KR20110014904A - Transparent display device - Google Patents

Abstract

PURPOSE: A transparent display device is provided to switch a color mode, black mode, and a transparent mode, thereby providing a display device facing the background of a rear surface. CONSTITUTION: A blind panel unit(110) includes a pair of first transparent substrates(115) and a numatic liquid crystal substance. According to a first voltage, the blind panel unit blocks an incoming light of all wavelength bands. A display panel unit(120) includes a pair of a second transparent substrate(123) and a cholesteric substance(125). According to a second voltage, the display panel transmits incident light of all wavelength bands. The first and second voltages are applied between the first and the second transparent substrates.

Description

Transparent display device {TRANSPARENT DISPLAY DEVICE}

The present invention relates to a display device.

Highly developed electronic information technology, well-established industrial foundations, and rapidly spreading information distribution networks have resulted in rapid performance improvements and widespread deployment of information and communication devices. Among them, the information display device, which is the ultimate medium for the machine to convey information to humans, is the latest ultra-thin / large area full color from the early cathode ray tube (CRT) monochromatic display device, which occupied a very large volume. We have seen very fast growth rates to the display, and this trend will be accelerated by factors such as the rapidly increasing amount of information, the aesthetic desire of users to see more sophisticated and beautiful, and the office environment that needs to be simplified. It is expected. In recent years, unlike the conventional display, there is a demand for maximizing the aesthetics and utilization by making the background of the back side visible by maintaining the display panel itself in a transparent state in which no image is displayed.

Such a so-called transparent display technology is a core information display device of the next generation, and is expected to have a very large ripple effect on the whole society by innovatively improving the human lifestyle and the quality of information enjoyed. Such a transparent display can be applied to portable materials made of transparent materials such as glasses to further improve its mobility and portability, and can be used as a display element that maximizes space utilization by being applied to a glass window of a house or a windshield of a car. In addition, the present invention may be applied to or utilized in other fields not mentioned above, thereby contributing to the enhancement of human convenience and satisfaction.

In the demand for such a transparent display, a conventional universal information display device is configured to display an image driven in color in an operation mode, and to maintain a essentially black screen state in an inactive mode. The limitation is that it cannot satisfy the demand for a display operating in transparent mode.

In view of such a demand for a transparent display, the structure of a liquid crystal display (LCD), which is a representative flat panel display device having the highest market share among various information display devices developed in the past, will be described. The back light unit (BLU) is a light source that is located at the rear and serves as a light source for supplying light to the display device, a liquid crystal panel positioned at the front thereof to selectively transmit or block light, and light transmitted from the liquid crystal panel. It consists of a color filter (Color Filter) for separating the color to have any one of red, green, blue. Among these, the above-mentioned backlight unit and color filter have very low light transmittance due to their structure and characteristics. Such low light transmittance causes the entire liquid crystal display to block the back background. It acts as a major cause.

Looking at the feasibility of the transparent display through the structure of the plasma display panel (PDP), another display method showing a high share in the large flat panel display market together with the liquid crystal display, the plasma display is a glass substrate with an electrode It consists of a barrier rib pattern formed above, a fluorescent substance coated on the inside of the barrier rib, and a counter substrate on which an electrode is formed. In this structure, the partition pattern optically scatters the light incident from the rear surface to make the background of the rear surface look cloudy, and the fluorescent material coated inside the partition has low light transmittance. To block the rear light. By, it is a major cause of opaque, the entire display panel.

As described above, many flat panel display devices developed in the related art are fundamentally blocked by back light by the structure, and thus are not suitable for achieving the transparency of the aforementioned display, and thus have a new structure of color that can achieve such a transparent display. Development of a display method is required.

An object of the present invention to solve this problem is to provide a transparent display device that can be freely switched between color mode, black mode and transparent mode, and improved usability and aesthetics of the information display element and freedom in image display. .

The transparent display device according to the present invention includes a pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmits incident light in all wavelength bands, and is applied between the first transparent substrates. And a blind panel portion for blocking incident light in all wavelength bands according to the first voltage, and a cholesteric liquid crystal material stacked on the blind panel portion and injected between the pair of second transparent substrates and the second transparent substrates. The display panel unit may reflect incident light of a specific wavelength band among incident light of a visible light band and transmit incident light of all wavelength bands according to a second voltage applied between the second transparent substrates.

Specific wavelength band of the display panel unit,

It is preferable that it is any one of red, green, and blue wavelength bands.

The first transparent substrate is

A pair of liquid crystal alignment layers respectively formed on the nematic liquid crystal material, each pair of liquid crystal alignment layers for aligning the liquid crystal molecules of the nematic liquid crystal material in a predetermined direction, and a pair of first layers for applying a first voltage; It is preferable to include a transparent electrode, a pair of glass substrates respectively formed on the first transparent electrode, and a pair of polarizing films each formed on the glass substrate.

The liquid crystal aligning film is

The rubbing direction of each of the liquid crystal alignment layers is formed to be different from each other by 90 degrees,

Polarizing film,

It is preferable that it is formed so as to transmit incident light oscillating in parallel with the rubbing direction of each of the liquid crystal alignment films.

The second transparent substrate is

It is preferable to include a pair of second transparent electrodes formed on the cholesteric liquid crystal material, respectively, and a glass substrate formed on each of the second transparent electrodes for applying a second voltage.

The transparent display device according to the present invention includes a pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmits incident light in all wavelength bands, and is applied between the first transparent substrates. A blind panel portion which blocks incident light in all wavelength bands according to the first voltage to be formed, stacked on the blind panel portion, and including a pair of second transparent substrates and a cholesteric liquid crystal material injected between the second transparent substrates The display panel unit reflects incident light in a specific wavelength band among incident light in the visible light band, and transmits incident light in all wavelength bands according to a second voltage applied between the second transparent substrates, and a display panel to illuminate the display panel unit. And a transparent frontlight unit formed in the float.

Specific wavelength band of the display panel unit,

It is preferable that it is any one of red, green, and blue wavelength bands.

The first transparent substrate is

A pair of liquid crystal alignment layers respectively formed on the nematic liquid crystal material, each pair of liquid crystal alignment layers for aligning the liquid crystal molecules of the nematic liquid crystal material in a predetermined direction, and a pair of first layers for applying a first voltage; It is preferable to include a transparent electrode, a pair of glass substrates respectively formed on the first transparent electrode, and a pair of polarizing films each formed on the glass substrate.

The liquid crystal aligning film is

The rubbing direction of each of the liquid crystal alignment layers is formed to be different from each other by 90 degrees,

Polarizing film,

It is preferable that it is formed so as to transmit incident light oscillating in parallel with the rubbing direction of each of the liquid crystal alignment films.

The second transparent substrate is

It is preferable to include a pair of second transparent electrodes formed on the cholesteric liquid crystal material, respectively, and a glass substrate formed on each of the second transparent electrodes for applying a second voltage.

The front light unit,

A light source for irradiating light, a transparent light guide plate stacked on the display panel unit and uniformly propagating the light irradiated from the light source, and formed on one side of the light guide plate, and the light propagated into the light guide plate is emitted to the front of the display unit panel unit. It is preferable to include a plurality of micro patterns for changing the optical path.

The transparent display device according to the present invention includes a pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmits incident light in all wavelength bands, and is applied between the first transparent substrates. Blind panel portion for blocking incident light in all wavelength bands in accordance with the first voltage to be, and a plurality of stacked on the blind panel portion, a cholesteric liquid crystal material injected between a pair of the second transparent substrate and the second transparent substrate A display panel unit including each and reflecting incident light in a specific wavelength band among incident light in a visible light band, and transmitting incident light in all wavelength bands according to a second voltage applied between the second transparent substrates; Specific wavelength bands of each of the display panel units may be different wavelength bands.

The display panel part,

A first unit display panel stacked on the blind panel unit, a second unit display panel stacked on the second unit display panel, and a third unit display panel stacked on the second unit display panel,

Specific wavelength bands of each of the first unit display panel, the second unit display panel, and the third unit display panel include:

It is preferable that it is any one of red, green, and blue wavelength bands.

The first transparent substrate is

A pair of liquid crystal alignment layers respectively formed on the nematic liquid crystal material, each pair of liquid crystal alignment layers for aligning the liquid crystal molecules of the nematic liquid crystal material in a predetermined direction, and a pair of first layers for applying a first voltage; It is preferable to include a transparent electrode, a pair of glass substrates respectively formed on the first transparent electrode, and a pair of polarizing films each formed on the glass substrate.

The liquid crystal aligning film is

The rubbing direction of each of the liquid crystal alignment layers is formed to be different from each other by 90 degrees,

Polarizing film,

It is preferable that it is formed so as to transmit incident light oscillating in parallel with the rubbing direction of each of the liquid crystal alignment films.

The second transparent substrate is

It is preferable to include a pair of second transparent electrodes formed on the cholesteric liquid crystal material, respectively, and a glass substrate formed on each of the second transparent electrodes for applying a second voltage.

The transparent display device according to the present invention includes a pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmits incident light in all wavelength bands, and is applied between the first transparent substrates. And a blind panel portion for blocking incident light in all wavelength bands according to the first voltage, and a cholesteric liquid crystal material stacked on the blind panel portion and injected between the pair of second transparent substrates and the second transparent substrates. The display panel unit may reflect incident light of a specific wavelength band among incident light of a visible light band, and transmit incident light of all wavelength bands according to a second voltage applied between the second transparent substrates. A specific wavelength band constituting one pixel and between display panel portions of pixels adjacent to each other is a different wavelength band.

The first transparent substrate is

A pair of liquid crystal alignment layers respectively formed on the nematic liquid crystal material, each pair of liquid crystal alignment layers for aligning the liquid crystal molecules of the nematic liquid crystal material in a predetermined direction, and a pair of first layers for applying a first voltage; It is preferable to include a transparent electrode, a pair of glass substrates respectively formed on the first transparent electrode, and a pair of polarizing films each formed on the glass substrate.

The liquid crystal aligning film is

The rubbing direction of each of the liquid crystal alignment layers is formed to be different from each other by 90 degrees,

Polarizing film,

It is preferable that it is formed so as to transmit incident light oscillating in parallel with the rubbing direction of each of the liquid crystal alignment films.

The second transparent substrate is

It is preferable to include a pair of second transparent electrodes formed on the cholesteric liquid crystal material, respectively, and a glass substrate formed on each of the second transparent electrodes for applying a second voltage.

According to the present invention, not only the color mode and the black mode, but also the transparent mode according to the needs of the user can be provided, thereby providing a display device in which the background of the rear surface is visible.

In addition, it can be installed in the windows of houses or buildings, windshields of various means of transportation, and at the same time to function as a transparent glass window and a display device can maximize the usability and aesthetics of the space.

In addition, by adopting the reflective mode, in an environment where sufficient external light exists, the image displayed on the display can be identified without a separate light source, and thus power consumption can be minimized.

In addition, since switching between the color mode, the black mode, and the transparent mode is performed, so-called bi-stability that maintains the state without a separate voltage is applied, which further reduces power consumption as compared with the conventional display.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration, operation principle and operation mode of the transparent display device according to an embodiment of the present invention. In addition, in the description of each embodiment, parts that refer to the same configuration will be described with the same reference numerals.

[First Embodiment]

1A is a diagram illustrating a configuration of a transparent display device 100 according to a first embodiment of the present invention.

First, a configuration of the transparent display apparatus 100 according to the first embodiment will be described in detail with reference to FIG. 1A.

Referring to FIG. 1A, the transparent display device 100 according to the present invention includes a blind panel unit 110 and a display panel unit 120.

The blind panel unit 110 includes a pair of nematic liquid crystal materials 117 injected between the first transparent substrate 115 and the first transparent substrate 115.

The first transparent substrate 115 is formed on the nematic liquid crystal material 117, respectively, and the pair of liquid crystal alignment layers 111a and 111b and the liquid crystal to align the liquid crystal molecules of the nematic liquid crystal material 117 in a predetermined direction. A pair formed on the alignment layers 111a and 111b, respectively, and a pair formed on the pair of first transparent electrodes 112a and 112b and the first transparent electrodes 112a and 112b to apply the first voltage V1, respectively. The glass substrates 113a and 113b and a pair of polarizing films 114a and 114b respectively formed on the glass substrates 113a and 113b may be included.

The pair of liquid crystal alignment layers 111a and 111b may be composed of an upper liquid crystal alignment layer 111a and a lower liquid crystal alignment layer 111b, and the upper liquid crystal alignment layer 111a and the lower liquid crystal alignment layer 111b are respectively rubbed. The nematic liquid crystal material 117 may be coupled to the nematic liquid crystal material 117 so that the direction is 90 degrees. Various polymer materials can be used as a constituent material of the liquid crystal alignment layers 111a and 111b, and it is generally preferable to use a polyimide series.

The pair of first transparent electrodes 112a and 112b may include a first upper transparent electrode 112a and a first lower transparent electrode 112b. Here, a matrix of electrode lines intersected in the horizontal and vertical directions may be formed on the first lower transparent electrode 112b side. Thin film transistors (TFTs) may be formed at intersections of the horizontal and vertical electrode lines. In this case, the horizontal electrode lines and the vertical electrode lines may be connected to source and gate electrodes of the thin film transistors, respectively. In addition, the drain electrode of the thin film transistor may be connected to the first lower transparent electrode 112b. As such, the electrode arrangement configuration of the blind panel unit 110 may be configured by an active matrix method.

The blind panel unit 110 is not limited to the electrode arrangement configuration, and the passive panel 110 in which the first upper transparent electrode 112a and the first lower transparent electrode 112b are arranged in the form of a conductor line perpendicular to each other is passive. It may be configured to take a matrix structure.

It is preferable that the pair of polarizing films 114a and 114b are formed to transmit incident light oscillating in parallel with the rubbing direction of each of the liquid crystal alignment films 111a and 111b.

The display panel unit 120 is stacked on the blind panel unit 110 and includes a cholesteric liquid crystal material 125 injected between the pair of second transparent substrates 123 and the second transparent substrate 123. do.

Here, the second transparent substrate 123 is formed on the cholesteric liquid crystal material 125, respectively, a pair of second transparent electrodes 121a and 121b for applying the second voltage V2, and the second It is preferable to include the glass substrates 122a and 122b formed on the transparent electrodes 121a and 121b, respectively. The electrode arrangement structure of the second transparent substrate 123 may be configured in an active matrix or passive matrix manner as in the electrode arrangement configuration of the blind panel unit 110 described above.

The cholesteric liquid crystal material 125 may be formed using commercially available liquid crystal materials (Ch-100-650, CH-100-550, CH-100-450, Slichem Co., Ltd). In addition, the nematic liquid crystal material (E48, ZLI-4455-100, Merck Co., Ltd) may be formed by mixing a chiral dopant (S-811, S-1011, Merck Co., Ltd, etc.) in a certain ratio. . In addition, the nematic liquid crystal material (CH-100, Slichem Co., Ltd) may be formed by mixing a cholesteric liquid crystal material (CH-100-450, Slichem Co., Ltd) reflecting a blue wavelength band in a predetermined ratio. have. In the liquid crystal material in which the chiral dopant is mixed with the nematic liquid crystal material, the maximum wavelength band may be shortened as the ratio of the chiral dopant increases. Therefore, the ratio of the chiral dopant can determine the color reflected when the cholesteric liquid crystal mixture is in the planar state (see the literature on the mixing ratio of the nematic liquid crystal material and the chiral dopant. A study on the alignment film for the device, 1998.9 ").

On the other hand, in mixing the liquid crystal material, when the cholesteric liquid crystal material is formed by mixing the 'CH-100' to 'CH-100-450', as the mixing ratio of the nematic liquid crystal CH-100 increases The maximum reflected wavelength band can be long. That is, as the ratio of the nematic liquid crystals increases, the reflective color is shifted to the red color. Specific mixing ratios are described in the following references (Study on Electro-optical and Mechanical Properties of Flexible Displays Using Cholesteric Liquid Crystals, page 28, 2007, Master's Thesis, Hoseo University).

Next, an operation principle and an operation mode of the transparent display apparatus 100 according to the first embodiment of the present invention will be described in detail.

First, the operation principle of the blind panel 110 will be described.

The blind panel unit 110 is arranged in a direction in which the liquid crystal molecules are rotated in a predetermined direction according to the rubbing direction of the liquid crystal alignment layers 111a and 111b disposed above and below the nematic liquid crystal material 117 in a state where no voltage is applied. The polarization direction of the light incident on the nematic liquid crystal material 117 also rotates in a predetermined direction. Accordingly, the incident light is transmitted through the polarizing films 114a and 114b which are formed to transmit polarization components that oscillate in the same direction as the rubbing direction of the liquid crystal alignment layers 111a and 111b positioned above and below the blind panel 110. The unit 110 is to show a transparent state.

When the first voltage V1 is applied to the nematic liquid crystal material 117 through the first transparent electrodes 112a and 112b of the blind panel unit 110, an electric field is formed, the molecules of the nematic liquid crystal material 117 Polarization located on the nematic liquid crystal material 117 aligned in one direction along the electric field, thereby maintaining only the polarization state of the incident light and transmitting only the polarization component oscillating in the direction perpendicular to the polarization axis of the incident light. To be blocked by the film 114a. By such a principle, when the first voltage is applied to the blind panel unit 110, the incident light may not be transmitted and may be blocked / absorbed.

Next, the operation principle of the display panel 120 will be described.

The cholesteric liquid crystal material 125 of the display panel 120 has liquid crystal molecules aligned in a predetermined direction in each layer in a planar mode having a layered structure. The arrangement direction of the liquid crystal molecules has a so-called helical molecular arrangement in which the arrangement direction is constantly changed as the layer is changed. Due to the molecular arrangement, the cholesteric liquid crystal material 125 exhibits a specific property such as photonic crystal in which the refractive index is changed at regular intervals along the axis of the molecular helix. The cholesteric liquid crystal material 125 layer having a photonic crystal structure strongly reflects only incident light in a specific wavelength band among incident light in a visible light band. In this case, the wavelength band of the reflected light may be determined as follows according to the period in which a constant refractive index is repeated in the spiral liquid crystal molecular axis direction and the refractive index of the cholesteric liquid crystal material 125.

n _o p <Reflected Wavelength <n _e p

Here, n _o and n _e represent the refractive indexes of the cholesteric liquid crystal material 125 in the orthogonal direction, respectively, and p represents the period of the molecular helix, that is, the pitch (Helix Pitch).

According to the above principle, by adjusting the period of the specific molecular spiral (Helix Pitch) and the refractive index of the cholesteric liquid crystal material 125, in the planar mode to reflect only the incident light of a specific wavelength band to display the display panel 120 You can control the color. Here, the specific wavelength band of the cholesteric liquid crystal material 125 is preferably one of the wavelength bands of red (650 nm), green (550 nm), and blue (450 nm) wavelength bands that constitute the three primary colors of light.

In addition, when the second voltage V2 is applied to the cholesteric liquid crystal material 125 through the second transparent electrodes 121a and 121b, and thus a strong electric field is formed, the cholesteric liquid crystal The liquid crystal molecules of the material 125 transition to a so-called homeotropic mode that can transmit incident light in all wavelength bands while aligning along the electric field. In such a homeotropic mode, the display panel unit 120 acts as an optically transparent medium.

Hereinafter, an operation mode according to the characteristics of the blind panel unit 110 and the display panel unit 120 will be described.

1B to 1D illustrate an operation mode of the transparent display apparatus 100 when external light is present.

First, FIG. 1B is a diagram illustrating a color mode of the transparent display apparatus 100.

In the color mode, the first panel V1 is applied to the blind panel unit 110 and the voltage is not applied to the display panel unit 120. The cholesteric liquid crystal material located inside the display panel unit 120 ( The display panel 120 is operated in a planar mode by preventing an electric field from being applied to 125, and the blind panel unit 110 at a lower portion thereof is a blocking mode for blocking / absorbing the back light 15 of all wavelength bands. It works. Accordingly, the cholesteric liquid crystal material 125 reflects the incident light 10 having a specific wavelength band among the incident light in the visible light band according to the period of the molecular spiral structure, and the reflected incident light 10 is recognized by the viewer. Outside incident light 13 may be transmitted through the display panel unit 120, and may be blocked / absorbed by the blind panel unit 110 disposed on the bottom surface thereof.

As described above, as the transparent display apparatus 100 operates in the color mode, pixels having a specific color may be recognized in the observer's field of view. At this time, the pitch of the cholesteric liquid crystal material 125 may be freely designed according to the color to be displayed, but any one of red (650 nm), green (550 nm), and blue (450 nm) wavelength bands constituting three primary colors of light may be used. It is preferable that it is one wavelength band.

Next, FIG. 1C illustrates a transparent mode of the transparent display apparatus 100.

In the transparent mode, the cholesteric liquid crystal material 123 is applied to the cholesteric liquid crystal material 123 by applying the second voltage V2 through the second transparent electrodes 121a and 121b to thereby apply a strong electric field to the display panel 120. To be in a tropic state. In addition, the nematic liquid crystal material 115 is present in the transparent state by not applying a voltage to the blind panel 110 so that the background of the rear surface is recognized by the viewer's view.

1D illustrates a black mode of the transparent display device 100.

In the black mode, the cholesteric liquid crystal material 125 is applied by applying a second voltage V2 through the second transparent electrodes 121a and 121b, thereby applying a strong electric field to the cholesteric liquid crystal material 125. It is present in the homeotropic state. In addition, when the nematic liquid crystal material 117 blocks / absorbs light in the mode wavelength band by applying the first voltage V1 through the first transparent electrodes 112a and 112b of the blind panel unit 110. The incident light 15 in all wavelength bands transmitted through the cholesteric liquid crystal material 125 in the transparent state is blocked / absorbed by the blind panel unit 110, and the back light 15 is also blocked by the blind panel unit 110. Can be blocked / absorbed. Accordingly, since no light is transmitted in the black mode, the pixel can be recognized in the viewer's field of view.

The transparent display device 100 illustrated in FIGS. 1A to 1B is illustrated for one pixel, and by controlling a matrix of transparent electrodes, pixels of a corresponding region may be independently controlled.

According to the first embodiment of the present invention, each mode of the display panel 120 has stability. Accordingly, each mode can be maintained even if the voltage is not continuously applied from the outside, and thus driving can be performed at very low power. In addition, since it operates using external light, since it does not drive a light source that consumes a separate power, it has an inherent advantage of being economic in terms of power consumption.

Second Embodiment

2A to 2C are diagrams illustrating a configuration and an operation mode of the transparent display apparatus 200 according to the second embodiment of the present invention. Hereinafter, the same reference numerals are used to refer to the same configuration as the first embodiment.

First, a configuration of the transparent display apparatus 200 according to the second embodiment will be described in detail with reference to FIG. 2A.

Referring to FIG. 2A, the transparent display device 200 according to the present invention includes a blind panel unit 110, a display panel unit 120, and a front light unit 130.

The blind panel unit 110 includes a pair of nematic liquid crystal materials 117 injected between the first transparent substrate 115 and the first transparent substrate 115. Since the configuration of the blind panel unit 110 is the same as that of the blind panel unit 110 according to the first embodiment described above, a detailed description of the blind panel unit 110 according to the second embodiment is described in the first embodiment. Substitute the description of the blind panel unit 110 according to.

The display panel unit 120 is stacked on the blind panel unit 110 and includes a cholesteric liquid crystal material 125 injected between the pair of second transparent substrates 123 and the second transparent substrate 123. do. Since the configuration of the display panel unit 120 is the same as that of the display panel unit 120 according to the first embodiment described above, a detailed description of the display panel unit 120 according to the second embodiment is described in the first embodiment. It will be replaced with the description of the display panel 120 according to.

Accordingly, the transparent display apparatus 200 according to the second embodiment of the present invention may operate in the color mode shown in FIG. 2A, the transparent mode shown in FIG. 2B, and the black mode shown in FIG. 2C.

However, the transparent display device 200 according to the second embodiment of the present invention may include the front light unit 130 unlike the transparent display device 100 according to the first embodiment.

The front light unit 130 is formed on the display panel unit 120 to illuminate the display panel unit 120.

2D is a diagram illustrating a configuration of the front light unit 130.

Referring to FIG. 2D, the front light unit 130 is stacked on the light source 131 in the form of a point or line that irradiates light, the display panel unit 120, and the light 132 irradiated from the light source 131. The transparent light guide plate 133 which evenly propagates therein and the light 132 formed on one side of the light guide plate 133 and propagated into the light guide plate 133 are emitted downward to the front of the display panel 120. It may include a plurality of micro-pattern 135 for changing the path.

Here, the micro pattern 135 is preferably formed to emit light 132 incident and propagated into the light guide plate 133 in a direction perpendicular to the light guide plate 133.

The micro pattern 135 may be formed of a pattern having a small size having various forms including a prism, a lens, a pyramid, and the like.

Third Embodiment

3A and 3B illustrate a configuration of a transparent display device 300 according to a third embodiment of the present invention. Hereinafter, the same reference numerals are used to refer to the same configuration as the first embodiment.

3A and 3B, the transparent display apparatus 300 according to the present invention includes a blind panel unit 110 and display panel units 120a, 120b and 120c stacked on the blind panel unit 110. .

The blind panel unit 110 includes a pair of nematic liquid crystal materials 117 injected between the first transparent substrate 115 and the first transparent substrate 115. Since the configuration of the blind panel unit 110 is the same as that of the blind panel unit 110 according to the first embodiment described above, a detailed description of the blind panel unit 110 according to the second embodiment is described in the first embodiment. Substitute the description of the blind panel unit 110 according to.

The display panel units 120a, 120b, and 120c may include the first unit display panel 120a stacked on the blind panel unit 110 and the second unit display panel 120b stacked on the second unit display panel 120a. And a third unit display panel 120c stacked on the second unit display panel 120b. As described above, the display panel unit according to the third exemplary embodiment is not limited to three unit display panels, but at least two unit display panels are preferably stacked.

Each of the first to third unit display panels 120a, 120b, and 120c is similar to the configuration of the display panel unit 120 according to the first embodiment. However, it is preferable that specific wavelength bands of the cholesteric liquid crystal material 123 located in the first to third unit display panels 120a, 120b, and 120c are different wavelength bands. More specifically, the pitch of each cholesteric liquid crystal material 123 can be freely adjusted according to the color to be expressed, but the red (650 nm), green (550 nm), and blue (450 nm) wavelengths that constitute the three primary colors of light It is preferable to have a specific wavelength band in any one of the bands, but adjusted to different wavelength bands. For example, the first unit display panel 320a has a characteristic of a red (650 nm) wavelength band, the second unit display panel 320b has a characteristic of a green (550 nm) wavelength band, and a third unit display panel ( The pitch of the cholesteric liquid crystal material 323 configured in each may be adjusted so that 320c may have a characteristic of a blue (450 nm) wavelength band.

As shown in FIGS. 3A and 3B, the display panel units 120a, 120b, and 120c use two or more unit display panels having different pitches to reflect incident light of different wavelength bands, thereby reflecting multicolor. Type transparent display device can be implemented.

As shown in FIG. 3A, when the color to be expressed is red, the second unit display panel 120b applies a 2-1 voltage to the first unit display panel 120a reflecting blue and reflects green. A second voltage is applied to the first unit display panel 120a and the second unit display panel 120b in a homeotropic mode, and the third unit display panel 120c that reflects red is in a plane mode. By controlling with, the desired color (red) can be expressed.

In addition, as shown in FIG. 3B, when the color to be expressed is yellow, the first unit display panel 120a reflecting blue is controlled in the homeotropic mode, and the second unit display panel reflecting green ( 120b) and the third unit display panel 120c reflecting red are controlled in a plane mode so that the two colors (green and red) are mixed to express a desired color.

The transparent display device 300 illustrated in FIG. 3 is illustrated for one pixel, and each pixel may be independently controlled by a matrix composed of respective transparent electrodes.

[Modification of First Embodiment]

4A and 4B illustrate a configuration and an operation mode of the transparent display device 400 according to a modification of the first embodiment of the present invention.

The transparent display device 400 includes a plurality of pixels 400a, 400b, and 400c as illustrated in FIGS. 4A and 4B. Here, each of the pixels 400a, 400b, and 400c includes the transparent display device 100 according to the first embodiment. In addition, pixels adjacent to each other are formed by injecting cholesteric liquid crystal materials 125a, 125b, and 125c having different pitches from each other. That is, between pixels adjacent to each other may mean that a specific wavelength band has different wavelength band characteristics. At this time, the pitch of the injected cholesteric liquid crystal materials (125a, 125b, 125c) can be freely adjusted according to the color to be expressed, but red (650nm), green (550nm), or blue (450nm) constituting the three primary colors of light It is desirable to adjust the wavelength band.

As shown in FIG. 4A, each pixel 400a, 400b, or 400c reflects only incident light 42 and 43 of a specific wavelength band (pixels 400b and 400c), or the incident light 41 and the rear surface of all wavelength bands. By blocking the light 40 (pixel 400a), a single transparent display device 400 composed of two or more pixels can be implemented so that various colors can be simultaneously displayed. Here, one pixel and adjacent pixels are separated into partitions, and the partitions may be formed using a dry structure method including a reactive ion etching, a microstructure processing process such as sand blaster, imprint, or the like.

As shown in FIG. 4B, a transparent mode, a black mode, or a color mode depends on whether each of the display panel unit 120 formed in each pixel 400a, 400b, or 400c and the blind panel unit 410 disposed below the respective operation unit operate. It can also work as either. Accordingly, according to the modification of the first embodiment, it is possible to express different colors at different positions on one panel.

Although the blind panel unit 110 described in the embodiment of the present invention has been shown to operate in a transmission mode when no electric field is applied and in a blocking mode when an electric field is applied, this should be understood as an example and should be understood as an electric field. And thus the operation in the transmission or blocking mode may be determined in various ways depending on the rubbing direction of the liquid crystal alignment layer and the arrangement direction of the polarizing film (not shown) formed on the upper and lower surfaces of the blind panel 110. There will be.

In addition, two or more embodiments of the above-described embodiments may be configured to be combined with each other. By doing so, the features of each embodiment can be expressed simultaneously, and more effectively achieve the goal pursued by the present invention.

As described above, those skilled in the art to which the present invention pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the following claims rather than the above description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

1A to 1D illustrate a configuration and an operation mode of a transparent display device 100 according to a first embodiment of the present invention.

2A to 2C are diagrams illustrating a configuration and an operation mode of the transparent display device 200 according to the second embodiment of the present invention.

2d is a diagram showing the configuration of the front light unit 130 according to the second embodiment of the present invention.

3A to 3B show the configuration of a transparent display device 300 according to a third embodiment of the present invention.

4A and 4B illustrate a configuration and an operation mode of a transparent display device 400 according to a modification of the first embodiment of the present invention.

********** Description of the symbols for the main parts of the drawings **********

100, 200, 300, 400: transparent display device

110: blind panel portion

120: display panel unit

120a: first unit display panel

120b: second unit display panel

120c: third unit display panel

130: frontlight unit

Claims (10)

A pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmit incident light in all wavelength bands, depending on the first voltage applied between the first transparent substrates. A blind panel unit blocking incident light in a wavelength band; And Stacked on the blind panel portion, including a pair of second transparent substrate and a cholesteric liquid crystal material injected between the second transparent substrate, and reflects the incident light in a specific wavelength band of incident light in the visible light band, Display panel unit for transmitting incident light of all wavelength bands according to the second voltage applied between the second transparent substrate Transparent display device comprising a. A pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmit incident light in all wavelength bands, depending on the first voltage applied between the first transparent substrates. A blind panel unit blocking incident light in a wavelength band; Stacked on the blind panel portion, including a pair of second transparent substrate and a cholesteric liquid crystal material injected between the second transparent substrate, and reflects the incident light in a specific wavelength band of incident light in the visible light band, A display panel unit configured to transmit incident light of all wavelength bands according to a second voltage applied between the second transparent substrates; And A transparent frontlight unit formed on the display panel unit to illuminate the display panel unit Transparent display device comprising a. The method according to claim 1 or 2, The specific wavelength band of the display panel unit, A transparent display device, wherein the wavelength band is any one of red, green, and blue wavelength bands. The method of claim 2, The front light unit, A light source for irradiating light; A transparent light guide plate stacked on the display panel and configured to evenly propagate light emitted from the light source therein; And And a plurality of micro patterns formed on one side of the light guide plate and configured to change an optical path so that light propagated into the light guide plate is emitted to the front of the display panel. A pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmit incident light in all wavelength bands, depending on the first voltage applied between the first transparent substrates. A blind panel unit blocking incident light in a wavelength band; And A plurality of stacked on the blind panel portion, each of the pair of the second transparent substrate and the cholesteric liquid crystal material injected between the second transparent substrate, and reflects the incident light in a specific wavelength band of incident light in the visible light band A display panel unit configured to transmit incident light in all wavelength bands according to second voltages applied between the second transparent substrates, The specific wavelength band of each of the plurality of stacked display panel units is a different wavelength band. The method of claim 5, The display panel unit, A first unit display panel stacked on the blind panel unit; A second unit display panel stacked on the second unit display panel; And A third unit display panel stacked on the second unit display panel, Specific wavelength bands of each of the first unit display panel, the second unit display panel, and the third unit display panel include: A transparent display device, wherein the wavelength band is any one of red, green, and blue wavelength bands. A pair of first transparent substrates and a nematic liquid crystal material injected between the first transparent substrates, and transmit incident light in all wavelength bands, depending on the first voltage applied between the first transparent substrates. A blind panel unit blocking incident light in a wavelength band; And Stacked on the blind panel portion, including a pair of second transparent substrate and a cholesteric liquid crystal material injected between the second transparent substrate, and reflects the incident light in a specific wavelength band of incident light in the visible light band, A display panel unit configured to transmit incident light in all wavelength bands according to a second voltage applied between the second transparent substrates, Wherein the blind panel unit and the display panel unit constitute one pixel, and specific wavelength bands between display panel units of adjacent pixels are different wavelength bands. The method according to claim 1, 2, 5 or 7, The first transparent substrate, A pair of liquid crystal alignment layers respectively formed on the nematic liquid crystal material and for aligning liquid crystal molecules of the nematic liquid crystal material in a predetermined direction; A pair of first transparent electrodes formed on the liquid crystal alignment layer, respectively, for applying the first voltage; A pair of glass substrates respectively formed on the first transparent electrode; And Transparent display device comprising a pair of polarizing films formed on the glass substrate, respectively. The method of claim 8, The liquid crystal aligning film, The rubbing direction of each of the liquid crystal alignment layer is formed to be different by 90 degrees, The polarizing film, And transmit incident light oscillating in parallel with a rubbing direction of each of the liquid crystal alignment layers. The method according to claim 1, 2, 5 or 7, The second transparent substrate, A pair of second transparent electrodes respectively formed on the cholesteric liquid crystal material and configured to apply the second voltage; And And a glass substrate formed on each of the second transparent electrodes.

Images