SE526853C2 - LCD on flexible substrate - Google Patents

Abstract

The present invention relates to a liquid crystal display on a flexible substrate adapted to work in reflective mode. The LCD comprises a paper based flexible back substrate (1). The surface of the back substrate (1) is coated with a polymeric coating (1a) providing a required surface roughness.

Description

526 853 2 Paper substrates are also a good alternative to polymers, as demands for more environmentally friendly solutions become greater, in this respect paper is almost ideal.

When using paper as a substrate in the manufacture of LCDs, there are several problems that must be solved.

A paper surface is much coarser than a plastic or glass surface. ITO that is normally used is difficult to use as an electrode on paper. The diffusion of water and oxygen is high in paper due to its perneability. It is difficult to apply an internal thin film polarizer to a paper substrate. It is also difficult to use polyimide as the LC-alignment layer on paper substrates.

To solve one or more of the above-identified problems from the standpoint of an LCD on a flexible substrate designed to operate in a reactive mode, including a flexible backing substrate, the present invention teaches the use of a paper-based backing substrate where the backing surface is coated with a polymer layer. which provides the desired surface smoothness.

In order to obtain the desired surface roughness, it is proposed that the polymer layer be designed so as to give a surface roughness which is less than 5 μm.

To overcome the problems of diffusion through paper-based substrates, the present invention teaches that the polymer layer is designed to prevent liquid crystal from diffusing into the paper-based backing substrate and to avoid contamination from diffusing into the liquid crystal.

Different types of electrodes can be used in an LCD according to this invention.

The LCD may, for example, contain organic electrodes, such as electrodes made of poly (3,4-ethylenedioxythiophene) doped with poly (4-styrenesylfonate) (PEDOT-PSS). The LCD may also contain inorganic electrodes, such as ITO.

The rear electrode can consist of active electrical circuits or be designed for passive electric drive.

The polarizer of an inventive LCD can be designed in different ways.

One possible solution teaches that the LCD consists of a front polarizer and a deceleration film.

This front polarizer can be an external polarizer consisting of a thin film polarizer or a conventional plastic film polarizer.

The front polarizer can also be an internal polarizer, consisting of a second thin film polarizer. In this case, the LCD may consist of a separate LC alignment layer in combination with a second thin film polarizer; It is also possible to make the front LC alignment layer of a second thin film polarizer.

According to another design, the present invention teaches that the LCD consists of a combination of a front and rear polarizer.

Different combinations of front polarizers made of an external or internal polarizer are possible. An external front polarizer can be made of a third thin film polarizer or a conventional plastic film polarizer. An internal polarizer may be made of a fourth thin film polarizer. In the latter design, it is possible to combine a separate front LC alignment layer with a fourth thin film polarizer. It is also possible to make the front LC alignment layer of a fourth thin film polarizer.

The present invention teaches that the back polarizer may be made of a fifth thin film polarizer. According to this design, it is possible to combine a separate rear LC alignment layer with a fifth thin film polarizer. It is also possible to make behind the LC alignment layer a fifth thin film polarizer.

To overcome the problem of contaminating the LC from the thin film polarizer used as the LC alignment screen, the present invention teaches that a first thin protective polymer layer is positioned between the front polarizer and the LC associated with the LCD, and that a second thin protective polymer layer is positioned between the back polarizer and the LC.

To overcome the problem of combining an organic electrode with a thin film polarizer, where the thin film polarizer can dissolve slightly when applied to an organic electrode, the present invention teaches that a third thin protective polymer layer is positioned between the baking electrode and the back polarizer, and that a fourth thin protective polymer layers are placed between the front electrode and the front polarizer in designs where the organic electrode is combined with a thin film polarizer.

When separate LC alignment layers are used, the present invention teaches that these may be made of UV-curing or heat-curing polymers.

It is also proposed that the electrodes can be divided into separate electrically controllable segments.

An inventive LCD can use an LC designed to operate in the nematic phase, smectic phase, or in the cholesterol phase, where the latter design does not require a polarizer. The mentioned LC phases can be of 30 ffl in) 3 \ CO (Ti CN 4 the following types: low molecular weight LC, polymer stabilized LC, polymer dispersed LC (PDLC) or polymer LC.

It is also possible to use a free surface LC-lm as LC in an inventive LCD. Such a design does not require a front substrate or front electrode, although a front electrode may be used.

A free surface LC film can be designed for ln-plain switching (IPS).

It is also taught that a protective film can be applied to the free surface LC film.

Different types of front substrate can be used in an LCD according to the invention. One design teaches that the front substrate is made of a polymeric film such as PET, PES, PC, polycyclic olefin or polyarylate. Another possible design is a front substrate made of glass.

Advantages The advantages of an LCD according to the present invention are that such an LCD is possible to manufacture in high volumes and very cost-effectively. It will thus be possible to have LCDs on, for example, disposable products, such as packaging. It will also be easier to make an LCD as an integral part of a product.

Brief description of drawings.

An LCD according to the present invention will now be described in detail with reference to the accompanying drawings, in which: Figure 1 is a schematic and simplified cross-section of an LCD according to the present invention, Figures 2 to 6 are schematic illustrations of different designs of how to realizes a polarization combination with different LC alignment layers, Figure 7 is a schematic cross-section of different protective layers, Figure 8 is a schematic cross-section of an LCD designed to operate in cholesteric phase, and Figure 9 is a schematic cross-section of an LCD with a free surface LC- fi lm. Description of Preferred Embodiments The present invention will be described with reference to Figure 1, which shows an LCD on a flexible substrate designed to operate in the reactive mode.

The LCD contains a paper-based flexible backing substrate 1, and the surface of the backing substrate 1 is covered with a polymer film * 1a which contributes to the required surface smoothness. The polymer film 1a is most advantageously constructed so as to give a surface roughness which is finer than 5 μm.

The polymer film 1a is designed to prevent LC 2 from diffusing into the paper-based backing substrate 1. The polymer film 1a is also designed to prevent contamination from diffusing into the LC 2.

According to an advanced design, the LCD contains a baking electrode 3 which is organic, such as a baking electrode made of poly (3,4-ethylenedioxythiophene) doped with poly (4-styrenesulfonate) (PEDOT-PSS). It is also possible to have a baking electrode 3 which is inorganic, such as a baking electrode made of ITO.

The rear electrode 3 may consist of active electrical circuits, or it may be designed for passive electrical driving.

An inventive LCD also consists of a front electrode 4. It may be organic, such as front electrode 4 consisting of poly (3,4-ethylenedioxythiophene) doped with poly (4-styrene sulfonate) (PEDOT-PSS), or inorganic example a front electrode 4 made by lTO.

Figure 1 also shows a separate front LC alignment layer 6a and a separate rear LC alignment layer 6b.

Various embodiments of polarizers will now be described. A first design is shown in Figure 2, an LCD containing a front polarizer 5a with deceleration film 51. It should be understood that no back polarizer is required in any design with a front polarizer and a deceleration film.

The figure shows an external front polarizer 5a. This external front polarizer 5a may be made of a first thin film polarizer or a conventional plastic film polarizer. Figure 2 also shows a separate front LC alignment layer 6a.

Figure 3 shows a front polarizer made of an internal polarizer 5b. This internal front polarizer 5b can also be made of a thin film polarizer, a second thin film polarizer. Figure 3 shows a separate front LC alignment layer 6a in combination with a second thin film polarizer 5b. The present invention teaches that it is possible to make a front LC alignment layer 6a of the second thin film polarizer 5b, according to Figure 4.

It should be clarified that several different standards behind LC alignment layers 6b can be used in designs where no back polarizer is required, as for example in the embodiments described in Figures 2, 3 and 4.

Figure 5 shows another design of a polarizer where the LCD consists of a combination of a front polarizer 5c and a rear polarizer 5d.

Here it is shown that the front polarizer 5c is made of an external polarizer 5c.

The external polarizer 5c may be made of third thin film polarizer or of a conventional type of polarizer.

Figure 6 shows a design where the front polarizer is made of an internal polarizer 5e. The internal polarizer 5e may also be made of a thin film polarizer, a fourth thin film polarizer. Figure 6 shows a separate front LC alignment layer 6a in combination with the fourth thin film polarizer 5e.

Figure 7 shows that it is also possible to make the front LC alignment layer 6a of the fourth thin film polarizer 5e.

Figures 5 and 6 show a design where the back polarizer 5d is made of a fifth thin film polarizer. These visar gures show a separate rear LC alignment layer 6b in combination with a fifth thin film polarizer 5d.

Figure 7 shows that it is possible to make behind the LC alignment layer 6a of a fifth thin film polarizer 5d.

In the designs where an LC alignment layer is made of a thin film polarizer, it is proposed that a protective layer be placed between the thin film polarizer and the LC in the LCD.

This is exemplified in Figure 7 which shows a first thin protective polymer layer 7a placed between the front polarizer 5e and the LCn 2, and a second thin protective polymer layer 7b placed between the back polarizer 5d and the LCn 2.

It is also preferable to have protective layers between the organic electrodes and thin film polarizers. This is exemplified in Figure 5 which shows a third thin protective polymer layer 7c placed between the baking electrode 3 and the baking polarizer 5d. It should be made clear that this protective layer is only required if the baking electrode 3 is organic. 526.: ». F ~» 3 7 Figure 6 shows a fourth thin protective polymer layer 7d placed between the front electrode 4 and the front polarizer 5e. It should be made clear that this protective layer is only required if the baking electrode 4 is organic.

The protective layers 7a, 7b, 7c, 7d are only illustrated in Figures 5, 6 and 7, it should in any case be made clear that these protective layers can also be used in other designs to prevent direct contact between the thin film polarizer and the LC or the organic electrode. .

The present invention teaches that in designs with a separate front LC alignment layer 6a, and a separate rear LC alignment layer 6b, these LC alignment layers may consist of UV curing or thermosetting polymers.

The current invention also teaches that the rear electrode 3 and / or the front electrode 4 are divided into separate electrically controllable segments.

An LC 2 in an LCD according to the present invention can be designed to operate in the nematic phase or smectic phase, where the LC phases can be of the following types; low molecular weight LC, polymer stabilized LC, polymer dispersed LC (PDLC) or polymer LC.

Figure 8 shows a design where the LC 21 is designed to function in its cholesteric phase. Such an LCD requires no polarization. Thus, it comprises a front LC alignment layer 6a and a rear LC alignment layer 6b, such as LC alignment layer consisting of UV-curing or thermosetting polymers, a baking electrode 3 and a front electrode 4.

A proposed design teaches that the LCD is designed for bistable mode.

Figure 9 shows a design where the LC 22 consists of a free surface LC-m ch. In this design, it is proposed that the LCD comprise a protective film 8 placed on the free surface LC film. This LCD can be designed for in-plain switching. Due to the nature of the free surface LC film, an LCD according to this design need not have a front substrate or a front electrode, a rear electrode 3 can be seen in the fi clock. However, a front electrode can be used.

However, polarization can be realized by using all the embodiments described above even if no polarizer is shown in the clock. Figure 1 shows that an LCD according to the present invention comprises a front substrate 9 made of a polymeric film, such as polymeric films made of PET, PES, PC, polycyclic olefin or polyarylate.

It is also possible to use front substrates 9 made of glass. 526 853 s For simplicity, this front substrate 9 is shown only in Figure 1, although it is obvious that other designs, illustrated in other figures, may also include a front substrate.

The present invention provides opportunities to present permanent information through an LCD in a very simple manner. According to a design, the backing substrate 1 comprises a printed pattern, for example an image or a topographical pattern.

It should be mentioned that the invention is not limited to the previously mentioned and illustrated examples of embodiments thereof and that modifications may be made within the scope of the inventive concept as illustrated in the appended claims.

Claims (57)

20 25 30 PATENT REQUIREMENTS An LCD (liquid crystal display) on a flexible substrate designed to operate in a reactive mode, comprising a flexible backing substrate, characterized in that said backing substrate is paper-based, and that the surface of said backing substrate is coated with a polymer layer which contributes to the required surface roughness. . An LCD according to Claim 1, characterized in that said polymer layer is designed to give a surface roughness of less than 5 μm. An LCD according to Claim 2, characterized in that said polymer layer is designed to prevent LC associated with said LCD from diffusing into said paper-based backing substrate. An LCD according to Claim 3, characterized in that said polymer layer is designed to prevent contamination from diffusing into said LC. An LCD according to any one of the preceding Claims, characterized in that said LCD comprises an organic baking electrode. An LCD according to Claim 5, characterized in that said baking electrode is made of poly (3,4-ethylenedioxythiophene) doped with poly (4-styrenesylfonate) (PEDOT-PSS). An LCD according to any one of Claims 1 to 4, characterized in that said LCD comprises an inorganic baking electrode. An LCD according to Claim 7, characterized in that said baking electrode consists of ITO. An LCD according to any one of Claims 5 to 8, characterized in that said baking electrode comprises active electrical circuits. An LCD according to any one of Claims 5 to 8, characterized in that said baking electrode is designed for passive electric drive. 20 30 CT! l ~ J \ _ '; i \ * CO f. fl CN 11. 1 1. The LCD comprises an organic front electrode. An LCD according to any one of the preceding claims, characterized in that said An LCD according to Claim 11, characterized in that said front electrode is made of poly (3,4-ethylenedioxythiophene) doped with poly (4-styrenesulfonate) (PEDOT-PSS). An LCD according to any one of Claims 1 to 10, characterized in that said LCD comprises an inorganic front electrode. An LCD according to Claim 13, characterized in that said front electrode is made of ITO. An LCD according to any one of the preceding claims, characterized in that said LCD comprises a front polarizer with a deceleration film. An LCD according to Claim 15, characterized in that said front polarizer is made of an external polarizer. An LCD according to Claim 16, characterized in that said external polarizer is made of a first thin film polarizer. An LCD according to Claim 16, characterized in that said external polarizer is made of a conventional plastic film type. An LCD according to Claim 15, characterized in that said front polarizer is made of an internal polarizer. An LCD according to Claim 19, characterized in that said internal polarizer is made of a second thin film polarizer. 20 25 30 (31 26 OO (TI (Ai 11 An LCD according to Claim 20, characterized in that said LCD comprises a separate front LC alignment layer in combination with said second thin film polarizer. An LCD according to Claim 20, characterized in that said LCD comprises a front LC alignment layer, and that said front LC alignment layer consists of said second thin film polarizer. An LCD according to any one of Claims 1 to 14, characterized in that said LCD comprises a combination of a front and a rear polarizer. An LCD according to Claim 23, characterized in that said front polarizer consists of an extreme polarizer. An LCD according to Claim 24, characterized by said external polarizer is made of a third thin film polarizer. An LCD according to Claim 24, characterized in that said extreme polarizer is made of conventional plastic film type. An LCD according to Claim 23, characterized by said front polarizer consisting of an internal polarizer. An LCD according to Claim 27, characterized in that said internal polarizer is made of a fourth thin film polarizer. An LCD according to Claim 28, characterized in that said LCD comprises a separate front LC alignment layer in combination with said fourth thin film polarizer. An LCD according to Claim 28, characterized in that said LCD comprises a front LC alignment layer, and in that said front LC alignment layer consists of said fourth thin film polarizer. 20 30 26 85 12 (II QN An LCD according to any one of Claims 23 to 30, characterized in that said back polarizer is made of a fifth thin film polarizer. An LCD according to Claim 31, characterized in that said LCD comprises a separate rear LC alignment layer in combination with said fifth thin film polarizer. An LCD according to Claim 31, characterized in that said LCD comprises a rear LC alignment layer, and in that said rear LC alignment layer consists of said fifth thin film polarizer. An LCD according to Claim 22 or 30, characterized in that a first thin protective polymer layer is placed between said front polarizer and the LC associated with said LCD. An LCD according to Claim 33, characterized in that a second thin protective polymer layer is placed between said back polarizer and the LC associated with said LCD. An LCD according to Claim 5 in combination with any one of Claims 31 to 33, characterized in that a third thin protective polymer layer is placed between said baking electrode and said baking polarizer. An LCD according to Claims 11 and 22 or Claims 11 and 30, characterized in that a fourth thin protective polymer layer is placed between said front electrode and said front polarizer. An LCD according to Claim 21 or 29, characterized in that said front LC alignment layer is made of a UV-curing or thermosetting polymer. An LCD according to Claim 32, characterized in that said rear LC alignment layer is made of a UV-curing or thermosetting polymer. 20 25 30 13 An LCD according to any one of Claims 5 to 39, characterized in that said baking electrode is divided into separate electrically controllable segments. An LCD according to any one of Claims 11 to 40, characterized in that said front electrode is divided into separate electrically controllable segments. An LCD according to any one of the preceding claims, characterized in that said LC is designed to function in its nematic phase. An LCD according to any one of Claims 1 to 41, characterized in that said LC is designed to operate in its smectic phase. An LCD according to any one of Claims 1 to 14, characterized in that said LC is designed to function in its cholesteric phase. An LCD according to Claim 44, characterized in that said LCD comprises a front and rear LC alignment layer. An LCD according to Claim 45, characterized in that said front and rear LC alignment layers consist of a UV-curing or thermosetting polymer. An LCD according to any one of the preceding claims, characterized in that said LCD is designed to operate in bistable mode. An LCD according to any one of Claims 42 to 44, characterized in that said LC phase may be of the following types; low molecular weight LC, polymer stabilized LC, polymer dispersed LC (PDLC) or polymer LC. An LCD according to any one of Claims 1 to 10, characterized in that said LC consists of a free surface LC-m lm. An LCD according to Claim 49, characterized in that said LCD comprises a protective layer placed on said free surface LC-1m. 20 526 85. » 14 An LCD according to Claim 49 or 50, characterized in that said LCD is designed for in-plain switching. An LCD according to Claim 51, characterized in that said LCD comprises a polarizer according to any one of Claims 15 to 36. An LCD according to Claim 52, characterized in that said LCD comprises front electrodes according to any one of claims 11 to 14 and 37. An LCD according to any one of Claims 1 to 48, characterized in that said LCD comprises a front substrate made of a polymer film. An LCD according to Claim 54, characterized in that said polymer film is made of PET, PES, PC, polycyclic olein or polyarylate. An LCD according to any one of Claims 1 to 48, characterized in that said LCD comprises a front substrate made of glass. An LCD according to any one of the preceding claims, characterized in that said backing substrate comprises a printed pattern, for example in the form of an image or a topographical pattern.