NL9101417A - DISPLAY DEVICE ASSEMBLY. - Google Patents

Description

Display device assembly.

This invention relates to display assemblies of the type containing a liquid crystal display of the type having two glass plates separated by a liquid crystal material, each glass plate carrying a respective electrode layer, and a planar fluorescent lamp which is formed by two glass plates separated by a gas discharge volume.

Conventional flat panel displays of this type usually have a flat liquid crystal display backlit, such as formed by various fluorescent tubular lamps, a reflector and diffuser. More recently, it has been proposed to use flat screen discharge lamps for backlighting. Examples of such lamps are described in: WO 90/09676, JP-A-5846568, EP-A-0283014, GB-A-2217905, WO 87/04562, JP-A-57180067, JP-A-59127357, GB- 9115185 and GB-9105626. These flat screen lamps have the advantage over tubular lamps that they provide more even illumination and are more robust and compact.

In many applications, it is desirable that the entire thickness of the display, that is, backlit, be as small as possible without reducing the robustness of the display. However, the amount by which the thickness of the display device can be reduced is limited by the thickness of the two glass plates that form the backlight and the two glass plates that form the display device. Any gap between the front plate of the backlight and the rear plate of the display can lead to multiple reflections that can reduce the legibility and level of illumination. Even when the front surface of the backlight is connected to the rear surface of the display device, these problems are not completely avoided since it is very difficult to completely remove all air bubbles between the two surfaces. Any difference in refractive index of the glass plates or the bonding material will also cause reflection at the boundary. The connection can also provide a place of weakness. In addition, since the glass plates forming the display and the backlight need to be strong enough to prevent damage during assembly, the total thickness of the two glass plates when joined together is greater than necessary.

It is an object of the present invention to provide a display device assembly which can be used to avoid these drawbacks.

According to the present invention, there is provided a display device assembly of the type mentioned in the preamble, characterized in that one of the glass plates of the lamp provides one of the glass plates of the liquid crystal display such that the liquid crystal display device is integrally formed with the lamp and such that activation of the lamp causes illumination of the liquid crystal display device.

Preferably, the fluorescent lamp is a cold cathode lamp and the liquid crystal display is a dichroic display. The lamp may have a series of pillars between the two plates of the lamp that support the plates. The glass plates can be made of sodium glass. The assembly may include a filter layer having regions of different color transmission properties, the filter layer being carried by the other plate of the display device and the regions of the filter layer aligned with individual electrodes of one of the electrode layers. The other of the glass plates of the lamp can carry a reflector on its external surface and can carry a polarizer between the other plate and the reflector.

The assembly may include a second liquid crystal display with two glass plates separated by a liquid crystal material, each glass plate of the second liquid crystal display carrying a respective electrode layer, and the other of the plates of the lamp provides one of the glass plates of the second liquid crystal display device so that the second liquid crystal display device is formed integrally with the lamp and such that activation of the lamp causes illumination of both liquid crystal display devices.

The assembly may include a sensor responsive to inversion of the assembly to cause a change in the information output from the display assembly.

Display device assemblies according to the present invention will now be described, by way of example, with reference to the accompanying drawings, in which: Figure 1 is a cross-sectional view of an embodiment of an assembly; figure 2 shows a cross-section of an alternative embodiment of an assembly; and Figures 3 and 4 are perspective views showing two further embodiments of an assembly.

Referring to Figure 1, the display assembly includes a backlight formed by a flat screen cold cathode fluorescent lamp 1, and a dichroic liquid crystal display (LCD) 2 above the lamp.

The lamp 1 is of the type as described in WO 90/09676 but can be any other flat panel fluorescent lamp. The lamp 1 contains two parallel flat plates 10 and 11 of soda-lime glass, each of which is provided on facing surfaces with a matrix series of rows and columns of supporting pillars in the form of truncated pyramids 12 so that the flat tops of corresponding pyramids on each plate contact each other and the plates are supported against inward deformation. Other forms of support between the two plates can be used. The two plates are joined together around their circumferences and the volume 5 between them is filled with a low pressure gas discharge mixture, depositing a phosphor layer 6 on the interior surfaces of the two plates. Two electrodes 13 and 14 extend along opposite sides within the gas discharge volume 5 in the lamp so that when the electrodes are activated discharge occurs which causes the generation of light from the phosphor layer 6. A polarizer 15 is mounted on the outer surface of the bottom plate 11; the polarizer may contain a retardation layer. An aluminum layer 16 is deposited on the bottom surface of the polarizer 15 to serve as a reflector.

The reflective layer can be either flat or profiled to increase the amount of light emitted from the pillars 12,

In addition to forming the top forward plate of the lamp 1, the plate 10 additionally provides the bottom rear plate of the LCD 2 and is, therefore, the intermediate plate of the assembly. Activation of the lamp 1 causes illumination of the LCD 2.

A matrix array of thin layer transistors or diode switches 20 is deposited directly on the top surface of the plate 10 to provide a layer of individual electrodes 21 on their top surface. A plurality of wires 22 extend to the rows and columns of the switches 20 so that the individual electrodes 21 can be addressed in the usual manner.

The upper surface of the electrodes 21 is covered with a lower alignment layer 23 of a polar organic material which is intended to rotate the molecules of a conventional liquid crystal material 24 which is in the only space between the intermediate plate 10 and an upper plate 25 of the LCD 2 is placed. A thin, semi-transparent layer 26 of indium tin oxide providing the top common electrode of the LCD 2 is deposited directly on the bottom surface of the top plate 25. External electrical connection to the electrode layer 26 is obtained via a wire 27. A filter layer 28 is applied to the lower surface of the electrode layer 26 by means of gauze pressure. The filter layer 28 is of a transparent polyamide or similar material and contains a matrix array of red, green, and blue regions aligned with and of the same size as the individual electrodes 21 of the transistors in the region 20 on the plate. 10. In practice, the size of the filter regions 28 and individual electrodes 21 will be considerably smaller than shown. Further details of the manufacture of suitable filter layers are given in the article by Kamamori et al, "Multicolor Graphic LCD with Tricolor Layers Formed by Electrodeposition", SID 84 Digest, biz. 215-216. When a monochrome display device is desired, the filter layer 28 can be omitted. On the bottom surface of the filter layer 28 is an upper alignment layer 17 which is identical to the lower alignment layer 23.

The top plate 25 is connected around its periphery to the intermediate plate 10 by a glass connection 29 after the liquid crystal material 24 has been introduced.

Above the top plate 25 is a retardation layer 30 of an elongated polycarbonate which is highly birefringent. This layer 30 is optional and, when used, serves to delay the phase of radiation passing through the layer. Elliptically polarized radiation falling on the layer 30 will, after passing through the layer, be more linearly polarized. A polarizer 31 is placed above the retardation layer 30.

The construction and operation of the LCD 2 is conventional except that the bottom plate of the LCD is provided by the top plate 10 of the lamp 1. LCDs are made conventionally using aluminosilicate glass or aluminoborosilicate glass as they have a very low alkali content. It is believed that alkali metal ions present in cheaper soda-lime glass induce instability in the material that forms the thin layer transistor and contaminates the liquid crystal material. However, it is now believed that cheaper soda lime glass can be used in LCDs, see the article by Uchikoga et al, "Soda Lime Glass as a Subtrate for TFT-LCDs", Japan Display 1989, biz. 426-428. Another problem that previously raised doubts about the suitability of soda-lime glass in LCDs is its large shrinkage during processes such as chemical vapor deposition. However, this problem can be prevented by preheating the glass to 500 ° C before it is processed.

The assembly of the present invention has several advantages over previous assemblies, in which the LCD is a separate component of the backlight. Because only three glass plates are used instead of four, the assembly can in the first place be made thinner and lighter than previous display devices. This is of particular importance in large-area displays, since any increase in weight of the display will be more prone to deformation; this could adversely affect the operation of the LCD. Secondly, the current construction avoids the need for two glass / air interfaces between the backlight and the LCD. This reduces radiation losses at the interface and prevents multiple reflections between the surfaces. Third, the integral nature of the LCD and backlight provides a much more robust construction than previous assemblies in which the LCD is separate from the backlight. This makes the assembly of the present invention less susceptible to damage from vibration and mechanical shock. Even where the LCD and backlight of previous assemblies are interconnected, this still results in the total thickness of the two interconnected glass plates being greater than necessary in the present invention. A junction additionally provides a place for mechanical weakness and for radiation losses. Moreover, the joining process of the assembly contributes to the number of processing steps and consequently to the price of the assembly.

The fact that the LCD is part of the backlight means that there will be good thermal transfer between the backlight and the LCD. This can be an advantage when used in cold environments as it avoids the need to use separate display heaters. The heat generated by the backlight may be sufficient to keep the intermediate wall at about 45 ° C. Temperature fluctuation is also reduced which may otherwise adversely affect the display.

Cold cathode fluorescent lamps, of the types described above, have a long life compared to heated electrode lamps. Therefore, the lamp life can be equal to that of the LCD on the order of 15 k to 20 k hours.

The above-described display assembly is of the dichroic type, although it will be appreciated that various other liquid crystal displays may be used, such as twisted nematic, super-twist displays, ferroelectric devices or polymer dispersed TN displays. These alternatives entail the need to use an additional polarizer to polarize radiation from the backlight. For example, this additional polarizer could be placed between the backlight 1 and the LCD 2, such as, between the common electrode 20 and the filter layer 23. Alternatively, the polarizer could be placed on the bottom surface of the backlight, between the bottom plate 11 and the reflector 15. In this way, the polarizer will polarize light reflected from the reflector 15 so that light exiting the intermediate plate 10 has a significant portion that is polarized. However, since light must pass through the polarizer in two directions, this reduces the overall radiation level and the portion that is polarized.

A display assembly of the present invention could be used in many applications, such as in vehicle instrumentation, in large area flat screen televisions, or in advertising applications.

An alternative display assembly is shown in Figure 2 which has a single backlight 1 'identical to that of Figure 1 except that it has no reflective layer on its bottom plate 11 *. Instead, the bottom plate 11 'forms a plate of a second LCD 2' 'which is identical to the top LCD 2'. In this way, light from one backlight 1 'is used to illuminate both the top and bottom displays. A two-sided display assembly of this type could be used in various applications. For example, it could be used in an advertising display 130, as shown in Figure 3, where it is mounted vertically and rotated about a vertical axis by a motor 131. The displays on opposite sides of the assembly would be be arranged to display the same or different messages.

Alternatively, the display assembly could be included in a portable display terminal 40, such as for a computer. Different information could be displayed on opposite sides 41 and 42 of the assembly. For example, terminal 40 may include a sensor, such as a ramp switch 43, which responds to reversal of the terminal causing a change in the displayed information. In this way, the terminal could be arranged to mimic a book with a different page of information on each side that changes each time the terminal is turned over. Also, the sensor could respond to rotation of the terminal in different directions, that is, right to left or left to right, causing the terminal to display either later or earlier pages of information.

The display assembly may include other conventional features such as a touch sensitive membrane on top of the polarizer 31 for data entry or selection.

Claims (10)

A display assembly comprising a liquid crystal display of the type having two glass plates separated by a liquid crystal material, each glass plate carrying a respective electrode layer, and a planar fluorescent lamp formed by two glass plates separated by a gas discharge volume, characterized in that one of the glass plates (10) of the lamp (1) provides one of the glass plates of the liquid crystal display (2) so that the liquid crystal display as integrally formed with the lamp and such that activation of the lamp (1) causes illumination of the liquid crystal display (2). A display device assembly according to claim 1, characterized in that the fluorescent lamp (1) is a cold cathode lamp. A display device assembly according to claim 1 or 2, characterized in that the liquid crystal display device (2) is a dichroic display device. A display device assembly according to any one of the preceding claims, characterized in that the lamp (1) between the plates (10 and 11) of the lamp has a series of pillars (12) supporting the plates. A display device assembly according to any one of the preceding claims, characterized in that the glass plates (10 and 11) are of sodium glass. A display device assembly according to any one of the preceding claims, characterized in that the assembly is provided with a filter layer (28) with areas having different color transmission properties, that the filter layer (28) is carried by the other plate ( 25) of the display device (2), and that the regions of the filter layer (28) are aligned with individual electrodes of one of the electrode layers (21 and 26). A display device assembly according to any one of the preceding claims, characterized in that the other of the glass plates (11) of the lamp (1) carries a reflector (16) on its external surface. A display device assembly according to claim 7, characterized in that the other of the glass plates (11) between the other plate (11) and the reflector (16) carries a polarizer (15). A display assembly according to any one of claims 1 to 6, characterized in that the assembly includes a second liquid crystal display (2 '') with two glass plates (11 'and 25') separated are by a liquid crystal material (24 ''), that each glass plate of the second liquid crystal display device carries a corresponding electrode layer, and that the other of the plates (11 ') of the lamp are one of the glass plates of the second liquid crystal display (2 '') is provided so that the second liquid crystal display is integrally formed with the lamp and such that activation of the lamp causes illumination of both liquid crystal displays. A display assembly according to any one of the preceding claims, characterized in that the assembly includes a sensor (43) responsive to reversal of the assembly to cause a change in the information output by the display assembly.