KR20090082708A - Liquid crystal display device - Google Patents

Abstract

A liquid crystal display device is provided to offer the light, which is reflected on an inclined reflective surface of a stepped reflective member after being offered from a light source, uniformly to an LCD panel. A liquid crystal panel(160) displays an image. A light emitting device(145) is equipped at one side of a lower part of an LCD panel. A stepped reflective member(140) is equipped at a lower part of the LCD panel. A stepped light guide pattern having an inclined reflective surface is formed at one side of the stepped reflective member which corresponds to the LCD panel. The stepped reflective member perpendicularly guides the reflected light to the LCD panel.

Description

Liquid crystal display {LIQUID CRYSTAL DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly, to incline light provided from a light source provided at a predetermined interval at a lower side or a lower portion of a liquid crystal panel on which an image is implemented. The present invention relates to a liquid crystal display device which is intended to reflect through a reflective surface and guide the light vertically toward the front surface of the liquid crystal panel.

In general, the direct type back-light used in the large-size liquid crystal display provides direct light emitted from a cold cathode tube (CCFL) to the liquid crystal panel. The light provided from the light is reflected through a reflecting plate disposed below the light, and is provided to the front liquid crystal panel. At this time, a milky white scattering plate such as a diffuser plate is additionally disposed in the light reflection path, so that light having a locally uniform illuminance is illuminated on the liquid crystal display. However, this method brings the liquid crystal display to a large and complicated model due to the problem of thickening the backlight device.

For this reason, it is a two-pole device that emits light only when a current passes in recent years. It uses a light emitting diode (LED), which has fast response speed, low power consumption and semi-permanent life, as a surface light source device. In addition to reducing the backlight of the display device, the overall brightness is also improved. First of all, the next-generation LCD can replace the cold cathode tube backlight device by reproducing natural color and high-definition images compared to the existing cold cathode tube, and resolving the afterimage problem of video and using eco-friendly products without mercury. The core parts of the car are also good.

Hereinafter, the conventional direct type liquid crystal display will be briefly described with reference to the accompanying drawings.

1 is a cross-sectional view of a liquid crystal display device having a direct type LED backlight device, and FIG. 2 is a plan view illustrating a plurality of PCBs arranged and fixed on a lower cover of FIG. 1.

Referring to FIGS. 1 and 2, the liquid crystal display device has a lower side on the basis of the main support 50 made of a synthetic resin or a stainless steel (SUS STEEL) mold having a rectangular frame (or frame). It is provided with a backlight device (not shown) on the lower cover 30, the liquid crystal panel 10 is mounted on the upper side. The upper cover 60 covers the front (or upper) edge of the liquid crystal panel 10 and is assembled and fastened to the main support 50.

Here, the liquid crystal panel 10 is a thin film transistor (TFT) array substrate and a color filter substrate bonded to each other, and includes a liquid crystal injected therebetween. TFTs that perform a switching role are formed on the TFT array substrate in a matrix form, and red (R), green (G), and blue (B) color filters are formed on the color filter substrate to display an image.

The backlight device for providing light to the liquid crystal panel 10 configured as described above includes one LED chip (or LED device) of R, G, and B provided on the lower cover 30 to emit light. LED array 36 formed of a cluster (cluster) of the LED array consisting of at least one line, a plurality of PCB (Printed Circuit Board) (PCB) 34 formed on the LED array, and the PCB 34 A reflection plate 32 formed on the entire lower surface of the region where) is driven to reflect light, a diffusion plate 42 provided above the LED array to diffuse light emitted from the LED array, and a diffusion plate thereof. The prism sheet 44 used for the purpose of refracting the light diffused by the 42 to increase the front luminance of the light, and a protective sheet 46 for protecting the prism sheet 44 are included.

Through the above configuration, the light emitted from the LED package 36 forming one cluster is mixed with each other to generate white light, and the white light is emitted to the outside of the cluster again, wherein the emitted light is manufactured by the LED Due to the radiation characteristics related to the light source, it tends to be concentrated on the center of the cluster or on the center of the LED chip or LED element.

Therefore, in order to smoothly mix colors due to such a phenomenon of LEDs in the related art, as shown in FIG. 1, the separation distance l between the LED package 36, that is, the light source and the liquid crystal panel 10 is sufficiently sufficient. Or the LED package 36 was arrange | positioned and formed on the PCB 34 by securing it, or narrowing the distance between a light source and a light source.

As a result, a sufficient separation distance (l) between the LED package and the liquid crystal panel is required. As a result, the thickness of the liquid crystal display device is limited, and as a result, the quantity of the light source is increased by reducing the distance between the light source and the light source. The cost has increased.

The present invention has been made to solve the above problems, the object is that the light provided from the light source provided at one side of the lower side of the liquid crystal panel that is implemented image or provided at regular intervals in the lower portion of the stepped reflective member The present invention provides a liquid crystal display device configured to be reflected through a photo reflective surface and uniformly provided to a liquid crystal panel.

The liquid crystal display device according to the first embodiment of the present invention for achieving the above object is a liquid crystal panel in which an image is implemented, the light emitting means provided on one side of the lower portion of the liquid crystal panel to provide light, and the light emitting means one side A stepped light induction pattern having a reflective surface inclined on one surface of the liquid crystal panel and facing the liquid crystal panel to reflect the light provided from the light emitting means through the inclined reflective surface to reflect the liquid crystal. It is guided perpendicular to the panel, characterized in that it comprises a stepped reflective member whose thickness increases as the distance from the light emitting means increases.

In addition, the liquid crystal display device according to the second embodiment of the present invention is a liquid crystal panel in which an image is implemented, a plurality of light emitting means arranged and provided at regular intervals under the liquid crystal panel to provide light, and the light emitting means A stepped light induction pattern having a reflection surface inclined on one surface of the liquid crystal panel, which is arranged and arranged on the lower side of the liquid crystal panel, is provided on one side, and the light provided from the light emitting means is provided through the inclined reflection surface. Reflecting is guided perpendicularly to the liquid crystal panel, characterized in that it comprises a plurality of step-shaped reflective member that increases in thickness as the distance from the light emitting means increases.

A liquid crystal display according to a third embodiment of the present invention is a pair of liquid crystal panels arranged at regular intervals to implement an image, and the light emitting is provided on one side between the two liquid crystal panels and a plurality of layers to provide light Means and a light emitting means provided on one side between the two liquid crystal panels, and a stepped light induction pattern having inclined reflecting surfaces on both sides is formed to receive light from the light emitting means through the inclined reflecting surface. It is characterized in that it comprises a stepped reflective member to reflect and guide each perpendicular to the liquid crystal panel, the thickness increases as the distance from the light emitting means increases.

In addition, the liquid crystal display device according to the fourth embodiment of the present invention is a pair of liquid crystal panels arranged at regular intervals to implement an image, a support plate provided between the two liquid crystal panels, the support plate and each liquid crystal A plurality of light emitting means arranged and provided at regular intervals between the panels to provide light, and the light emitting means on one side provided between the support plate and each of the liquid crystal panel, each of which is mirrored on one surface facing the liquid crystal panel A stepped light induction pattern having a photographic reflecting surface is formed to reflect light provided from the light emitting means through the inclined reflecting surface and guide the light perpendicular to the liquid crystal panel, and the distance increases from the light emitting means. Characterized in that comprises a stepped reflective member.

As a result of the above configuration, the present invention can ensure a relatively long light path for color mixing between the light source and the liquid crystal panel in the case of the LED light source can obtain a light of uniform brightness.

In addition, since the separation distance between the light source and the liquid crystal panel for light mixing is not particularly limited, it is possible to reduce the thickness of the liquid crystal display.

In addition, it is possible to implement a large-scale liquid crystal display without increasing the number of light sources such as LED, thereby reducing the cost.

Hereinafter, the configuration will be described in more detail with reference to the accompanying drawings.

3 is an exploded perspective view of a liquid crystal display according to a first exemplary embodiment of the present invention, FIG. 4 is a fastening cross-sectional view of FIG. 3, and FIG. 5 is a perspective view showing the stepped reflective members of FIGS. 3 and 4.

3 to 5, the liquid crystal display according to the first embodiment of the present invention is provided on the liquid crystal panel 160, and the lower side of the liquid crystal panel 160, the image is implemented to provide light The light emitting means 145 and the light emitting means 145 are provided on one side and are provided below the liquid crystal panel 160 and have an inclined reflective surface on one surface corresponding to (or facing) the liquid crystal panel 160. A stepped light induction pattern is formed to reflect the light provided from the light emitting means 145 through the inclined reflective surface to guide the light perpendicular to the liquid crystal panel 170. As the distance from the light emitting means 145 increases, It characterized in that it comprises a stepped reflecting member 140 whose thickness gradually increases.

First, light emitting devices 143 and 145 are provided at one side of the lower cover 100 made of an electrogalvanized steel sheet (EGI) or aluminum (Al). The light emitting devices 143 and 145 include light emitting means 145 formed by fixing an LED element or an LED chip on a printed circuit board (PCB) and a housing 143 fixing the light emitting means 145. have. In this case, the light emitting unit 145 may be fixed to the side wall (or the main support 150) of the lower cover 100 without the housing 143, and the PCB may be a flexible PCB (FPCB).

However, when the light emitting means 145 in the present invention is a fluorescent lamp such as CCFL, External Electrode Florescent Lamp (EEFL) and Hot Cathode Fluorescent Lamp (HCFL), etc., instead of the LED device or LED chip, In order to protect against, the housing 143 in the present invention may be required.

In addition, the LED elements or LED chips constituting the light emitting means 145 are arranged and fixed at a predetermined interval on the PCB, such LED elements or LED chips are formed in an array of "RGBRGBRGB", or R, The LED chips of G and B may be formed as one cluster to form an LED array.

A light emitting means 145 is provided on one side of the lower cover 100 so that the light provided from the light emitting means 145 is perpendicular to the liquid crystal panel 160 through a stepped light guide pattern (or to the ground). ), And a stepped reflection member 140 is provided to reflect the light toward the front surface of the liquid crystal panel 160. Such a stepped reflective member 140 reflects the light provided from the flat lower surface and the light emitting means 145 on one side through the inclined reflective surface to contact the lower cover 100 and the upper liquid crystal. The upper surface of the stepped light guide pattern is formed to guide the panel 160, the stepped reflective member 140 is gradually increased in thickness as the distance from the light emitting means (145).

In addition, the stepped reflective member 140 is an inclined reflective surface of the stepped light induction pattern on the upper side in order to reflect the light provided from the light emitting means 145 such as an LED and to provide the light uniformly to the liquid crystal panel 160. The areas S1 to Sn are formed different from each other. In other words, the stepped light induction pattern of the inclined reflective surface corresponding to the approximately center region provided with the light concentrated by the light emitting means 145 has a small area S1 of the inclined reflective surface, Based on the stepped light induction pattern in the middle area, the area (S2 to Sn) increases in size toward both edges. In this case, for example, the areas S2 to Sn of the inclined reflective surfaces of the stepped light guide patterns corresponding to each other may be the same as going to both sides based on the stepped light guide patterns of the center region. That is, the area Sn of the inclined reflective surface of one edge region and the area Sn of the inclined reflective surface of the other edge region may be the same.

Therefore, in order to form different areas S1 to Sn of the inclined reflecting surface which reflects and induces light from the light emitting means 145 among the stepped light induction patterns formed on the upper surface of the stepping reflecting member 140. By adjusting the length (L1 ~ Ln) (or height) of the inclined reflecting surface will be able to adjust the uniformity of light.

In addition, the angle θ of the inclined reflective surface formed on the upper surface of the stepped reflective member 140 is preferably about 45 degrees. However, this may vary slightly depending on the emission characteristics of the light emitting means 145 and the model size of the liquid crystal display when the stepped reflective member 140 is initially manufactured. For example, this may be parallel to the bottom surface of the lower cover 100. Assuming that the liquid crystal panel 160 is placed, it is more preferable to adjust the angle θ of the inclined reflective surface so that light is vertically provided to the liquid crystal panel 160. Therefore, the inclined reflection surface of the stepped reflection member 140 according to the present invention has an angle θ of the inclined reflection surface from 0 ° <from the opposite direction of the light emitting means with respect to the bottom surface of the lower cover 100. It may be formed in the range of θ <90 °, or in the range of 90 ° <θ <180 ° based on the direction of the light emitting means.

The stepped reflective member 140 is composed of, for example, a poly frame forming a main body, and a reflective layer formed on an inclined reflective surface on which the entire upper side of the frame or the stepped light guide pattern is formed. In this case, the reflective layer may be made of a white polyester film separately attached to the frame, or metal (Ag, Al) formed through a separate coating process on the frame may be formed in the form of a film. The mold reflecting member 140 may be formed in the form of a film by first forming a frame through injection molding, and then introducing the frame into a process chamber to coat metal (Ag, Al) on the upper side of the frame. Through this, the stepped reflective member 140 may have a light reflectance of about 90% to 97% of visible light in the reflective layer, and the thicker the coated film, the higher the reflectance.

In addition, the upper side of the step-shaped reflective member 140 is fastened to the main support 150 of the rectangular frame (or frame of the frame) shape made of a synthetic resin or susu steel molding.

In addition, an optical member 149 may be additionally loaded on the main support 150 to compensate for optical characteristics of light provided through the inclined reflective surface of the stepped reflective member 140. In this case, the optical member 149 may be formed of any one of a diffusion sheet having a diffusion pattern for alleviating nonuniformity of light, a prism sheet having a condensing pattern for increasing front luminance of light, and a protective sheet for protecting the prism sheet from the outside. Can be.

The liquid crystal panel 160 is mounted on the main support 150. The liquid crystal panel 160 is a thin film transistor array substrate 160a bonded to face each other to maintain a uniform cell-gap, a color filter substrate 160b in which color filters of R, G, and B are formed, and between the two substrates. It consists of the liquid crystal layer formed in the.

In addition, the upper cover 170 is fastened to the upper side of the liquid crystal panel 160, and the upper cover 170 covers the four edge regions of the liquid crystal panel 160, and at the same time, the main support 150 or the lower cover ( 100) is assembled and fastened.

As a result of the above configuration, as shown in FIGS. 4 and 5, the liquid crystal display according to the first exemplary embodiment of the present invention is concentrated and radiated in the center region of the light emitting means 145 to form the stepped reflective member 140. The amount of light reflected through the inclined reflecting surface formed to have a relatively small area (S1) in the center region of the light emitted from the side of the light emitting means 145 and gradually increases from the side of the stepped reflective member 140 Since the amounts of light reflected through the inclined reflecting surface formed to have an area S2 to Sn are equal to each other, the luminance appearing on the liquid crystal panel 160 is uniform.

6 is an exploded perspective view showing a liquid crystal display according to a second embodiment of the present invention.

As shown in FIG. 6, the liquid crystal display according to the second exemplary embodiment of the present invention includes a liquid crystal panel 260 in which an image is implemented, and light is arranged and arranged at regular intervals under the liquid crystal panel 260. A plurality of light emitting means 243 and the light emitting means 243 provided on each side to be arranged and arranged on the lower portion of the liquid crystal panel 260, and is inclined on one surface corresponding to the liquid crystal panel 260 A stepped light induction pattern having a slope is formed to reflect light provided from the light emitting means 245 through the inclined reflective surface to guide the light perpendicular to the liquid crystal panel 260, and the distance from the light emitting means 245 is increased. It is characterized in that it comprises a plurality of step-shaped reflective member 240 whose thickness gradually increases with distance.

First, lower light emitting devices 243 and 245 which are arranged and fixed at regular intervals are provided under the lower cover 200 made of an electrogalvanized steel sheet (EGI) or aluminum (Al). Here, the light emitting devices 243 and 245 are composed of light emitting means 245 formed by fixing an LED element or LED chip on a PCB, and a housing 243 fixing the light emitting means 245. At this time, the light emitting means 245 may be fixed to the side wall of the lower cover 200 without the housing 243, the above PCB may be replaced by FPCB.

However, when the light emitting means 245 is a fluorescent lamp such as CCFL, EEFL, HCFL and the like, which is not an LED element or an LED chip, the housing 243 as in the present invention is used to protect the fluorescent lamp from external shock. May be required.

In addition, the LED elements or LED chips constituting the light emitting means 245 are arranged and fixed at a predetermined interval on the PCB, such LED elements or LED chips are formed in an array of "RGBRGBRGB" or R, G It can be formed by forming an LED array using the LED chip of B as a cluster.

A light emitting means 245 is provided on one side of the lower cover 200, and the light provided from the light emitting means 245 is perpendicular to the liquid crystal panel 260 through a stepped light guide pattern (or the lower cover 200). A plurality of stepped reflective members 240 are provided to reflect in a direction perpendicular to the bottom surface of the bottom surface) and to provide the front surface of the liquid crystal panel 260. The stepped reflective member 240 reflects the light provided from the light emitting means 245 on one side and the flat lower side contacting the lower cover 200 through the inclined reflective surface to the upper liquid crystal panel 260. The upper surface of the stepped light guide pattern is formed, the stepped reflecting member 240 is gradually increased in thickness as the distance from the light emitting means 245.

Each stepped reflection member 240 formed as described above has a thick portion in one stepped reflection member 240 disposed adjacent to each other, and a thin portion in the other stepped reflection member 240. Are disposed on the lower cover 200 so as to face each other, wherein the light emitting devices 243 and 245 (or the light emitting means 245) provided in the thin portion are formed in the adjacent stepped reflection member 240. Light emission which is disposed on the inclined side wall portion of the thick portion and fastened or fastened to an accommodating groove formed separately in the side wall portion thereof, thereby providing light at the lower side of the liquid crystal panel 260 when viewed from the outside. The phenomenon that the means 245 (or the light emitting devices 243 and 245) are not visible does not occur.

In addition, each of the stepped reflecting members 240 provided on the lower cover 200 has sidewall members respectively formed on both sides of the stepped reflecting member 240 in a direction perpendicular to the long axis direction of the inclined reflecting surface. 241 may be further provided. The side wall member 241 may be formed by attaching a separately produced reflective sheet or the like, or may be simultaneously formed of the same material when the stepped reflective member 240 is formed.

In addition, the stepped reflecting member 240 is an inclined reflecting surface of the stepped light induction pattern on the upper side in order to reflect the light provided from the light emitting means 245 such as an LED to be uniformly provided to the liquid crystal panel 260. The area (not shown) of is formed differently. In other words, the stepped light induction pattern of the inclined reflective surface corresponding to the substantially center region provided by the light concentrating light from the light emitting means 245 has a small area (not represented) in size of the inclined reflective surface. Based on the stepped light induction pattern in the middle area, the area (not shown) is gradually increasing toward both edges. In this case, for example, the areas (not shown) of the inclined reflective surfaces of the stepped light guide patterns corresponding to each other while going to both sides based on the stepped light guide patterns of the center region may be the same.

Therefore, in order to form different areas of the inclined reflection surface of the stepped light induction pattern formed on the upper surface of the stepped reflection member 240 by reflecting light from the light emitting means 245, the inclined surface is inclined. By adjusting the length (or height) in the minor axis direction of the reflecting surface, the uniformity of the light can be adjusted as much as possible.

In addition, the angle (not shown) of the inclined reflection surface formed on the upper surface of the stepped reflection member 240 is preferably about 45 degrees. This may vary slightly depending on the emission characteristics of the light emitting means 245 and the model scale of the liquid crystal display when the initial stepped reflective member 240 is manufactured. For example, the liquid crystal panel is placed horizontally with the bottom surface of the lower cover 200. Assuming 260, it is more preferable to adjust the angle of the inclined reflective surface so that light is vertically provided to the liquid crystal panel 260. Therefore, the inclined reflective surface of the stepped reflective member 240 according to the present invention is based on the bottom surface (or ground) of the lower cover 200 when the angle of the inclined reflective surface is θ. It may be formed in the range of 0 ° <θ <90 ° from the opposite direction, or in the range of 90 ° <θ <180 ° based on the direction of the light emitting means.

The stepped reflective member 240 is composed of, for example, a poly frame forming a main body, and a reflective layer formed on an inclined reflective surface on which the entire upper side of the frame or a stepped light guide pattern is formed. In this case, the reflective layer may be made of a white polyester film separately attached to the frame, or a metal (Ag, Al), etc. formed through a separate coating process on the frame may be formed in the form of a film. 240 may be formed in the form of a film by first forming a frame through injection molding, and then introducing the frame into the process chamber to coat metal (Ag, Al) on the upper side of the frame. Through this, the stepped reflective member 240 may have a light reflectance of about 90% to 97% of the visible light in the reflective layer. In this case, the thicker the coated film, the higher the reflectance.

In addition, the upper side of the staircase reflective member 240 is fastened to the main support 250 of the rectangular frame (or frame of frame) shape made of a synthetic resin or sus steel mold.

In addition, an optical member 249 may be additionally loaded on the main support 250 to compensate for the optical characteristics of the light provided through the inclined reflective surface of the stepped reflective member 240. At this time, the optical member 249 may be formed of any one of a diffusion sheet having a diffusion pattern for alleviating nonuniformity of light, a prism sheet having a condensing pattern for increasing front luminance of light, and a protective sheet for protecting the prism sheet from the outside. Can be.

The liquid crystal panel 260 is mounted on the main support 250. The liquid crystal panel 260 is a thin film transistor array substrate 260a bonded to face each other to maintain a uniform cell gap, a color filter substrate 260b having color filters R, G, and B formed therebetween, and the two substrates. It consists of the liquid crystal layer formed in the.

In addition, an upper cover 270 is fastened to an upper side of the liquid crystal panel 260, and the upper cover 270 covers four edge regions of the liquid crystal panel 260 and at the same time the main support 250 or the lower cover ( 200) is assembled and fastened.

As a result of the above configuration, the liquid crystal display according to the second embodiment of the present invention is concentrated and radiated in the center region of the light emitting means 245 so as to have a relatively small area in the center region of the stepped reflective member 240. Light reflected through the inclined reflecting surface formed to have an amount of light reflected through the photographic reflecting surface and an area that is radiated to the side of the light emitting means 245 and gradually increased on the side of the stepped reflecting member 240. By maintaining the same amounts of light, the luminance appearing on the liquid crystal panel 260 becomes uniform.

7 is a cross-sectional view of a double-sided liquid crystal display according to a third embodiment of the present invention.

As shown in FIG. 7, the liquid crystal display according to the third exemplary embodiment of the present invention is provided with a pair of liquid crystal panels 360a and 360b arranged at regular intervals to realize an image, and the two liquid crystal panels 360a and The light emitting means 345 provided on one side between the 360b and providing light by forming a plurality of rows (or a plurality of layers), and the light emitting means 345 on one side between the two liquid crystal panels 360a and 360b. Stepped light induction pattern is provided on the both sides and each having a reflective surface inclined to reflect the light provided from the light emitting means 345 through the inclined reflective surface to be perpendicular to the liquid crystal panel (360a, 360b) respectively It is characterized in that it comprises a step-shaped reflective member 340 is guided and the thickness gradually increases as the distance from the light emitting means 345.

First, light emitting devices 343 and 345 which are fastened in a sliding manner from side surfaces thereof are provided on one side wall of the main support 350 having a rectangular frame shape made of a synthetic resin or sus steel mold. Here, the light emitting devices 343 and 345 are composed of a light emitting means 345 formed by fixing two rows of LED elements or LED chips on a PCB, and a housing 343 fixing the light emitting means 345. have. At this time, the light emitting means 345 may be fixed to the side wall of the main support 350 without the housing 343, the PCB above may be replaced with FPCB.

However, when the light emitting means 345 is a fluorescent lamp such as CCFL, EEFL, HCFL and the like, which is not an LED device or an LED chip, a separate housing 343 may be required to protect the fluorescent lamp from an external impact. In this case, the fluorescent lamp will be provided in a double layer in the housing 343.

In addition, the LED elements or LED chips constituting the two-row light emitting means 345 are arranged and fixed at regular intervals in each column on the PCB. Such LED elements or LED chips are arranged in an array of " RGBRGBRGB. &Quot; It can be formed by forming an LED array or a LED chip of R, G, B as a cluster.

In addition, the central area of the main support 350 forming a rectangular frame (or frame) is slidably fastened from the side to include a light emitting means 345 on one side, and provides light provided from the light emitting means 345. Stepped reflective members 340 are provided on the front surfaces of the liquid crystal panels 360a and 360b by reflecting in a direction perpendicular to the liquid crystal panels 360a and 360b through the stepped light guide patterns formed on both sides. It is.

The stepped reflecting member 340 corresponds to (or faces) the rear surfaces of the liquid crystal panels 360a and 360b, respectively, through the inclined reflecting surfaces to reflect the light provided from the light emitting means 343 on one side. Consists of the upper and lower sides of the stepped light induction pattern is formed by reflecting the reflection to the liquid crystal panel (360a, 360b), wherein the stepped reflecting member 340 has a thickness as the distance from the light emitting means 345 Is gradually increasing.

In addition, the stepped reflecting member 340 is an inclined reflecting surface of the stepped light induction pattern on the upper side in order to reflect the light provided from the light emitting means 345 such as an LED and to provide the light uniformly to the liquid crystal panel 160. The areas S1 to Sn are formed different from each other. In other words, the stepped light induction pattern of the inclined reflecting surface corresponding to the approximately center region provided with light concentrated from the light emitting means 345 has a small area S1 of the inclined reflecting surface. Based on the stepped light induction pattern in the middle area, the area (S2 to Sn) increases in size toward both edges. In this case, for example, the area S2 to Sn of the inclined reflective surfaces of the stepped light guide patterns corresponding to each other may be the same as going to both sides based on the stepped light guide patterns of the center region. That is, the area Sn of the inclined reflective surface of one edge region and the area Sn of the inclined reflective surface of the other edge region may be the same.

Accordingly, in order to form different areas S1 to Sn of the inclined reflection surface of the stepped light induction pattern formed on the upper surface of the stepped reflection member 340 by reflecting light from the light emitting means 345. By adjusting the length (or height) of the inclined reflecting surface, the uniformity of light can be adjusted to any extent.

In addition, when the angle of the inclined reflection surface formed on the upper surface of the stepped reflection member 340 is θ, it is preferable that the angle θ is formed to be about 45 degrees. Accordingly, the inclined reflection surface of the stepped reflection member 340 according to the present invention is opposite to the light emitting means based on the liquid crystal panels 360a and 360b having angles θ of the inclined reflection surfaces opposite to each other. It may be formed in the range of 0 ° <θ <90 ° from the direction, or in the range of 90 ° <θ <180 ° from the direction of the light emitting means.

The stepped reflection member 340 is composed of a poly frame forming a main body, for example, and a reflective layer formed on an inclined reflective surface on which the entire upper side of the frame or the stepped light guide pattern is formed. In this case, the reflective layer may be made of a white polyester film separately attached to the frame, or a metal (Ag, Al), etc. formed through a separate coating process on the frame may be formed in the form of a film. The frame 340 may be formed in the form of a film by first forming a frame through injection molding, and then introducing the frame into a process chamber to coat metal (Ag, Al) on the upper side of the frame. Through this, the step-shaped reflective member 340 may have a light reflectance of about 90 to 97% of the visible light in the reflective layer. In this case, the thicker the coated film, the higher the reflectance.

In addition, an optical member 349 may be additionally mounted on the main support 350 to compensate for optical characteristics of light provided through the inclined reflective surfaces of the stepped reflective members 340, respectively. At this time, the optical member 349 may be formed of any one of a diffusion sheet having a diffusion pattern for alleviating nonuniformity of light, a prism sheet having a condensing pattern for increasing front luminance of light, and a protective sheet for protecting the prism sheet from the outside. Can be.

The liquid crystal panels 360a and 360b are mounted on the main support 350, respectively. The liquid crystal panels 360a and 360b are formed of a thin film transistor array substrate bonded to face each other to maintain a uniform cell gap, a color filter substrate on which color filters of R, G, and B are formed, and a liquid crystal layer formed between the two substrates. It consists of.

In addition, the upper cover 370 is fastened to the upper side of the liquid crystal panels 360a and 360b, and the upper cover 370 covers the four side edge regions of the liquid crystal panels 360a and 360b and at the same time the main support 350. To the upper cover 370a or 370b.

As a result of the above configuration, the liquid crystal display according to the third embodiment of the present invention is inclined and radiated in the center region of the light emitting means 345 so as to have a relatively small area in the center region of the stepped reflection member 340. The amount of light reflected through the reflecting surface and the light reflected through the inclined reflecting surface formed to have an area which is radiated to the side of the light emitting means 345 and gradually increased from the side of the stepped reflecting member 340 Since the amounts of light remain the same, the luminance appearing in each of the liquid crystal panels 360a and 360b becomes uniform.

8 is an exploded perspective view of a liquid crystal display according to a fourth exemplary embodiment of the present invention.

As shown in FIG. 8, the liquid crystal display according to the fourth exemplary embodiment of the present invention includes a pair of liquid crystal panels 460a and 460b arranged at regular intervals to implement an image; A support plate 400 provided between the two liquid crystal panels 460a and 460b; One side of the plurality of light emitting means 445a and 445b which are arranged and arranged at regular intervals between the support plate 400 and the liquid crystal panels 460a and 460b to provide light, and the light emitting means 445a and 445b. Stepped light induction pattern is provided between the support plate 400 and each of the liquid crystal panel (460a, 460b) and has a reflective surface inclined on one surface corresponding to the liquid crystal panel (460a, 460b) is formed And reflect the light provided from the light emitting means 445a and 445b through the inclined reflecting surface to guide the light perpendicular to the liquid crystal panels 460a and 460b, respectively, and as the distance from the light emitting means 445a and 445b increases. It characterized in that it comprises a stepped reflecting member (440a, 440b) increases.

First, the support plate 400 positioned in the center of the double-sided liquid crystal display device is provided. The support plate 400 may be formed of an electrogalvanized steel sheet (EGI) or aluminum (Al), or the like, or may be formed of stainless steel or synthetic resin.

Based on the support plate 400, the light emitting devices 443a, 445a, 443b, and 445b are divided into a plurality of regions on the upper side and the lower side, respectively, on one side of the divided region.

Here, the light emitting devices 443a and 445a and 443b and 445b are configured to fix the light emitting means 445a and 445b formed by fixing an LED element or an LED chip in two rows on a PCB and the light emitting means 445a and 445b. And housings 443a and 443b. In this case, the light emitting means 445a and 445b may be fixed to the sidewall of the support plate 400 (or the main support 350a and 350b) without the housings 443a and 443b, and the PCB may be replaced with an FPCB.

However, when the light emitting means 445a, 445b is a fluorescent lamp such as CCFL, EEFL, HCFL and the like, which is not an LED device or an LED chip, separate housings 443a and 443b are used to protect the fluorescent lamp from external shock. This may be required.

In addition, the LED elements or LED chips constituting the light emitting means 445a and 445b are arranged and fixed at regular intervals on the PCB. Such LED elements or LED chips are arranged in an array of " RGBRGBRGB " It may be formed or formed by forming an LED array using the LED chips of R, G, B as a cluster.

Light emitting means 445a and 445b are provided on one side of upper and lower sides of the support plate 400 so that the light provided from the light emitting means 445a and 445b is transferred to the liquid crystal panels 460a and 460b through a stepped light guide pattern. A plurality of stepped reflective members 440a and 440b are provided, respectively, which are reflected in the vertical direction and provided on the front surfaces of the liquid crystal panels 460a and 460b. The stepped reflective members 440a and 440b reflect the light provided from one side of the flat surface and the light emitting means 445a and 445b on the support plate 400 through the inclined reflective surface to form the liquid crystal panel 460a, 460b), each of which has a stepped light guide pattern formed thereon, wherein the stepped reflection members 440a and 440b gradually increase in thickness as the distance from the light emitting means 445a and 445b increases. It is.

Each of the stepped reflecting members 440a and 440b formed as described above has a thick portion of the stepped reflecting members 440a and 440b and the other stepped reflecting members 440a and 440b. 440b is disposed on the support plate 400 so that the thin portions face each other, wherein the light emitting devices 443a, 445a; 443b, 445b (or light emitting means 445a, 445b) are provided at the thin portions. ) Is disposed and fastened to an inclined sidewall portion of a thick portion of the adjacent stepped reflective members 440a and 440b, or is fastened to an accommodating groove formed separately on the sidewall portion thereof, whereby the liquid crystal panel is viewed from the outside. The phenomenon in which the light emitting devices 443a and 445a and 443b and 445b (or light emitting means 445a and 445b) provided below the light emitting units 460a and 460b to provide light is prevented.

In addition, each of the stepped reflecting members 440a and 440b provided on the support plate 400 is formed on both sides of the step reflecting members 440a and 440b, which are perpendicular to each other in a direction perpendicular to the long axis direction of the inclined reflecting surface. Each of the side wall members 441a and 441b may be additionally provided. Such sidewall members 441a and 441b may be formed by attaching separately manufactured reflective sheets or the like, or may be simultaneously formed using the same material when the stepped reflective members 440a and 440b are formed. The side wall members 441a and 441b are provided to exclude the influence of the light provided from the light emitting means in any one region on the adjacent region during the divided driving of the liquid crystal display device. Therefore, the sidewall members 441a and 441b of the present invention may be formed slightly higher than the height of the thick portion of the stepped reflective members 440a and 440b based on the bottom surface of the support plate 400.

In addition, the stepped reflection members 440a and 440b induce the stepped light induction on the upper side thereof so as to reflect the light provided from the light emitting means 445a and 445b such as an LED to be uniformly provided to the liquid crystal panels 460a and 460b. The area (not shown) of the inclined reflecting surface of the pattern is formed differently. In other words, the stepped light induction pattern of the inclined reflective surface corresponding to the substantially center region provided by the light concentrating light from the light emitting means 445a and 445b has a small area (not represented) of the inclined reflective surface, The area (not shown) increases gradually toward both edges based on the stepped light induction pattern of the region. In this case, for example, the areas (not shown) of the inclined reflective surfaces of the stepped light guide patterns corresponding to each other while going to both sides based on the stepped light guide patterns of the center region may be the same.

Accordingly, in order to form different areas of the inclined reflecting surfaces of the stepped light induction patterns formed on one surface of the stepped reflection members 440a and 440b to reflect light from the light emitting means 445a and 445b. Uniformity of light can be adjusted by adjusting the length (not shown) (or height) of the inclined reflective surface.

In addition, when the angle of the inclined reflecting surface formed on one side surface of the stepped reflecting members 440a and 440b is θ, the angle θ is preferably about 45 degrees. This may vary slightly depending on the emission characteristics of the light emitting means 445a and 445b and the model size of the liquid crystal display device in the initial design of the stepped reflective members 440a and 440b. Considering the liquid crystal panels 460a and 460b, it is more preferable to adjust the angle of the inclined reflection surface so that light is vertically provided to the liquid crystal panels 460a and 460b. Therefore, the inclined reflection surfaces of the stepped reflection members 440a and 440b according to the present invention have an angle θ of the inclined reflection surface 0 ° from the opposite direction of the light emitting means with respect to the bottom surface of the support plate 400. It may be formed in the range of <θ <90 °, or in the range of 90 ° <θ <180 ° based on the direction of the light emitting means.

The stepped reflection members 440a and 440b are formed of, for example, a poly frame forming a main body, and a reflective layer formed on the entire upper side of the frame or an inclined reflective surface on which a stepped light guide pattern is formed. In this case, the reflective layer may be made of a white polyester film separately attached to the frame, or a metal (Ag, Al), etc. formed through a separate coating process on the frame may be formed in the form of a film. (440a and 440b) may be formed in the form of a film by first forming a frame through injection molding, and then introducing the frame into a process chamber to coat metal (Ag, Al) on the upper side of the frame. As a result, the light reflectance of visible light in the reflective layer may reach about 90 to 97% of the stepped reflective members 440a and 440b. In this case, the thicker the coated film, the higher the reflectance.

And, on the upper side of the stepped reflective members 440a and 440b, the main supports 450a and 450b having a rectangular frame (or frame of frame) formed of a synthetic resin or sus steel mold are fastened.

In addition, optical members 449a and 449b may be additionally loaded on the main supports 450a and 450b to complement optical characteristics of light provided through the inclined reflective surfaces of the stepped reflective members 440a and 440b. At this time, the optical members 449a and 449b may include any one of a diffusion sheet having a diffusion pattern for alleviating nonuniformity of light, a prism sheet having a condensing pattern for increasing front luminance of the light, and a protective sheet for protecting the prism sheet from the outside. It can be done as one.

The liquid crystal panels 460a and 460b are mounted on the main supports 450a and 450b. The liquid crystal panels 460a and 460b include a thin film transistor array substrate bonded to face each other to maintain a uniform cell gap, a color filter substrate on which color filters of R, G, and B are formed, and a liquid crystal layer formed between the two substrates. It consists of.

In addition, the upper covers 470a and 470b are fastened on the upper sides of the liquid crystal panels 460a and 460b, and the upper covers 470a and 470b cover the four side edge regions of the liquid crystal panels 460a and 460b. It is assembled and fastened to the main support 450a, 450b or the support plate 400. As shown in FIG.

As a result of the above arrangement, the liquid crystal display according to the fourth embodiment of the present invention is concentrated and radiated in the center region of the light emitting means 445a and 445b so that a relatively small area is formed in the center region of the stepped reflection members 440a and 440b. Inclined light formed to have an amount of light reflected through the inclined reflective surface formed to have, and the area radiated to the side of the light emitting means (445a, 445b) and gradually increased from the side of the stepped reflective members (440a, 440b) Since the amounts of light reflected through the reflecting surface remain the same, as a result, the luminance appearing in each of the liquid crystal panels 460a and 460b is uniform.

As described above, the liquid crystal display device according to the first to fourth embodiments of the present invention is a double-sided liquid crystal display capable of realizing images in both directions as well as a single-sided liquid crystal display device capable of realizing images in a single direction in which the viewer is present. Various examples of the apparatus and its single-sided and double-sided liquid crystal display devices ranging from the liquid crystal display device capable of dividing driving to increase the contrast ratio of the image have been described.

Furthermore, in the case of the double-sided liquid crystal display device having the stepped reflective member, the frame shape of the main support may be changed to be configured in a sliding manner, or may be provided with a separate support plate. In this regard, various modifications are possible.

And, with respect to the scope of the present invention will be revealed in the claims described below.

1 is a cross-sectional view of a liquid crystal display device having a direct type LED backlight device;

FIG. 2 is a plan view showing a plurality of PCBs arranged and fixed on the lower cover of FIG.

3 is an exploded perspective view of a liquid crystal display according to a first embodiment of the present invention.

4 is a cross-sectional view of the fastening of FIG.

5 is a perspective view illustrating the stepped reflective member of FIGS. 3 and 4.

6 is an exploded perspective view showing a liquid crystal display according to a second embodiment of the present invention.

7 is a cross-sectional view of a double-sided liquid crystal display device according to a third embodiment of the present invention.

8 is an exploded perspective view of a liquid crystal display according to a fourth embodiment of the present invention.

Claims (27)

A liquid crystal panel in which an image is implemented; Light emitting means provided on one side of the lower portion of the liquid crystal panel to provide light; And The light emitting means is provided on one side of the lower portion of the liquid crystal panel, and a stepped light induction pattern having a reflective surface inclined on one surface corresponding to the liquid crystal panel is formed to provide light provided from the light emitting means through the inclined reflective surface. And a stepped reflecting member which reflects the light toward the liquid crystal panel and increases its thickness as the distance from the light emitting means increases. The liquid crystal display device according to claim 1, wherein the stepped reflective member comprises a reflective layer formed on the stepped light guide pattern. The liquid crystal display device according to claim 2, wherein the reflective layer of the stepped reflective member is a white polyester film attached on a poly frame. The liquid crystal display device of claim 2, wherein the reflective layer of the stepped reflective member is formed of any one of silver (Ag) and aluminum (Al) coated on a poly frame. The liquid crystal device of claim 1, wherein the light emitting means comprises at least one of a light emitting diode (LED), a cold cathode fluorescent lamp (CCFL), an external electrofluorescent lamp (EEFL), and a hot cathode fluorescent lamp (HCFL). Display. 2. The liquid crystal display device according to claim 1, wherein the formation angle [theta] of the inclined reflection surface of the stepped reflection member is 90 [deg.] <[180] from the direction of the light emitting means. A liquid crystal panel in which an image is implemented; A plurality of light emitting means arranged and arranged at regular intervals under the liquid crystal panel to provide light; And The light emitting means is provided on one side and arranged and provided under the liquid crystal panel, and a stepped light induction pattern having an inclined reflective surface is formed on one surface facing the liquid crystal panel, and the light emitting means is provided through the inclined reflective surface. And a plurality of stepped reflection members reflecting the light provided from the light guide device to be perpendicular to the liquid crystal panel and increasing in thickness as the distance from the light emitting means increases. The liquid crystal display device according to claim 7, wherein the stepped reflection member comprises a reflective layer formed on the stepped light guide pattern. The liquid crystal display device according to claim 8, wherein the reflective layer of the stepped reflective member is a white polyester film attached on a poly frame. The liquid crystal display device of claim 8, wherein the reflective layer of the stepped reflective member is formed of any one of silver (Ag) and aluminum (Al) coated on a poly frame. 8. The liquid crystal display device according to claim 7, wherein the formation angle [theta] of the inclined reflection surface of the stepped reflection member is 90 [deg.] <[180] from the direction of the light emitting means. 8. The liquid crystal display device according to claim 7, wherein the stepped reflection member is further provided with sidewall members on both sides to block light provided from adjacent stepped reflection members. 13. The liquid crystal display device according to claim 12, wherein the sidewall member of the staircase reflective member is a reflective sheet. The liquid crystal device of claim 7, wherein the light emitting means comprises any one of a light emitting diode (LED), a cold cathode fluorescent lamp (CCFL), an external electrode fluorescent lamp (EEFL), and a hot cathode fluorescent lamp (HCFL). Display. A pair of liquid crystal panels arranged at regular intervals to implement an image; Light emitting means provided on one side between the two liquid crystal panels and disposed up and down to provide light; And The light emitting means is provided on one side, and is provided between two liquid crystal panels, and a stepped light induction pattern having inclined reflection surfaces on both sides is formed to reflect light provided from the light emitting means through the inclined reflection surface. And a stepped reflective member which is guided perpendicularly to the liquid crystal panel, and whose thickness increases as the distance from the light emitting means increases. 16. The liquid crystal display device according to claim 15, wherein the stepped reflection member comprises a reflective layer formed on the stepped light guide pattern. 17. The liquid crystal display device according to claim 16, wherein the reflective layer of the stepped reflective member is a white polyester film attached on a poly frame. The liquid crystal display of claim 16, wherein the reflective layer of the stepped reflective member is formed of any one of silver (Ag) and aluminum (Al) coated on a poly frame. 16. The liquid crystal display device according to claim 15, wherein the formation angle [theta] of the inclined reflection surface of said stepped reflection member is 90 degrees &lt; A pair of liquid crystal panels arranged at regular intervals to implement an image; A support plate provided between the two liquid crystal panels; A plurality of light emitting means arranged and provided at regular intervals between the support plate and each liquid crystal panel to provide light; And The light emitting means is provided on one side, and is provided between the support plate and each liquid crystal panel, and a stepped light induction pattern having an inclined reflection surface is formed on one surface corresponding to the liquid crystal panel, and is formed through the inclined reflection surface. And a stepped reflective member which reflects light provided from the light emitting means and guides the light vertically to the liquid crystal panel and increases in thickness as the distance from the light emitting means increases. 21. The liquid crystal display device according to claim 20, wherein the stepped reflection member comprises a reflective layer formed on the stepped light guide pattern. 22. The liquid crystal display device according to claim 21, wherein the reflective layer of the stepped reflective member is a white polyester film attached on a poly frame. 22. The liquid crystal display device according to claim 21, wherein the reflective layer of the stepped reflective member is made of one of silver (Ag) and aluminum (Al) coated on a poly frame. 21. The liquid crystal display device according to claim 20, wherein the stepped reflection member further includes sidewall members on both sides that block light provided from adjacent stepped reflection members. 25. The liquid crystal display device according to claim 24, wherein the sidewall member of the staircase reflective member is a reflective sheet. 21. The liquid crystal display device according to claim 20, wherein the formation angle [theta] of the inclined reflective surface of the stepped reflection member is 90 [deg.] <[180] from the direction of the light emitting means. The liquid crystal device of claim 20, wherein the light emitting means comprises one of a light emitting diode (LED), a cold cathode fluorescent lamp (CCFL), an external electrode fluorescent lamp (EEFL), and a hot cathode fluorescent lamp (HCFL). Display.

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