DE3531736A1 - Liquid-crystal display device - Google Patents

Abstract

The present invention discloses a liquid-crystal display device which uses an electroluminescence element (32) as the light source. In the case of the liquid-crystal display device according to the invention, the electroluminescence element (32) is covered at least on its rear side by a moisture-resistant protective coating (51) which has a laminated-on metal foil (54), and the metal foil (54) is connected to an earthing circuit (56). The metal foil (54) blocks the electrical field which is used for operating the electroluminescence element (32), so that a driving integrated circuit can be arranged directly behind the electroluminescence element (32) which is covered by the protective coating (51), without the integrated circuit being adversely affected by the disadvantageous effects of the electric field. <IMAGE>

Description

LIQUID CRYSTAL DISPLAY DEVICE

The present invention relates to a liquid crystal display device, in which an electroluminescent element is used as the light source for the backlight will.

In recent years, the adoption of the digital system has become more and more prevalent in all fields, and as natural As a consequence of this, display devices are moving to the digital representation of data. In particular liquid crystal display devices are used in an extremely wide range of applications because they have such advantages as have a high display quality and low energy consumption and, in addition, as they are in line with the general trend towards a Reduction in weight and thickness correspond. Though liquid crystal display devices in a bright room are visible, since their display surfaces are illuminated by the fact that they are arranged on the rear sides Reflective panels reflect incident outside light, a light source must be used in liquid crystal display devices used for lighting purposes in the dark., since the displays produced on the display surfaces are completely invisible in a dark room.

An example of a conventional liquid crystal display device, which has a light source for illumination purposes is constructed as shown in FIG. Here, polarizing plates 14, 15 are respectively on the front and rear surfaces of a liquid crystal cell 13 which is formed by joining two substrate plates 11, 11; in addition, a reflection plate 16 is on of the polarizing plate 15 is attached to the rear surface, and at the same time a plurality of lamps 17 are along the Side areas of the liquid crystal cell 13 arranged, whereby

Light from the side areas of the liquid crystal cell 13

ORIGINAL INSPECTED

is projected. With this arrangement, however, the light is extremely uneven and the display is only near the Lamps 17 made visible. In this device, it is therefore necessary to illuminate the display over the entire surface required to use a large number of lamps 17.

Another conventional liquid crystal display device is constructed as shown in FIG. Included is a light guide plate 18 formed of, for example, acrylic resin, between one provided on the rear side Polarizing plate 15 and a reflection plate 16 are arranged, and a plurality of lamps 17 is the edges the light guide plate 15 arranged opposite one another, wherein the light from the lamps 17 through the light guide plate is guided through to the display area. This device has the advantage that the uniformity of the lighting is slightly improved and the brightness of the lighting is increased. However, this device brings through the Light guide plate 18 involves a very large increase in size, and lamps 17 must have a have a very high luminance and, moreover, the power consumption increases, and in addition to this, it is necessary to have a Provide heat dissipation by means of a device such as a radiant panel.

Another example of a conventional liquid crystal display is constructed as shown in FIG. It is a semi-transparent reflection plate 19 on one on the rear provided polarizing plate 15 is arranged, a light diffusion plate 20 on the back of the semi-transparent Reflection plate 19 and a plurality of lamps 17 arranged on the other side thereof, whereby the from the lamps 17 passed light through the light diffusion plate 20 and on the rear surface of a Liquid crystal cell 13 is projected. This device has the disadvantages that it becomes uneven Light distribution tends to use the additional

Light diffusion plate 20 brings with it, the lamps 17 a must have high luminance and heat dissipation by means of a device such as a radiant panel, makes necessary.

Yet another example of a conventional liquid crystal display device consists in a combination of the device according to FIG. 6 with the device according to FIG. 7. However, this version is complicated in construction and has a high cost.

In addition to this, still another example of a conventional device is constructed as shown in FIG Fig. 8 is shown. There is an electroluminescent element 21 on the back of a liquid crystal cell arranged. This electroluminescent element 21 is generally provided with moisture-proof layers 22, 23 coated to thereby extend the useful life of the fluorescent Materials to increase. In this device, the electroluminescent element 21 is made to emit light, and this light is through a semi-transparent reflection plate 19 and projected on the back of the liquid crystal cell 13. This device has the Advantages of following the general trend towards a reduction in thickness and weight, a reduction in energy consumption and creates an even distribution of light. To excite the electroluminescent element 21 is an alternating current of high voltage (such as 100 to 200V, 50 to 10 kHz or 100 kHz is required for the purpose of reducing the Thickness of the device is the integrated circuit for driving the liquid crystal display device in the In most cases, arranged immediately behind the electroluminescent element 21 and in close contact with this held. This makes it possible for the alternating current used to operate the electroluminescent element 21 to be used high voltage affects the operation of the integrated circuit for driving the display device and the

ORIGINAL INSPECTED

353Ί736

Prevents the display device from operating normally.

The object of the present invention is to To provide a liquid crystal display device which uses an electroluminescent element as a light source for illumination is used and which has an arrangement which adversely affects the operation of driving the liquid crystal display device integrated circuit used by the to operate the electroluminescent element used high voltage alternating current prevents.

To solve this problem, a liquid crystal display device is provided according to the present invention, which is characterized by the fact that it uses an electroluminescent element as a light source for the background lighting used that the electroluminescent element at least on its back with a moisture-proof protective layer is covered, which has a laminated metal foil, and that the metal foil is provided for grounding or is grounded.

Because the effect of the alternating current electric field used to operate the electroluminescent element in the construction described above by the metal foil of the back of the electroluminescent element covering moisture-proof protective layer is intercepted, prevents the operation of the for driving the liquid crystal display device used integrated circuit, which is further behind the Electroluminescent element is arranged, is disturbed, and the reliability of the liquid according to the invention crystal display device is thus ensured. The liquid crystal display device of the present invention thus corresponds to the general trend towards a reduction

of thickness and weight, allows a reduction in energy or power consumption, creates a uniform Light distribution and enables excellent operation without any errors.

Preferred developments of the invention emerge from the subclaims.

The invention and further developments of the invention are described below with reference to the schematic representations of FIG preferred embodiments explained in more detail.

Show it:

Fig. 1 is a cross-sectional view of a first embodiment of the present invention;

Fig. 2 is a cross-sectional view showing a grounding arrangement for a moisture-proof protective layer therein Embodiment shows;

Figure 3 is a partial cross-sectional view of another embodiment incorporating a modified grounding arrangement for the moisture-proof protective layer;

Fig. 4 is a partial cross-sectional view of yet another embodiment that further modified one Has a grounding arrangement for the moisture-proof protective layer; and

Figures 5, 6, 7 and 8 are cross-sectional views of conventional liquid crystal display devices.

As shown in Fig. 1, the liquid crystal display device has according to the first embodiment, a liquid crystal element 31 and an electroluminescent element behind the liquid crystal element 31.

With respect to the liquid crystal element 31, the layers bearing reference numerals 33 and 34 denote a pair transparent substrates, e.g. made of plastic film or thin glass. On the inner surfaces of the substrates transparent electrodes 35, 36 formed of, for example, tin oxide or indium oxide are arranged. On the inner surfaces Alignment layers 37, 38 are arranged on these transparent electrodes 35, 36. The reference number 39 denotes a sealing material applied along the and portions of the substrates 33, 34 and the layers formed on these substrates is arranged around. The substrates 33, 34 are fastened to one another by means of this sealing material 39 in such a way that they enclose a liquid crystal layer 40 between them.

Polarizing plates 41, 42 are arranged on the outer surfaces of the substrates 33, 34, and a semi-transparent one Reflection plate 43 is on the outer surface of the one on the rear side of the liquid crystal element 31 Polarizing plate 42 attached.

As far as the electroluminescent element 32 is concerned, the layer bearing the reference number 44 denotes a transparent substrate, which is formed, for example, from thin glass or plastic film, the reference number 45 denotes a transparent electrode which is made of indium oxide or tin oxide, the reference number 46 a fluorescent layer formed using ZnS or a mixed crystal of ZnS and ZnSe or a mixed crystal of ZnS and CdS as a matrix with the addition of an activating agent such as Cu, Cl or Mn, reference numeral 47 is a dielectric layer formed by dispersing a powder material with a high dielectric constant, such as TiO ₂ or BaTiO ₃ , is formed in an organic, high molecular weight binder, the reference numeral 48 is a counter electrode which is formed from a metallic layer of Al or Cu, and the reference numeral 49 denotes a desiccator layer, which is formed by embedding a inorganic desiccators s, such as zeolite, silica gel or calcium oxide, is formed into a hygroscopic polymer such as polyvinyl alcohol or ethyl cellulose. These layers are applied one after the other in the order mentioned in order to completely form the electroluminescent element 32. Also, reference numeral 50 denotes a moisture-proof protective layer covering the front surface of the above-mentioned superposed layer structure, and reference numeral 51 denotes a moisture-proof protective layer which covers the rear surface of the superposed layer structure

at the edges
covers and thereby / extends to the front up to the protective layer 50. : The protective layer covering the front surface is made of a transparent film made of polyethylene or polyester. The the rear face

covering moisture-proof protective layer 51 is in the form of a three-layer structure, wherein a metal foil 54, which is formed e.g. from Al or Cu, e.g. between a polyethylene film 52 and a polyester film 53 is arranged, as shown in FIG. At one end of the moisture-proof Protective layer 51, the polyester film 53 is peeled off to expose the metal film 54. With the exposed At the portion of the metal foil 54, one end of a metal foil tape 55 is connected, which by means of a means such as e.g. a conductive adhesive or solder material. This metal foil tape 55 is provided with a grounding circuit 56 tied together.

With the arrangement described above, when a voltage is applied, the liquid crystal element 31 causes the transparent electrodes 35, 36 a change in the orientation of the liquid crystal 40 and causes the desired display thereby, that it optionally blocks or allows the passage of light. When applying an alternating voltage between the transparent electrode 45 and the counter electrode 47, the electroluminescent element causes the fluorescent element Layer 47 for emitting light through the transparent electrode 45, the transparent substrate 44 as well as through the moisture-proof protective layer 50. When using this liquid crystal display device in a bright room, it becomes these operated in such a way that they are a reflective display caused by causing the semitransparent reflection plate 43 to reflect the outside light will. In this case, the liquid crystal display device has not used for the operation of the electroluminescent element 32. When this liquid crystal display device however, if it is operated in a dark room, since the outside lighting is no longer available, operated to effect the desired display by the light from the electroluminescent element 32 penetrates. In this case, since the electroluminescent element 32 is supplied with an alternating current of high voltage, at

one in close contact with the rear surface of the electroluminescent element 32 arranged and used for driving the liquid crystal display device integrated Circuit under the influence of the electric field can cause erroneous operation. As with the present Invention, the rear surface of the electroluminescent element 32 with the moisture-proof protective layer 51, which the Metal foil 54 is covered, and since this metal foil 54 is connected to the grounding circuit 56 via the metal foil tape 55, the effect of the Electroluminescent element 32 intercepted alternating voltage applied by the metal foil 54 and attached to it prevented from affecting the integrated circuit used for driving the liquid crystal display device. Despite using the high voltage to energize the electroluminescent element 32, the Liquid crystal display device thus operate without fail.

As this liquid crystal display device in a portable computer or a liquid crystal display watch was tested experimentally, it worked without any errors. However, as a liquid crystal display device was used in which the metal foil 54 was not grounded, it often showed an erroneous operation and was not capable of exhibiting reliability sufficient for commercial use thereof.

Fig. 3 shows a further embodiment of the present Invention with a modified arrangement for grounding the metal foil 54 of the moisture-proof protective layer 51. In this embodiment, one end portion of the moisture-proof protective layer 51 is extended outward, and a conductive terminal 57 is through a flange-like rivet 58 with this extended portion of the sheet tied together. The metal foil 54 is connected to the conductive connection 57 via the material of the rivet. Besides, the conductive terminal connected to the ground circuit 56.

Fig. 4 shows yet another embodiment of the present invention with an even further modified one Arrangement for grounding the metal foil 54 of the moisture-proof protective film 51. In this embodiment, the Edge areas of the electroluminescent element 32, or better Said the edge areas of the protective layer 51, fastened to a chassis 59 by means of screws 60 and nuts 61. Washers 62 are arranged under the heads of the screws 60, on their fastening side, i.e. on their the side facing the protective layer 51 are provided with pointed projections. These pointed protrusions penetrate the moisture-proof protective layer and contact the metal foil 54. The metal foil 54 is Electrically connected to the chassis 59 through the washers 62, the bolts 60 and the nuts, and the chassis 59 is connected to the ground circuit 56.

In the exemplary embodiments described above, the moisture-proof protective layer 51 can optionally also be in In the form of a two-layer structure, which consists of a plastic film and a metal film. the Structures of the liquid crystal element 31 and the electroluminescent element 32 are not different from the above structures described are limited.

The following are those related to the present invention achievable effects described.

Since, as already described above, the present invention, the electroluminescent element as a light source for Backlight used and at least the back of this electroluminescent element with the moisture-proof Protective layer, which has a laminated metal foil, is covered and this metal foil is connected to a grounding circuit, which is further behind the electroluminescent element arranged and for driving the liquid crystal display device serving integrated circuit by the

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Metal foil in front of the effect of the on the electroluminescent element applied AC voltage, and an erroneous operation of the liquid crystal display device is thus prevented. Since the electroluminescent element is used as a light source for lighting, the liquid crystal display device of the present invention corresponds to the trend towards a reduction in thickness and Weight, and it also enables a reduction in energy consumption and shows an even distribution of light.

Claims (11)

Expectations 1. A liquid crystal display device using an electroluminescent element is used as a light source for lighting, characterized in that the electroluminescent element (32) at least on its The back is covered with a moisture-proof protective layer (51) which has a metal foil (54) laminated on, and that the metal foil (54) is connected to a grounding device (56). 2. Liquid crystal display device according to claim 1, characterized in that the electroluminescent element (32) a transparent substrate (44), a transparent electrode (45), a fluorescent layer (46), a dielectric layer (47), a counter electrode (48) and a desiccator layer (49) which are applied one after the other in the order mentioned. 3. Liquid crystal display device according to claim 1 or 2, characterized in that the transparent substrate (44) is formed from a glass plate or from a plastic film. 4. Liquid crystal display device according to one of claims 1 to 3, characterized in that the transparent electrode (45) is formed from indium oxide or tin oxide. 5. Liquid crystal display device according to one of claims 1 to 4, characterized in that the fluorescent layer (46) using ZnS, a mixed crystal of ZnS and ZnSe or a mixed crystal of ZnS and CdS is formed as a matrix with the addition of Cu, Cl or Mn as an activating agent. 6. Liquid crystal display device according to one of claims 1 to 5, characterized in that the dielectric layer (47) is formed by dispersing a powder material having a high dielectric constant, preferably TiO or BaTiO ₃ , in an organic high molecular weight binder. 7. Liquid crystal display device according to one of claims 1 to 6, characterized in that the Counter electrode (48) is formed from a thin layer of Al or Cu. 8. Liquid crystal display device according to one of claims 1 to 7, characterized in that the Desiccator layer (49) by embedding an inorganic powdered desiccator agent, preferably zeolite, Silica gel or calcium oxide, in a hygroscopic polymer, preferably polyvinyl alcohol or ethyl cellulose, is formed. 9. Liquid crystal display device according to one of claims 1 to 8 / characterized in that the Metal foil (54) is connected to the grounding device (56) in that the metal foil (54) is connected by a peeled off area of the moisture-proof protective layer (51) is exposed and the exposed area of the metal floie (54) is connected to the grounding device (56) by the material of a metal foil tape (55). 10. Liquid crystal display device according to one of claims 1 to 8, characterized in that the Metal foil (54) is connected to the grounding device (56) in that one end of the moisture-proof protective layer (51) is extended, on the extended area a conductive connection (57) with the help of a rivet (58) is attached and the rivet (58) via the conductive connection (57) an electrical connection to the grounding device (56) forms. 11. Liquid crystal display device according to one of claims 1 to 8, characterized in that the Metal foil (54) is connected to the grounding device (56) in that the mutually opposite edge regions the electroluminescent element (32) by means of screws (60) and nuts (61) on a chassis (59) are attached, under the heads of the screws (60) washers (62) with pointed projections are arranged and the pointed projections make an electrical connection with the metal foil (54).