DE202011101372U1 - Infrared ray reflecting strip and liquid crystal display device containing the same - Google Patents

Abstract

An infrared ray reflective strip (10, 10 ') comprising: a light reflective substrate (20) having a configuration surface on which a plurality of reflective configurations (22, 22') are formed and a bottom surface; a transparent first protective layer (30) having high transmittance and low reflectivity for infrared rays adhered to or bonded to the plurality of reflective configurations (22, 22 ') of the light reflective substrate (20); a UV-resistant material layer (40) superposed on the first protective layer (30); a second protective layer (50) adhered or bonded to the underside of the light reflective substrate (20); an adhesive layer (60) to which the second protective layer (50) is applied; and a release paper (70) releasably adhered to the adhesive layer (60).

Description

The present invention generally relates to a high reflectivity infrared ray reflecting strip, and more particularly, to an infrared ray reflecting strip used in an optical touch-sensitive liquid crystal display (touch panel LCD display) and a liquid crystal display device containing a high reflectivity infrared ray reflecting strip.

Liquid crystal displays (LCDs), as a device for displaying information or images due to their compactness and image quality, low power consumption and low radiation, are widely used in various electronic devices, such as television (TV), personal computer (PC), laptop computer, Mobile phones, personal digital assistants (PDAs), etc. In order to enhance the convenience and fun of consumer electronics applications, the demand for touch panel LCD displays has recently increased dramatically.

Generally, touch-sensitive LCD displays have been classified into those of a resistance-type, a capacitance-type, and an optical-type, and optical-type touch-sensitive LCD displays have become more promising because of their high accuracy and short response time.

An optical touch panel uses a light blocking principle to determine a touch point on the board. For example, a plurality of light emitters and light receivers are provided on opposite sides of the board, and when an object such as a human finger touches a point on the board, light that wants to pass that point is blocked, and the location thereof Touch point can be determined by finding out which light receivers receive no light. Conventionally, a plurality of light-emitting diodes (LEDs) are provided on two adjacent sides of the board, such as one side on the X axis and the other side on the Y axis, and a plurality of infrared sensors are on the opposite sides of the ones provided with the LEDs Sides are provided to receive infrared rays emitted by the LEDs. These infrared rays form a plurality of positioning gratings on the surface of the board to position any point on the board. The positioning accuracy increases as the number of LEDs and sensors increases. However, this construction has disadvantages, i. That is, the LEDs and infrared sensors not only consume a lot of power, but also generate a considerable amount of heat, and this large amount of heat in turn creates a heat dissipation problem with the consumer electronics, which is generally compact in size. Therefore, the high power consumption and the large heat generation are two major disadvantages of this type of optical touch tablet.

In addition to the optical touch tablet described above, there is another optical touch tablet design. In this design, instead of looking at a variety of light sources and light sensors around the LCD board, two CMOS cameras are used as light sensors, with one CMOS camera located at the upper left corner and the other CMOS camera at the lower right corner of the LCD board and an infrared ray emitting device (eg, an infrared LED) is provided adjacent to each of the CMOS cameras. In addition, each of the lateral sides of the LED board is provided with an infrared ray reflecting strip to reflect infrared rays emitted from the LEDs onto the surface of the LCD board so as to cover the entire surface of the LCD board with infrared rays. When an object such as a human finger or a pen touches the board, the infrared ray is blocked on the surface of the LCD board, and the discontinuity of the infrared ray is detected by the CMOS cameras, and the position of this touch point can be detected by a triangulation detection method high precision. The better in this optical touch tablet design the infrared ray reflection force of the infrared ray reflecting rays, the less power the LED needs, and the less heat is generated. And there is still room for improving the infrared ray reflecting power of existing infrared ray reflecting stripes.

Therefore, in the manufacturers of optical touch-sensitive liquid crystal displays, there is a demand for an infrared ray reflecting strip having high infrared ray reflecting power to meet the requirements of lower power consumption and less heat generation.

It is therefore an object of the invention to provide a high reflectivity infrared ray reflecting strip for an optical touch-sensitive liquid crystal display device.

This object can be achieved by an infrared ray reflecting strip, which comprises:
a light reflecting substrate having a configuration surface on which a plurality of reflective configurations are formed, and a bottom;
a transparent first protective layer having high transmittance and low reflection power for infrared rays glued or bonded to the plurality of reflective configurations of the light reflecting substrate;
a UV-resistant material layer deposited on the first protective layer;
a second protective layer adhered or bonded to the underside of the light-reflecting substrate;
an adhesive layer having the second protective layer applied thereto; and
a release paper which releasably adheres to the adhesive layer.

Preferably, the reflective configurations on the configuration surface include hemispherical reflective configurations or pyramidal reflective configurations. The configuration surface may be coated with an aluminum film layer. The first and second protective layers may comprise a thermoplastic polyurethane (TPU) film.

According to another aspect of the invention, there is provided an optical touch-sensitive liquid crystal display device comprising:
a liquid crystal display board; and
an optical positioning unit comprising:
a plurality of infrared ray light sources arranged from at least one lateral side of the liquid crystal display panel;
at least two infrared sensors each disposed on at least two corners of the liquid crystal display panel; and
a plurality of infrared ray reflecting strips according to the invention, which are arranged on those lateral sides of the liquid crystal display board on which no infrared ray light sources are arranged.

Other features and objects of the invention will become more apparent upon reading the following description with reference to the accompanying drawings. For a further understanding of the invention and the advantages thereof, reference is now made to the ensuing description taken in conjunction with the accompanying drawings in which: FIG

1A FIG. 12 is a schematic plan view of an infrared ray reflective strip used in a touch panel optical liquid crystal display device according to a first embodiment; FIG.

1B FIG. 12 is an enlarged schematic cross-sectional view of the infrared ray reflective strip taken along line AA of FIG 1A ;

2A Fig. 12 is a schematic plan view of an infrared ray reflecting strip used in an optical touch-sensitive liquid crystal display device according to a second embodiment;

2 B FIG. 12 is an enlarged schematic cross-sectional view of the infrared ray reflective strip taken along line BB 'of FIG 2A ; and

3 Fig. 12 is a schematic plan view of an optical touch-sensitive liquid crystal display device according to another aspect of the invention, wherein three infrared ray reflective strips of the invention are provided.

Based on 1A and 1B now becomes an infrared ray reflecting strip 10 for a liquid crystal display (LCD display) according to a first embodiment of the invention.

As in the 1A and 1B As shown, the infrared ray contains reflective stripes 10 mainly a halogen-free back, which is a release paper 70 and one on the release paper 70 arranged adhesive film 60 contains; a light-reflecting substrate 20 that on the adhesive layer 60 is arranged and a configuration interface on which a variety of reflective configurations 22 are formed, and has a bottom. In this embodiment, the reflective configurations 22 may be hemispherical reflective configurations, and a metal film, such as an aluminum metal film, may be supported on the surface of these hemispherical reflective configurations to further enhance the reflectivity of the reflective configurations. Preferred is a second protective film 50 between the light-reflecting substrate 20 and the adhesive layer 60 intended.

In addition, the infrared rays contain reflective stripes 10 this embodiment, a transparent first protective film 30 which is on the configuration surface of the light-reflecting substrate 20 is arranged. This protective layer is preferred 30 made of a material having high transmittance and low reflection power for infrared rays, such as thermoplastic polyurethane (TPU), to allow infrared rays to pass through this protective film 30 without substantially reflecting, and arrive at the configuration surface of the light-reflecting substrate, and which allows the infrared rays passing through the metal-film-coated reflective configurations 22 reflects be through this protective film 30 to get an improved infrared ray reflection effect. In addition, in order to prevent the optical properties from deteriorating due to the moisture contained in the air, the surface of the first protective film is preferable 30 with a UV-resistant film material 40 coated.

When all the above-mentioned layers of the infrared ray reflecting strip 10 According to this embodiment, a high frequency bonding process is performed to properly bond this coating together, and then it can be cut to the required dimension to form infrared ray reflecting stripes 10 with the required sizes.

The 2A and 2 B show an infrared ray reflecting strip 10 ' according to a second embodiment of the invention. The structure of the infrared ray reflecting strip 10 ' is essentially the same as the one in 1A and 1B described infrared rays reflecting strip 10 except that the reflective configurations 22 ' of this embodiment are pyramidal reflective configurations, rather than the hemispherical reflective configurations of the first embodiment. Although the reflective configurations 22 ' of the second embodiment are pyramidally-reflecting configurations, they provide substantially the same infrared ray reflecting effect as in the first embodiment.

*** "" Referring to Fig. 3, there is shown an optical touch-sensitive liquid crystal display device (liquid crystal display device having an optical touch-sensitive board). *** " 100 according to another aspect of the present invention, wherein three infrared ray reflecting stripes 10 be applied.

As in 3 shown contains the optical touch-sensitive liquid crystal display device 100 generally a liquid crystal board 120 and an optical positioning unit containing a plurality of infrared light sources 130 having on a lateral or longitudinal side of the liquid crystal display board 120 are arranged; two infrared sensors 140 such as CMOS cameras, each at the upper right corner and the lower left corner of the liquid crystal display board 120 are arranged; and three rays reflecting infrared rays 10 according to the invention on the remaining lateral sides of the liquid crystal display board 120 , where no infrared light sources are provided, are arranged to those of the infrared light sources 130 emitted infrared rays on the entire surface of the liquid crystal panel 120 to reflect.

In conventional optical touch-sensitive liquid crystal display devices, a considerable number of light sources such as LEDs and sensors are used to construct an optical network with a high density of optical gratings on the liquid crystal display in order to obtain better positioning accuracy for locating a touched point on the screen. However, both the light sources and the sensors consume electric power and generate heat, and the more light sources and sensors are used in the liquid crystal display device, the more electric power is consumed and the more heat is generated. In contrast, the highly efficient infrared rays reflecting strip of the invention generates the required infrared light by reflection of the infrared light, and therefore no electric current is required to generate the light, and no heat is generated while the light is generated. Therefore, the number of LED light sources provided in an optical touch-sensitive liquid crystal display device using the infrared rays reflecting strips of the invention can be much smaller than the number of LED light sources that a conventional optical touch-sensitive liquid crystal display device needs. Therefore, the optical touch panel liquid crystal display device incorporating the infrared ray reflecting strip of the invention can dramatically reduce electric power consumption and heat generation to efficiently solve the problems of high power consumption, high heat generation, and heat dissipation difficulty existing in conventional liquid crystal display devices to solve. Because the infrared ray reflective strip of the invention and the infrared reflective reflective strip-containing optical touch-sensitive liquid crystal display device have the above-mentioned advantages and superior functions, the infrared ray reflecting strip and the optical touch-sensitive liquid crystal display device of the invention are products which are well applicable in the industry.

According to one aspect, an infrared ray reflecting strip ( 10 . 10 ' ) for a liquid crystal display device ( 100 ). The infrared rays reflecting strips ( 10 . 10 ' ) contains a light-reflecting substrate ( 10 ) having a configuration surface on which a plurality of reflective configurations ( 22 . 22 ' ) are formed, and a bottom; a transparent first protective layer ( 30 ) having high transmittance and low reflectivity for infrared rays due to the variety of reflective configurations ( 22 . 22 ' ) of the light-reflecting substrate ( 20 ) glued or connected to it; a UV-resistant material layer ( 40 ) on the first protective layer ( 30 ) is superimposed; a second protective layer ( 50 ) placed on the underside of the light-reflecting substrate ( 20 ) glued or connected to it; an adhesive layer ( 60 ), which is the second protective layer ( 50 ) is applied; and a release paper ( 70 ) attached to the adhesive layer ( 60 ) releasably adheres. According to another aspect, there is provided a liquid crystal display device including the light-reflecting stripes.

Claims (6)

Infrared ray reflecting strip ( 10 . 10 ' ) comprising: a light-reflecting substrate ( 20 ) having a configuration surface on which a plurality of reflective configurations ( 22 . 22 ' ) are formed, and a bottom; a transparent first protective layer ( 30 ) having high transmittance and low reflectivity for infrared rays due to the variety of reflective configurations ( 22 . 22 ' ) of the light-reflecting substrate ( 20 ) glued or connected to it; a UV-resistant material layer ( 40 ) on the first protective layer ( 30 ) is superimposed; a second protective layer ( 50 ) placed on the underside of the light-reflecting substrate ( 20 ) glued or connected to it; an adhesive layer ( 60 ), which is the second protective layer ( 50 ) is applied; and a release paper ( 70 ) attached to the adhesive layer ( 60 ) releasably adheres. Infrared ray reflecting strip ( 10 . 10 ' ) according to claim 1, wherein the reflective configurations ( 22 . 22 ' ) on the configuration surface of the light-reflecting substrate ( 20 ) hemispherical configurations ( 22 ) exhibit. Infrared ray reflecting strip ( 10 . 10 ' ) according to claim 1, wherein the reflective configurations ( 22 . 22 ' ) on the configuration surface of the light-reflecting substrate ( 20 ) pyramidal configurations ( 22 ) exhibit. Infrared ray reflecting strip ( 10 . 10 ' ) according to claim 1, wherein an aluminum metal film is applied to the surface of the configuration surface of the light-reflecting substrate (FIG. 20 ) is stored. Infrared ray reflecting strip ( 10 . 10 ' ) according to claim 1, wherein the first and second protective layers ( 30 . 50 ) comprise a thermoplastic polyurethane (TPU) film. Optical touch-sensitive liquid crystal display device ( 100 ) comprising: a liquid crystal display board ( 120 ); and an optical positioning unit, comprising: a plurality of infrared light sources (US Pat. 130 ) on at least one lateral side of the liquid crystal display board ( 120 ) are arranged; at least two infrared sensors ( 140 ), each at at least two corners of the liquid crystal display board ( 120 ) are arranged; and a plurality of infrared ray reflecting strips ( 10 ) according to any one of claims 1-5, which on lateral sides of the liquid crystal display board ( 120 ) are arranged at which no infrared light sources ( 130 ) are arranged.

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