel equipped with a particle recovery device that appropriately recovers and processes particles remaining on a particle group filling mask without being charged after the particle group filling step That is.
Furthermore, it is a second object of the present invention to propose an apparatus for manufacturing an information display panel that is also equipped with a particle regeneration processing device that regenerates the recovered unfilled particles so that they can be reused.

The first object is to form a plurality of cells partitioned by a partition wall in a space where two substrates, at least one of which is transparent, face each other, enclose a group of particles as a display medium in the cell, and An apparatus for manufacturing an information display panel for displaying information by moving a group,
A particle group filling mask for performing a particle group filling step of disposing the particle group filling mask on the substrate and dropping the particle group from above to fill the cell with the particle group; It further comprises a particle recovery device that sucks and recovers particles that have adhered to the particle group filling mask after the filling step and have not been filled;
The particle recovery device includes a first-stage particle collection unit that incorporates a filter and collects the unfilled particles, and the particle group filling tank and the first-stage particle collection unit. This can be achieved by an apparatus for manufacturing an information display panel, comprising a second stage particle collecting means for separating gas and the unfilled particles by a cyclone method.

  The first-stage particle collecting means may be a blower unit in which the filter is built in multiple stages.

  In addition to the information display panel manufacturing apparatus, a second object of the present invention is a particle storage container for storing recovered unfilled particles downstream of the second stage particle collecting means. It is desirable that the particle storage container is connected to a particle group supply device that supplies the particle group to the particle group filling tank when the particle group filling step is executed.

  Further, it is further desirable that a particle regeneration processing device for regenerating the recovered unfilled particles into standard particles that can be filled is disposed between the particle storage container and the particle group supply device. .

  According to the present invention, there is provided a particle recovery device including a first-stage particle collection means and a second-stage particle collection means for collecting unfilled particles, and in particular, a second-stage particle collection means. Since the means separates the gas and the unfilled particles by the cyclone method between the particle group filling tank and the first stage particle collection means, the unfilled particles are collected while being reliably collected. The unfilled particles can be easily separated and recovered. This not only reliably removes unfilled particles in the particle group filling tank and prevents contamination to the surrounding area, but also promotes the reuse (recycling) of the particle groups to protect the environment protection and information display panel. Cost reduction can be achieved.

In addition, in connection with the present invention, the manufacture of an information display panel in which particle recovery devices for particle recovery are arranged in a single stage with the main objective of reliably recovering unfilled particles that cause problems as described above. It was also assumed to be a device. This point will be described with reference to the drawings.
FIG. 5 is a diagram schematically illustrating an assumption example in the case where a manufacturing apparatus 100 for manufacturing an information display panel is provided with a particle recovery apparatus. FIG. 5 shows a state in which the unfilled particles NP deposited on the particle group filling mask MS are recovered by the blower unit BU serving as a particle recovery device. The blower unit BU is provided with a suction pump (not shown), and a suction pipe PL extends from the blower unit BU. The head portion HD at the tip of the blower unit BU adheres to the particle group filling mask MS. The unfilled particles NP are arranged to be sucked.

  The unfilled particles NP sucked by the head part HD are collected in the blower unit BU through the pipe PL. For example, in the blower unit BU, a pre-filter PF that suppresses the collection efficiency in the first stage and a second-stage hepa filter HEPA that increases the collection efficiency are arranged, and the gas that has passed through both filters (here, The air is recirculated around the head portion HD via the return pipe BP. Such an information display panel manufacturing apparatus can recover and remove the particles PA which have adhered to the particle group filling mask MS and have not been filled, so that the unfilled particles fall to the periphery and become contaminated. The problem to do is solved.

  However, the present inventor has confirmed that there are still various points to be improved even in the information display panel manufacturing apparatus having the particle recovery function shown in FIG. For example, if the prefilter PF arranged in the blower unit BU has a large amount of unfilled particles NP to be collected, clogging occurs in a short period of time. In order to cope with this, it is necessary to frequently clean the inside of the blower unit, and it is also necessary to replace the prefilter PF periodically. Therefore, the manufacturing apparatus shown in FIG. 5 has a large work load for maintenance, and it is necessary to replace the filter. Therefore, it has been found that there are points to be improved in terms of manufacturing efficiency and manufacturing cost.

Further, from the viewpoint of environmental protection, it is desirable to use the recovered unfilled particles for cell filling, but the manufacturing apparatus of FIG. 5 does not consider such points. Generally, a filter used for dust collection or the like is formed of a nonwoven fabric, glass fiber, or the like, and consideration is given to reliably collecting particles, and it is assumed that a once clogged filter is discarded or replaced. Therefore, it is not easy to separate and collect the particles collected by the filter. Further, when different types of particles (for example, black particles and white particles) are filled in the manufacturing apparatus of FIG. 5, the different types of particles are captured by the filter. In this case, even if the particles can be separated from the filter, they must be discarded. There is also an improvement in the reuse of the unfilled particles thus recovered.
The present invention has been made in consideration of not only the above-mentioned conventional problems but also the improvements pointed out here.

(A), (b) is the figure shown in order to demonstrate the principle structure of the information display panel of the charged particle movement system which is an example of the information display panel produced with the manufacturing method of this invention. (A), (b) is the figure shown in order to demonstrate the other principle structure of the information display panel of the charged particle movement system used as an example of the information display panel produced with the manufacturing method of this invention. It is the schematic block diagram which showed the characteristic structure of the manufacturing apparatus of the information display panel which concerns on this invention. It is the block block diagram shown about the case where a preferable structure is further applied to the manufacturing apparatus of the information display panel of FIG. It is the figure which showed typically the assumption example at the time of providing the particle | grain recovery apparatus about the manufacturing apparatus for manufacturing the panel for information displays.

  Hereinafter, an information display panel manufacturing apparatus according to an embodiment of the present invention will be described with reference to the drawings. Here, in order to facilitate understanding of the present invention, as an example, an information display panel of a charged particle moving system that displays particles and the like by moving the particle group using the particle group including the chargeable particle as a display medium. First, the schematic configuration will be described.

  In the charged particle movement type information display panel, an electric field is applied to a display medium configured as a particle group including charged particles sealed in a space between two opposing substrates. Along with the applied electric field direction, the particle group serving as the display medium is attracted by the force of the electric field or the Coulomb force, and the particle group moves by the change in the electric field direction, thereby displaying information such as an image. Therefore, it is necessary to design an information display panel so that the particle group can move uniformly and maintain the stability when the display information is rewritten repeatedly or when the display information is continuously displayed. Here, the force applied to the particles constituting the display medium may be a force due to an electric field, a force attracting each other by a Coulomb force between particles, an electric mirror image force between an electrode and a substrate, an intermolecular force, a liquid crosslinking force, gravity, and the like. .

An example of the information display panel will be described with reference to FIGS. 1 (a) and 1 (b) and FIGS. 2 (a) and 2 (b).
The examples shown in FIGS. 1A and 1B show at least two types of display media having different optical reflectance and charging characteristics, which are configured as a particle group including particles having at least optical reflectance and charging properties. (Shown here is a white display medium 3W configured as a particle group including negatively charged white particles 3Wa and a black display medium 3B configured as a particle group including positively charged black particles 3Ba). In each cell, according to the electric field generated by applying a voltage to the electrode pair formed by the electrode 5 (pixel electrode with TFT) provided on the substrate 1 and the electrode 6 (common electrode) provided on the substrate 2, Move perpendicular to the substrates 1 and 2. Then, the white display medium 3W is visually recognized by the observer as shown in FIG. 1A, or the black display medium 3B is visually recognized by the observer as shown in FIG. 1B. To do. Here, an example is shown in which a black and white dot matrix display is performed by arranging electrode pairs (1 dot) in a matrix.
In addition, in FIG. 1 (a), (b), the partition in front is abbreviate | omitted. The electrodes 5 and 6 may be provided outside the substrates 1 and 2, inside the substrate, or embedded in the substrate. Although an example in which a pixel (dot) and a cell are associated with each other on a one-to-one basis is shown, the pixel and the cell may not be associated with each other.

Further, in the example shown in FIGS. 2A and 2B, at least two types having different optical reflectivity and charging characteristics are configured as a particle group including particles having at least optical reflectivity and chargeability. The display medium (here, the white display medium 3W configured as a particle group including the negatively charged white particles 3Wa and the black display medium 3B configured as a particle group including the positively charged black particles 3Ba) is shown by the partition walls 4. In each of the formed cells, a voltage is applied between a pair of pixel electrodes formed by the electrode 5 (line electrode) provided on the substrate 1 and the electrode 6 (line electrode) provided on the substrate 2 crossing each other at right angles. Is moved perpendicularly to the substrates 1 and 2 in accordance with the electric field generated by. Then, the white display medium 3W is visually recognized by the observer as shown in FIG. 2A, or the black display medium 3B is visually recognized by the observer as shown in FIG. 2B. To do. Here, an example is shown in which a pair of electrodes (1 dot) is arranged in a matrix and black and white dot matrix display is performed.
In FIGS. 2A and 2B, the front partition is omitted. The electrodes 5 and 6 may be provided outside the substrates 1 and 2, inside the substrate, or embedded in the substrate. Although an example in which a pixel (dot) and a cell are associated with each other on a one-to-one basis is shown, the pixel and the cell may not be associated with each other.

  In addition, as said board | substrates 1 and 2, substrates, such as a glass substrate, a resin sheet board | substrate, and a resin film board | substrate, can be used. The substrate 2 on the display surface side (observation side) is a transparent substrate. When an electrode for applying a voltage having a predetermined voltage and polarity (positive / negative) (common electrode or line electrode 5 described in FIG. 1 or the like) is disposed in the information display screen area of the substrate 2 Is a transparent electrode. On the surface of the substrate 1 constituting the information display panel shown in FIGS. 1 and 2, pixel electrodes or line electrodes with thin film transistors (TFTs) are formed so as to form matrix electrode pairs. When a voltage is applied to the counter electrode pair, the above-described structure in which a desired display is performed by moving by applying an electric field to the display medium (particle group) can be realized.

Hereinafter, an apparatus for manufacturing an information display panel according to the present invention will be described with reference to the drawings.
FIG. 3 is a schematic configuration diagram showing a characteristic configuration of the information display panel manufacturing apparatus according to the present invention. As shown in FIG. 3, the information display panel manufacturing apparatus 10 according to the present invention includes a blower unit 12 as a first-stage particle collecting unit that incorporates a filter and collects the unfilled particles. In addition, a cyclone separation device 13 is included as a second stage particle collecting means for separating gas and unfilled particles between the particle group filling tank 14 and the blower unit 12 by a cyclone method.
As described above, the information display panel manufacturing apparatus 10 according to the present invention collects the particles NP that are discharged into the particle group filling tank 14 but are not filled into the cells but are attached to the particle group filling mask MS. And a cyclone separator 13 including a blower unit 12 and a cyclone separator 13. In particular, the cyclone separator 13 serving as a second stage particle collecting means is a gas between the particle group filling tank 14 and the blower unit 12. Since the unfilled particles NP are separated by the cyclone method, the collected unfilled particles can be easily separated and recovered while reliably collecting the unfilled particles.

  The cyclone separator 13 may be appropriately selected from conventional ones and disposed upstream of the blower unit 12. The blower unit 12 is provided with a pump (not shown) that generates a suction force (negative pressure) for sucking the unfilled particles NP. For example, this suction force is also connected to the upstream cyclone separator 13. The cyclone separator 13 includes a cylindrical chamber that serves as a centrifugal centrifuge. Such a cyclone separation device 13 is based on centrifugal force in the chamber, for example, when gas (gas in the particle group filling tank 14 such as air containing unfilled particles NP) flows in from the inlet in the tangential direction of the chamber. A differential pressure is generated, and the particles NP that have not been filled in the inner wall are separated and collected in a recovery container provided in the lower part. On the other hand, since the purified gas obtained by shaking off the unfilled particles NP flows out from the central portion to the downstream blower unit 12, the unfilled particles NP reaching the blower unit 12 side is extremely small. .

In FIG. 3, in the blower unit 12, as described in FIG. 5, for example, a pre-filter PF with reduced collection efficiency at the first stage and a second-stage hepa filter HEPA with increased collection efficiency are provided. Deploy. Further, the air that has passed through both the filters is circulated in the particle group filling tank 14 via the return pipe BP-1. If no recirculation is required, exhaust through pipe BP-2.
As described above, the information display panel manufacturing apparatus 10 shown in FIG. 3 includes the blower unit 12 serving as the first-stage particle collecting means and the cyclone separator 13 serving as the second-stage particle collecting means. In particular, the cyclone separator 13 separates the gas and the unfilled particles between the particle group filling tank 14 and the blower unit 12 in a cyclone method without using a filter. The collected particles NP that have not been packed can be separated and recovered and reused while reliably collecting the particles NP that have not been collected.

An embodiment in which an information display panel is manufactured using the information display panel manufacturing apparatus 10 of FIG. 3 described above will be described. In addition, the case where the information display panel was manufactured using the manufacturing apparatus 100 shown in FIG. 5 was used as a comparative example.
As an example and a comparative example, the results of producing the same amount of information display panel for 5 days are summarized in Table 1 below.

As shown in Table 1 above, in the case of the embodiment, it is possible to collect the particles NP that have not been filled up to 3 kg in the collection container 13a under the cyclone separator 13, and the filter of the blower unit 12 (blower) downstream thereof There was a slight amount of particles adhering to. Therefore, it is not necessary to frequently clean the filter in the blower unit 12, and the man-hours for cleaning the filter are greatly reduced.
On the other hand, in the case of the comparative example, particles NP that was not filled as much as 2.5 kg was collected in the filter of the blower unit 12, and it was necessary to frequently clean the filter to remove it. To clean the filter, remove the panel and piping of the blower unit housing, open the filter box cover, take out the filter, and clean the filter and box. After that, it was necessary to attach filters and filter box lids, and to install piping and casing panels, which required enormous cleaning steps.
On the other hand, in the case of the cyclone separation device 13, the clamp of the lower recovery container 13a is removed, the recovery container is taken out, the unfilled particles NP are poured into an external predetermined particle storage container, and the recovery container is fixed with an attachment clamp. Even with this work, it took only a few cleaning steps. In addition, the flow of particles from the collection container 13a into the particle storage container can be easily automated.

FIG. 4 is a block configuration diagram showing a case where a preferable configuration is further applied to the information display panel manufacturing apparatus 10 of FIG. A particle storage container 16 for storing the separated unfilled particles NP is connected to the recovery container 13a arranged at the lower part of the cyclone separator 13. The particle storage container 16 is connected to a particle group supply device 15 that supplies a particle group for filling to the particle group filling tank 14 described above via a transfer device 17. In this way, the unpacked particles NP separated and recovered by the cyclone separation device 13 can be recycled in the particle group filling tank 14 to reliably separate the unfilled particles NP, which has been a problem in the past. In addition, it is possible to construct a circulation supply system that reuses the collected particles.
Moreover, since the particle group is expensive, even if the number of steps in Table 1 is added, the merit of collecting the particle group is greater.

The transfer device 17 positioned between the particle storage container 16 and the particle group supply device 15 is a transfer device including a flow path switching and a mixing function for returning the recovered unfilled particles NP. . In addition, when the recovered unfilled particles NP need to be regenerated between the particle storage container 16 and the transfer device 17, the necessary processing is performed to regenerate standard particles that can be filled. If the particle regeneration processing device 18 is arranged so that it can be returned to the particle group supply device 15 after being processed, the second object of the present invention can be achieved. In this way, if the particle regeneration processing device 18 is provided, the unpacked particles NP separated and recovered can be more reliably regenerated into reusable particles.
In FIG. 4, reference numeral 19 denotes a new particle group supply device, which mixes a new particle group and a particle group obtained by reprocessing the collected particle group in a desired ratio by a mixing function provided by the transfer device 17. The regenerated particles stored in the storage tank 20 of the regenerated particle group, the new particles from the new particle supply device 19, and the recovered particles from the particle storage container 16 are sent to the transfer device 17 at a desired ratio by a screw feeder or the like. The ratio of the delivery amount can be arbitrarily changed by setting a screw feeder or the like.

  According to the information display panel manufacturing apparatus of the present invention described above, not only the unfilled particles NP in the particle filling tank can be surely sucked to prevent contamination to the surroundings, but also can be filled without using a filter. Since the particles NP that have not been collected are collected so as to be separated and recovered, the frequency of cleaning can be greatly reduced. For example, the filter cleaning frequency in the blower unit 12 downstream of the cyclone separator 13 can be reduced to 0.2 in the case of the embodiment, assuming that the case of the comparative example is 1. And since a particle group can be collect | recovered and reused, it can provide as a manufacturing apparatus which contributes also to the manufacturing cost reduction of the information display panel.

  Information display panels subject to the present invention include notebook computers, electronic notebooks, portable information devices called PDA (Personal Digital Assistants), display units of mobile devices such as mobile phones and handy terminals, electronic books, electronic newspapers, etc. Electronic paper, signboards, posters, bulletin boards such as blackboards (whiteboards), electronic desk calculators, display units for home appliances, automotive supplies, card display units such as point cards, IC cards, electronic advertisements, information boards, electronic POPs (Point Of Presence, Point Of Purchase advertising), electronic price tag, electronic shelf label, electronic score, display part of RF-ID equipment, as well as display part of various electronic equipment such as POS terminal, car navigation device, clock In addition to being used, an information display panel (rewritable paper) or external electric field forming means for rewriting display by connecting to external rewriting means is used. It is also suitably used as an information display panel (rewritable paper) for rewriting display.

  The display medium used for the information display panel which is the subject of the present invention is electrically drivable, such as a particle group containing charged particles, a particle group containing conductive particles, or a particle group containing semiconductive particles. A particle group containing particles, and the production apparatus of the present invention is suitable for filling these particle groups. As for the driving method of the information display panel which is the subject of the present invention, a simple matrix driving method and a static driving method which do not use a switching element in the panel itself, a three-terminal switching device represented by a thin film transistor (TFT) or a thin film diode Various types of driving methods such as an active matrix driving method using a two-terminal switching element represented by (TFD) and a driving method using an external electric field forming means can be applied.

1, 2 Substrate 3W, 3B Display medium (particle group)
10, 100 Information display panel manufacturing apparatus 12 Blower unit (first-stage particle collecting means)
13 Cyclone Separator (second stage particle collecting means)
14 Particle group filling tank MS Particle group filling mask

Claims (4)

A plurality of cells partitioned by partition walls are formed in a space where at least two transparent substrates are opposed to each other, and a particle group as a display medium is enclosed in the cell, and the particle group is moved to transfer information. An apparatus for manufacturing an information display panel to be displayed,
A particle group filling mask for performing a particle group filling step of disposing the particle group filling mask on the substrate and dropping the particle group from above to fill the cell with the particle group; It further comprises a particle recovery device that sucks and recovers particles that have adhered to the particle group filling mask after the group filling step and have not been filled,
The particle recovery device includes a first-stage particle collection unit that incorporates a filter and collects the unfilled particles, and the particle group filling tank and the first-stage particle collection unit. An apparatus for manufacturing an information display panel, comprising: second-stage particle collecting means for separating a gas and the unfilled particles by a cyclone method. 2. The apparatus for manufacturing an information display panel according to claim 1, wherein the first stage particle collecting means is a blower unit including the filter in multiple stages. A particle storage container for storing the recovered unfilled particles is disposed downstream of the second stage particle collecting means, and the particle storage container is configured to store the particle group when performing the particle group filling step. The apparatus for manufacturing an information display panel according to claim 1, wherein the apparatus is connected to a particle group supply device that supplies the particle group to the particle group filling tank. Between the particle storage container and the particle group supply device, there is further provided a particle regeneration processing device for regenerating the recovered unfilled particles into standard particles that can be filled. The apparatus for manufacturing an information display panel according to claim 3.