KR20170127290A - Display device - Google Patents

Abstract

The present invention relates to a display device, and more particularly, to a display device capable of preventing the heat generation of a display device and increasing the frequency of the display device. To this end, the display apparatus of the present invention includes a divider for distributing light provided from a light source through a plurality of branch optical fibers to a plurality of optical fibers, an attenuator connected to each of the plurality of branch optical fibers to attenuate the distributed light, and a display panel having a plurality of pixels connected to the ends of the plurality of branch optical fibers.

Description

Display device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly to a display device capable of preventing heat generation of a display device and increasing a pixel per inch (ppi) of the display device.

A flat panel display (FPD) is a small-sized system such as a portable computer such as a notebook computer, a PDA, or a mobile phone terminal as well as a monitor of a desktop computer in place of a conventional cathode ray tube (CRT) And an outdoor display board.

Currently, flat panel display devices that are commercially available include a liquid crystal display, a plasma display panel, and a light emitting diode (LED) display device. In the dual LED display device, As a display device using an effect, there is an advantage such as a simple driving method, low-temperature drive, and high reliability.

1 is a view showing a conventional display device.

As shown in Fig. 1, the display device 10 includes a display panel 11 on which an image is implemented, and a control unit 12 that controls the display panel so that an image is realized.

The display panel 11 has a plurality of pixels PX arranged in a matrix form on a substrate and each pixel PX is connected to the control unit 12 through a connection line CL.

The controller 12 applies a data voltage to each pixel PX through a connection line CL in response to a video signal (not shown) input from an external system (not shown). At this time, each of the pixels PX can be independently driven by the control unit 12.

2 is an enlarged view of a pixel of a conventional display device.

As shown in FIG. 2, each pixel PX is composed of a bulb-type red light emitting diode R, a green light emitting diode G, and a blue diode B, respectively.

The connection lines CL are connected to the cathodes (not shown) and the anodes (not shown) of the respective light emitting diodes R, G and B and connected to the light emitting diodes R, B are applied with a data voltage. Due to the applied data voltage, the semiconductor chip (not shown) of the light emitting diodes R, G, and B emits light by an electroluminescence effect.

The intensity of the light emitted from each of the light emitting diodes R, G, and B is adjusted by the controller 12 to realize the image of the display device 10.

However, the LED display device 10 that implements an image by the above method has the following problems.

First, since the light emitting diodes R, G, and B constituting each pixel PX are driven through the connection line CL, the resistance of the light emitting diodes R, G, and B and the connection line CL Heat is generated. This may cause deterioration of the light emitting diodes (R, G, B) and poor image quality of the display device 10. [

Secondly, due to the semiconductor chip, the anode, and the cathode of the light emitting diodes R, G, and B, there is a limitation in minimizing each of the light emitting diodes R, G, and B so that the pixel PX is also minimized There is a limit. Therefore, the display device 10 can not realize a high pixel per inch (ppi).

In addition, due to the supporting structure on the substrate for supporting the light-emitting diodes R, G and B, there arises a problem that it is difficult to reduce the weight of the display device.

An object of the present invention is to provide a liquid crystal display device capable of increasing the number of pixels per inch (ppi) by eliminating heat problems by disposing an LED light source outside the display panel.

According to an aspect of the present invention, there is provided a display apparatus including a divider for distributing light provided from a light source to a plurality of branching optical fibers through an optical fiber, an attenuator connected to each of the branching optical fibers for attenuating the divided light, And a display panel having a plurality of pixels connected to ends of the plurality of branch optical fibers. Here, the plurality of branch optical fibers may be arranged in a line arrangement, a triangular arrangement, or a square arrangement. And a plurality of pixels may be arranged in a regular interval structure or a honeycomb structure.

The display device according to the present invention has the following effects.

First, the display device according to the present invention is provided with a high-output LED light source disposed outside the display panel, and a heat dissipator is provided to prevent the LED light source from generating heat, do.

Second, the diameter of the branch optic fibers connected to each pixel is half the diameter of the LEDs disposed in the pixels of the conventional display device. Thus, the pixel size can also be reduced accordingly. Further, the pixels can be arranged more densely according to the arrangement structure of the above-mentioned pixels. Thereby, the pixel per inch (ppi) of the display device can be increased.

In addition, since only a plurality of branch optical fibers and a frame capable of fixing only the black matrix are provided in the pixels of the display panel of the present invention, the weight of the display device can be reduced.

1 is a view showing a conventional display device.
2 is an enlarged view of a pixel of a conventional display device.
3 is a view showing a display device according to the present invention.
4 is a view showing a distributor of a display device according to the present invention.
5 is a view showing an attenuator and a control unit of the display apparatus according to the present invention.
6A to 6D are views showing embodiments of branch optical fiber arrangement shapes in a pixel of a display device according to the present invention.
Figs. 7A to 7C are views showing embodiments of the cross-sectional shape of branch optical fibers of the display device according to the present invention.
8A to 8C are views showing embodiments of arrangement shapes of branch optical fibers and black matrix in each pixel of the display device according to the present invention.

Hereinafter, a display device according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a view showing a display device according to the present invention.

3, the display device 100 according to the present invention includes a display panel 110 in which an image is implemented, an LED light source 120 that provides light to the display panel, A distributor 130, an attenuator 140 for attenuating the distributed light, and a controller 150 for controlling the attenuator.

The LED light source 120 receives a voltage from an external power source (not shown) and emits light to the optical fiber FB. Here, the light emitted to the optical fiber FB may be red light, green light, blue light, and white light. In order to output the multi-color light, each LED light source 120 may use another kind of semiconductor chip (not shown). That is, the light emitted from the LED light source 120 has different intrinsic wavelengths depending on the type of the semiconductor chip embedded in the LED light source 120. For example, when the semiconductor chip is gallium arsenide (GaAsP), red light having a wavelength of about 700 nm is generated, and when the semiconductor chip is gallium phosphide (GaP), green light having a wavelength of about 540 nm is generated, In the case of gallium nitride (GaN), blue light having a wavelength of about 480 nm is generated. Further, the white light can be generated by combining the generated light of multiple colors.

Also, since the light generated from the LED light source 120 is distributed to each pixel PX through the optical fiber FB, the LED light source 120 must have high output. For example, when the total amount of light in one pixel PX is 0.1235 lm and the total number of pixels PX of the display panel 110 is 1214, the LED light source 120 emits light of 150 lm . Accordingly, the power consumption of the LED light source 120 in the semiconductor chip is increased in proportion to the intensity of the generated light. Accordingly, a heat dissipator (not shown) for preventing the semiconductor chip and the package module (not shown) that surrounds the semiconductor chip from being deteriorated by the heat generated when the high-power LED light source 120 consuming a large amount of power is emitted can be used. Such a heat dissipator can dissipate the heat generated from the semiconductor chip to the outside and cool it, and it can be attached to the semiconductor chip via an adhesive means made of a material having high thermal conductivity. However, the light source is not limited to the LED light source, but may be an OLED (Organic Light Emitting Diode) light source, a CNT (Carbon Nano Tube) light source, and a PLS (Plasma Lighting System).

The optical fiber FB receives the multi-colored light from the LED light source 120 and transmits it to the distributor 130. Here, the optical fiber FB may be separated so that light of multiple colors does not interfere with each other and light loss is not generated. For example, the optical fiber FB may include a red optical fiber irradiated with the red light, a green optical fiber irradiated with the green light, a blue optical fiber irradiated with the blue light, and a white optical fiber irradiated with the white light.

The distributor 130 receives the light from the LED light source 120 through the optical fiber FB and distributes the light to a plurality of branch optical fibers BFB.

4 is a view showing a distributor of a display device according to the present invention.

As shown in FIG. 4, the splitter 130 multiplexes the optical fibers FB in Y-shape, and is connected to a plurality of branch optical fibers BFB. The light incident from the LED light source 120 through the optical fiber FB in the Y-shaped connecting portion is uniformly separated. In this way, the light is uniformly separated through a plurality of Y-shaped connection portions, and the finally separated light is output to each branch optical fiber (BFB).

For example, each of the red light, the green light and the blue light is incident on the distributor 130 through a red optical fiber, a green optical fiber, and a blue optical fiber, and the multi-colored light is separated through Y- do. The separated red light, green light and blue light are separately incident on the red branch optical fiber (R-BFB), the green branch optical fiber (G-BFB) and the blue branch optical fiber (B-BFB), respectively.

The attenuator 140 is connected to a plurality of branch optical fibers BFB to attenuate the distributed multi-color light. Here, the attenuator 140 may be a Mach-Zehnder modulator.

5 is a view showing an attenuator and a control unit of the display apparatus according to the present invention.

5, the attenuator 140 of the display device 100 according to the present invention includes a first waveguide A and a second waveguide B connected in parallel in the middle of one branch optical fiber BFB, A first electrode 141, a second electrode 142 and a third electrode 143 disposed on the side surfaces of the first waveguide A and the second waveguide B, respectively.

Light incident through the branch optical fibers (BFB) is distributed to the first waveguide (A) and the second waveguide (B). At this time, different voltages are applied to the first electrode 141, the second electrode 142, and the third electrode 143 through the control unit 150. Due to the voltage thus applied, a current flows through the first waveguide A and the second waveguide B, and the holes and electrons existing in the first waveguide A and the second waveguide B The ratio is changed. As a result, the refractive indexes of the light passing through the first waveguide A and the second waveguide B are different from each other, which causes the phase difference of the light. The light having such a phase difference interferes with each other at the connecting portion C of the first waveguide A and the second waveguide B and consequently the intensity of the light output to the branch optical fiber BFB changes.

For example, when the phase difference of the light passing through the first waveguide (A) and the second waveguide (B) is zero or 2 ?, the output light may be constructively interfered. Conversely, when the phase difference of the light passing through the first waveguide A and the second waveguide B is? Or?, The output light may be canceled out. In order to control the phase difference of light more finely, the control unit 150 may control the voltage applied to each electrode or adjust the impurity concentration in each waveguide (A, B).

A plurality of pixels PX are defined in a frame (not shown) made of metal or plastic, for a display panel (not shown in FIG. 3, not shown). At least one branch optical fiber (BFB) is connected to each pixel PX of the display panel 110. The intensity of the light distributed from the LED light source 120 through the branch optical fiber BFB is adjusted by the attenuator 140 and output. An image is displayed on the display panel 110 by expressing gradation in each pixel PX through the color combination of the branch optical fibers BFB. For example, a green branch optical fiber (not shown, G-BFB in Fig. 6A) for outputting red light to each pixel PX (see RBFB not shown in Fig. 6A) A blue branch optical fiber (not shown, B-BFB in FIG. 6A) and a white branch optical fiber (not shown, W-BFB in FIG. 6D) to which white light is output can be connected. The image can be implemented through a combination of multicolor light output from the plurality of branch optical fibers (BFB).

6A to 6D are views showing embodiments of branch optical fiber arrangement shapes in a pixel of a display device according to the present invention.

As shown in FIG. 6A, one pixel PX includes a red branch optical fiber R-BFB for outputting red light, a green branch optical fiber G-BFB for outputting green light, and a blue branch optical fiber B- BFB) may be arranged in a line. This is the most basic layout structure, and is in the form of a rectangular pixel (PX), so it is suitable for wide display aspect ratio.

As shown in FIG. 6B, one pixel PX includes a red branch optical fiber R-BFB for outputting red light, a green branch optical fiber G-BFB for outputting green light, and a blue branch optical fiber B- BFB) may be arranged in a triangular shape. Accordingly, the pixel PX may be formed in a triangular shape. In addition, the plurality of triangular-shaped pixels PX may be arranged in a regular interval structure. Thus, the display panel 110 can implement various aspect ratios.

As shown in FIG. 6C, one pixel PX includes a red branch optical fiber R-BFB for outputting red light, a green branch optical fiber G-BFB for outputting green light, and a blue branch optical fiber B- BFB) may be arranged in a triangular shape. Accordingly, the pixel PX may be formed in a triangular shape. In addition, a plurality of triangular-shaped pixels PX may be arranged in a honeycomb structure. The honeycomb structure refers to a structure in which six triangular-shaped pixels (PX) are successively arranged in a regular hexagon. Thereby, the space utilization can be increased as compared with the above-described regular interval structure arrangement, and the pixel per inch (ppi) can be increased.

6D, a pixel PX includes a red branch optical fiber R-BFB for outputting red light, a green branch optical fiber G-BFB for outputting green light, a blue branch optical fiber B- BFB and white light W-BFB outputting white light may be arranged in a quadrangle. Accordingly, the pixel PX may be formed in a rectangular shape. In addition, a plurality of square-shaped pixels PX may be arranged in a regular interval structure. Thus, the display panel 110 can implement various aspect ratios. Further, since the white light can be output through the white branch optical fiber (W-BFB), the brightness of the display panel 110 can be increased.

By arranging the branch optical fibers BFB in each pixel PX, the size of the pixel PX can be reduced. For example, the branch optical fiber BFB connected to each pixel PX has a diameter of 0.25 mm, so that the length of each pixel PX can be reduced to 0.75 mm to 1 mm. Further, the pixels PX can be arranged more densely according to the arrangement structure of the pixels PX described above. Thereby, the pixel per inch (ppi) of the display device 100 can be increased.

Figs. 7A to 7C are views showing embodiments of the cross-sectional shape of branch optical fibers of the display device according to the present invention.

As shown in FIG. 7A, the end face BFB-a of the branch optical fiber BFB from which the light is output in each pixel PX may be flat. As the end face BFB-a of the branched optical fiber BFB is flat, the light output from each branched optical fiber BFB can be widely radiated. Thereby, the viewing angle of the display panel 110 can be secured.

As shown in FIG. 7B, the end face BFB-b of the branch optical fiber BFB from which light is output from each pixel PX may be hemispherical. By forming the hemispherical shape of the end face (BFB-b) of the branched optical fiber (BFB), light can be outputted in a straight direction in each branched optical fiber (BFB). Thus, the brightness of the display panel 110 can be secured.

As shown in FIG. 7C, the end face BFB-c of the branched optical fiber BFB from which light is output from each pixel PX may be aspherical. As the end face (BFB-c) of the branched optical fiber (BFB) forms an aspherical shape, the light output from each branched optical fiber (BFB) can be emitted in a directional manner and widely. Thereby, the viewing angle and the luminance of the display panel 110 can be secured.

8A to 8C are views showing embodiments of arrangement shapes of branch optical fibers and black matrix in each pixel of the display device according to the present invention.

8A, a red branch optical fiber (R-BFB), a green branch optical fiber (G-BFB), and a blue branch optical fiber (B-BFB) are connected to one pixel PX without a black mattress . However, even in this case, a frame defining the pixel PX may have its own shielding effect. By not adding a separate structure other than the frame supporting the branch optical fibers (BFB), the process cost can be reduced.

(R-BFB), a green branch optical fiber (G-BFB), and a blue branch optical fiber (B-BFB) including a black mattress for shielding external light are provided in one pixel PX, Lt; / RTI > Here, the black matrix BM is disposed on the same plane as the end face of the branch optical fiber BFB. By arranging the black matrix BM in this manner, the interference effect due to the light output from the optical fibers BFB of different colors in the same pixel PX can be minimized. For example, the green light and the blue branch optical fiber (B-BFB) output from the green branch optical fiber (G-BFB) due to the black matrix (BM) arrangement structure, based on the red light output from the red branch optical fiber (R- It is possible to minimize the interference effect of the blue light output from the light source. Thereby, external light can be blocked, and the screen immersion feeling can be increased.

8B, a green branch optical fiber (G-BFB) and a blue branch optical fiber (B-BFB), including a black mattress for shielding external light, are provided in one pixel PX, Lt; / RTI > Here, the black matrix BM may be arranged so that the end surfaces of the branch optical fibers BFB protrude from the plane on which the black matrix BM is disposed. By arranging the black matrix BM in this way, the light output from each branch optical fiber BFB can be widely radiated. Therefore, the viewing angle of the display panel 110 can be secured.

As described above, the display device according to the present invention has the following effects.

First, the display apparatus according to the present invention is provided with a heat emitting element for separately arranging a high-output LED light source outside the display panel, and for preventing the LED light source from generating heat. This makes it possible to solve the problem of heat generation, which is a problem of the conventional display device.

Second, the diameter of the branch optic fibers connected to each pixel is half the diameter of the LEDs disposed in the pixels of the conventional display device. Thus, the pixel size can also be reduced accordingly. Further, the pixels can be arranged more densely according to the arrangement structure of the above-mentioned pixels. Thereby, the pixel per inch (ppi) of the display device can be increased.

In addition, since only a plurality of branch optical fibers and a frame capable of fixing only the black matrix are provided in the pixels of the display panel, the weight of the display device can be reduced.

While a number of embodiments have been described in detail above, it should be construed as being illustrative of preferred embodiments rather than limiting the scope of the invention. Therefore, the invention should not be construed as limited to the embodiments described, but should be determined by equivalents to the appended claims and the claims.

100: display device 110: display panel
120: LED light source 130: distributor
140: attenuator 150: control unit
FB: Fiber Optic BFB: Branch Fiber

Claims (12)

A light source for providing light;
A splitter that receives the light through an optical fiber and distributes the light to a plurality of branched optical fibers;
An attenuator connected to each of the plurality of branch optical fibers to attenuate the distributed light; And
And a display panel having a plurality of pixels connected to ends of the plurality of branched optical fibers. The method according to claim 1,
The light is composed of red light, green light and blue light,
Wherein the optical fiber comprises a red optical fiber irradiated with the red light, a green optical fiber irradiated with the green light, and a blue optical fiber irradiated with the blue light,
The plurality of branch optical fibers are composed of a plurality of red branch optical fibers, a plurality of green branch optical fibers, and a plurality of blue branch optical fibers,
Wherein each of the plurality of pixels is connected to the red branch optical fiber, the green branch optical fiber, and the blue branch optical fiber. 3. The method of claim 2,
Wherein the red branch optical fiber, the green branch optical fiber, and the blue branch optical fiber are arranged in a line in each pixel. 3. The method of claim 2,
Wherein the red branch optical fiber, the green branch optical fiber, and the blue branch optical fiber are arranged in a triangular shape in each pixel,
Wherein the plurality of pixels are arranged in a regular interval structure. 3. The method of claim 2,
Wherein the red branch optical fiber, the green branch optical fiber, and the blue branch optical fiber are arranged in a triangular shape in each pixel,
Wherein the plurality of pixels are arranged in a honeycomb structure. The method according to claim 1,
The light is composed of red light, green light, blue light and white light,
Wherein the optical fiber comprises a red optical fiber irradiated with the red light, a green optical fiber irradiated with the green light, a blue optical fiber irradiated with the blue light, and a white optical fiber irradiated with the white light,
The plurality of branch optical fibers are composed of a plurality of red branch optical fibers, a plurality of green branch optical fibers, a plurality of blue branch optical fibers, and a plurality of white branch optical fibers,
Wherein each of the plurality of pixels is connected to the red branch optical fiber, the green branch optical fiber, the blue branch optical fiber, and the white branch optical fiber,
Wherein the red branch optical fiber, the green branch optical fiber, the blue branch optical fiber, and the white branch optical fiber are arranged in a square shape in each pixel. The method according to claim 1,
Wherein end faces of the branched optical fibers are flat. The method according to claim 1,
Wherein each of the branched optical fibers has a hemispherical end surface. The method according to claim 1,
And the end surfaces of the branched optical fibers are aspherical. The method according to claim 1,
Further comprising a black matrix disposed inside the respective pixels in the same plane as the end surfaces of the branch optical fibers. The method according to claim 1,
Further comprising a black matrix inside each pixel,
And an end of the branch optical fiber is connected to the pixel so that the branched optical fiber is protruded from the plane on which the black matrix is disposed. The method according to claim 1,
And a controller coupled to the attenuator to control the attenuator.

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