KR200482438Y1 - Display device with thermal link - Google Patents

Abstract

The display device includes a heat sink and an LCD panel having four peripheral edges. The LCD panel includes an inactive area extending inwardly at a predetermined distance from the periphery of the peripheral edge. An thermal link is provided, made of an anisotropic graphite material, and in thermal contact with the heat sink and at least a portion of the inert region of the LCD panel.

Description

[0001] DISPLAY DEVICE WITH THERMAL LINK [0002]

A liquid crystal display or LCD relates to a display device utilizing an image display panel formed of a pair of transparent sheets separated by a liquid containing rod-like crystals and made of a polarizing material.

The polarization axes of these two transparent sheets are aligned perpendicular to each other. The LCD is configured to display an image by arranging the crystal to pass light through the liquid to block the light. The crystals can each be adjusted separately and essentially act like a shutter. A current is applied to a predetermined pixel-like region, and such crystals are arranged to produce a dark or bright image. Dark areas are combined with bright areas to create text and images on the panel. Since the LCD panel itself does not generate light, a light source is required. Thus, the panel is a back-lit or side-lit that allows increasingly thin manufacturing parameters.

One criterion for television image quality is Mura, which is a word about inhomogeneity or discrepancy derived from Japan. In television and especially in the construction of an LCD television, the dark screen mura is the darkness unevenness of the screen. In other words, when the LCD panel receives an input that prevents any light transmission, the black of the screen actually changes with a relatively lighter or darker area. This variability is undesirable if it appears to be sufficiently perceptible to the human eye.

According to an aspect of an embodiment disclosed herein, a display device includes a heat sink and an LCD panel. The LCD panel includes peripheral edges and an inactive area extending inwardly from each of the peripheral edges at a predetermined distance. The thermal links made from the anisotropic graphite material are in thermal contact with the heat sink and at least a portion of the inactive region of the LCD panel.

According to another aspect of the embodiments disclosed herein, the thermal link is provided for a display device including an LCD panel and a heat sink. The LCD panel has an inactive area extending around the periphery. The thermal link includes a first portion in contact with at least a portion of the inactive region. The first portion includes a first end in contact with the inactive region and a second end extending outwardly from the inactive region. The first portion is generally coplanar with the LCD panel. The second portion extends from the second end of the first portion and terminates in the third portion. The second portion is generally arranged perpendicular to the first portion, and the third portion is generally arranged parallel to the first portion. The third portion is a contiguous anisotropic graphite material contacting the first portion of the heat sink and the second portion and the third portion generally forming a J-shaped cross-section.

According to another aspect of an embodiment disclosed herein, a display includes an LCD panel having a front side and a rear side. The LCD panel includes the inactive area in the peripheral edge of the LCD panel. A thermal solution is applied along one or more peripheral edges to the inactive areas of the front or back surface. The thermal solution has a thermal resistance of less than about 25 [deg.] C / W.

According to another aspect of an embodiment disclosed herein, an LCD display device includes a structural chassis including four corners and a plurality of mounting holes. Each of the mounting holes is positioned proximate to one of the corners and configured to receive a fastener for the wall mounting assembly. The LCD display device further includes an LCD panel fixed to the structural chassis.

Improve the picture quality of the television image.

1 is a front isometric view of a display panel.
2 is a rear isometric view of the display panel.
3 is an exploded front isometric view of the display panel.
4 is a front view of the LCD panel and a plurality of thermal links.
Figure 5 is a side view of an LCD panel and a plurality of thermal links, the remaining display panel elements removed for clarity.
6 is an enlarged cross-sectional view of the thermal link.
7 is a plan view of another chassis.

Referring to Figures 1-3, an LCD device is shown and generally designated 10. The apparatus 10 includes a plurality of components assembled in a stacked configuration. Although not shown, an external casing or housing may accommodate the stacked elements described herein. The chassis 12 is provided at the rear of the laminate and is composed of a generally rectangular sheet. The chassis 12 may include one or more embossments 14 or a raised portion, which may be provided to increase the strength and / or stiffness of the chassis. The chassis 12 is typically made of metal, such as steel, aluminum, or other structural material, to improve the structural integrity of the device 10 and also provides a mounting point for a display stand or wall hanging. The chassis 12 may further provide a heat sink function as will be described in greater detail herein.

The heat dissipation sheet 16 can be positioned in front of the chassis 12 in the stack and is in the form of a graphite sheet. In one embodiment, the heat dissipation sheet 16 extends substantially over the entire area of the chassis 12. In these or other embodiments, the heat dissipation sheet 16 is in thermal contact with substantially the entire chassis 12 plane. In another embodiment, the heat spreader sheet 16 is in thermal contact with at least 75% of the plane of the chassis 12. In this or other embodiments, the heat dissipation sheet 16 is provided to facilitate uniform heat dissipation across the entire area of the heat dissipation sheet 16. The heat source may include one or more circuit boards (not shown) that are supported on the front side of the chassis 12. Other heat sources may include one or more LED modules (not shown). In one embodiment, the heat dissipation sheet 16 is in operative thermal contact with one or more LED modules and allows the heat generated by the LED modules to be transferred to the heat dissipation sheet 16. In one embodiment, the heat spreading sheet 16 comprises at least one edge having a size and configuration in direct contact with one or more LED modules.

The heat dispersion sheet 16 is preferably an anisotropic graphite sheet material. In some embodiments, the graphite material is formed from one or more sheets of exfoliated graphite compressed particles. Compressed peeled graphite materials such as graphite sheets and foils have good handling strength consistency and are suitably compacted, for example, by roll pressing to a thickness of about 0.05 mm to 3.75 mm and a typical density of about 0.4 to 2.0 g / cc or higher. When used in accordance with the present disclosure, the exfoliated graphite compressed particle sheet should have a density of at least about 0.6 g / cc, more preferably at least about 1.1 g / cc, and most preferably at least about 1.6 g / cc. The upper limit of the graphite sheet heat spreader density is about 2.0 g / cc. Graphite sheets suitable for use in the thermal bridges of this disclosure are commercially available as eGRAF materials from Graftec International Holdings, Inc., Parma, Ohio. In another embodiment, the graphite material comprises one or more layers of pyrolytic graphite. "Thermally decomposed graphite" refers to a graphite material produced by the heat treatment of a given polymer, as described, for example, in U.S. Patent No. 5,091,025, which is incorporated herein by reference.

If necessary, the compressed particle sheet of exfoliated graphite can be treated with a resin, and the absorbed resin improves moisture resistance and handling strength, i.e., rigidity and shape "fix" of the product, of the graphite article after curing. A suitable resin content is preferably at least about 5 weight percent, more preferably about 10 to 35 weight percent, and suitably up to about 60 weight percent. Resins found particularly useful in the practice of the present invention include acrylic-, epoxy- and phenol-based resin systems, fluoropolymers, or mixtures thereof. Suitable epoxy resin systems include those based on diglycidyl ether bisphenol A (DGEBA) and other multifunctional resin systems. Phenolic resins that may be used include resole and novolac phenolic. Alternatively, the flexible graphite may be injected in addition to, or instead of, the resin together with the fibers and / or salts. In addition, reactive or non-reactive additives may be used to modify properties (e.g., viscosity, material flow, hydrophobicity, etc.) in the resin system.

In some embodiments, the plurality of graphite sheets may be laminated with an integral product. The compressed particle sheet of peelable graphite may be laminated with a suitable adhesive such as a pressure-sensitive or heat activated adhesive therebetween. Adhesives adopted should balance adhesive strength and minimum thickness and be able to maintain adequate adhesion at the temperature of use with heat transfer. Suitable adhesives are known to the operator and include acrylic and phenolic resins.

The graphite sheet should have an in-plane thermal conductivity of at least about 150 W / m * K. In another embodiment, the graphite sheet exhibits a horizontal thermal conductivity of at least about 300 W / m * K. In another embodiment, the graphite sheet exhibits a horizontal thermal conductivity of at least about 400 W / m * K. In another embodiment, the graphite sheet exhibits a horizontal thermal conductivity of at least about 700 W / m * K. In another embodiment, the graphite sheet exhibits a horizontal thermal conductivity of at least about 1500 W / m * K. In one embodiment, the graphite sheet material may be 10-15 microns thick.

The reflector 20 is interposed in front of the heat dissipating element 16 in the laminate. The front face 22 of the reflector 20 is configured to reflect light generated by the LED module toward the front of the viewer of the device 10. [ The reflector 20 also facilitates a uniform dispersion of light from the LED module. In one embodiment, the heat scattering sheet 16 is adhered to or attached to the reflector 20. [ In these or other embodiments, the heat dispersive material 16 is not in thermal contact with the chassis 12.

Each LED module includes one or more individual LEDs mounted on a printed circuit board. The LED module is mounted along at least the periphery of the device 10. In one embodiment, the LED module is positioned along the four entire peripheral edges of the device 10. In another embodiment, the LED module is positioned along only two peripheral edges of the device 10. In another embodiment, the LED module is positioned along only one edge of the device 10. It can also be seen that a light source other than the LED can be used. For example, the light generating module may instead comprise one or more cold cathode fluorescent lamps.

The light guide plate 24 is positioned in front of the reflector 20 in the laminate. The light guide plate 24 helps guiding light from the main LED module to the LCD panel 26, and the LCD panel 26 is positioned in front of the light guide plate 24 in the laminate. Accordingly, the light guide plate 24 includes an internal optical system, which guides the light from the LED module of the peripheral edge and distributes light substantially uniformly across the entire front surface 28 of the light guide plate 24. It should be understood that other lighting configurations are contemplated. For example, the LCD panel 26 may be a rear lit by one or more LEDs or directly to the CCFL module. In such an embodiment, the light guide plate 24 may be unnecessary.

The brightness enhancement film 30 can be positioned in front of the light guide plate 24 in the laminate. The film 30 improves the quality and uniformity of light entering the LCD panel 26. The film 30 may itself be a multi-layer assembly. For example, the film 30 may include one or more diffusion layers and / or one or more lens layers.

The backlight bezel 31 is positioned in front of the brightness enhancement film 30 in the laminate. The bezel 31 is generally open and rectangular and is provided to secure the backlight optical assembly to the chassis 12 including the brightness enhancement film 30 and the light guide plate 24 and the reflector plate 20. The backlight bezel 31 can be plastic or metal and is mechanically or glued to the chassis 12 and secured. The bezel 31 may include a peripheral step (not shown) or other capturing configuration on the rear surface. Such a step may capture the backlight optical assembly and serve to securely support the bezel 31 and the chassis 12. The bezel 31 may further include a peripheral step or alignment or clip feature on the front surface to align or accommodate the LCD panel 26 therein.

The LCD panel 26 is positioned in front of the brightness enhancement film 30 in the laminate. The LCD panel 26 is itself an assembly. As described above, the panel 26 usually includes a liquid crystal material layer interposed between two transparent electrodes. The opposing polarizing filter is usually located outside each of the electrode layers. The liquid crystal material, the electrode, the polarizing filter, and the optional optical layer are also held between two transparent sheets adhered to each other. Usually, the transparent sheet is glass, but other transparent optically and mechanically suitable materials may be used.

The LCD panel 26 does not cover the active pixels across the entire surface area. The inert portion 32 typically extends inwardly from the peripheral edge of the LCD panel 26. The inert portion 32 may extend from about 2 mm to about 10 mm inwardly from the peripheral edge of the LCD panel 26.

The outer bezel 34 is positioned forward of the LCD panel 26 in the stack. The bezel 34 is generally open and rectangular and is provided to secure the LCD panel 26 to the chassis 12. The outer bezel 34 can be plastic or metal and is bonded to the chassis 12, but is preferably mechanically fixed. In one embodiment, a plurality of mechanical fasteners extend from the bezel 34 through the bezel 31 and the backlight optical assembly, and are secured to the chassis 12. In this way, the LCD panel 26 is firmly fixed to the chassis 12. [ The outer bezel 34 may include a peripheral step (not shown) or other capturing configuration on the rear surface. Such a step may serve to capture and / or align the LCD panel 26 and to securely support it between the bezel 34 and the bezel 31. [

The one or more circuit boards may be located at a plurality of locations throughout the device 10. [ For example, the circuit board (not shown) may be fixed to the front surface of the chassis 12. An electrical connector (not shown) connects the control and power electronics from one or more circuit boards to the LCD panel. It is to be understood that the electrical connector is typically connected to the LCD panel at the lower edge 36 of the LCD panel 26, but the electrical connection can be connected at any one or more of the peripheral edges of the LCD panel 26. The control signal of the LCD panel 26 is transmitted from the circuit board through the electrical connector.

The area of the LCD panel 26 near the junction between the panel 26 and the electrical connector 38 is the area where the temperature is increased compared to the remaining display area of the LCD panel 26. [ This relatively increased temperature can be at least partially caused by the power for the LCD panel 26 and because all signals are sent through this area before being transmitted to the entire area of the LCD panel 26. Another area of increased temperature is near the corner edge of the LCD panel.

The temperature difference at the corner and circuit element intersection edges for the rest of the panel adversely affects the dark screen area. A thermal link may be provided between the heat sink and the area of the LCD panel 26 near the edge to reduce the thermal differential and improve the dark screen uniformity of the LCD panel 26. [ In view of the relatively large mass and metal composition, the heat sink is preferably a chassis 12. The thermal link is preferably anisotropic graphite material as described above. The thermal link can contact the front or rear surface of the LCD panel 26 but does not extend to the viewing area of the LCD panel 26. [ In other words, the thermal link preferably only makes thermal contact with the inactive or non-visible portion 32 of the LCD panel 26 surface.

In one embodiment, the thermal link may be bonded to the LCD panel 26 with a thermally conductive adhesive. In this or other embodiments, the thermal link is supported between the LCD panel 26 and the outer bezel 34 in a press-fit to the LCD panel. In another embodiment, the thermal link is supported between the LCD panel 26 and the backlit bezel 31 for indentation. In one embodiment, the thermal link is in contact with the front or back of the LCD panel 26 along all four edges. In another embodiment, the thermal link contacts the front or back surface of the LCD panel 26 and each of the corners at a predetermined distance. In another embodiment, the thermal link contacts the front or back of the LCD panel 26 and the three edges of the LCD panel 26 at a predetermined distance from the two corners closest to the interface with the electrical connector. In this or other embodiments, the thermal links extend from each of the corners to at least 10% of the total length of the edge. In another embodiment, the thermal link extends at least 20% of the overall length of the edge. In another embodiment, the thermal link extends to at least 30% of the total length of the edge.

According to one embodiment, the thermal link contacts the front or back surface along at least 50% of the edge length of the LCD panel 26 associated with the electrical connector 38. According to another embodiment, the thermal link contacts the front or rear surface along at least 75% of the edge length of the LCD panel 26 associated with the electrical connector 38. According to another embodiment, the thermal link extends along the front or rear along at least 90% of the edge length of the LCD panel associated with the electrical connector 38.

4 and 5, the LCD panel 26 includes an inactive area 32 extending around the entire peripheral edge. In one embodiment, the inactive area extends about 10 mm inward from the peripheral edge. In another embodiment, the inactive region extends about 8 mm inward from the peripheral edge. In another embodiment, the inactive region extends about 5 mm inward from the peripheral edge.

A pair of lower thermal links 42 engage the front surface of the LCD panel 26 along a lower edge 36 to which an electrical connector connects to the LCD panel 26. As can be seen, in the region where the thermal link 42 engages the LCD panel 26, the thermal link is in thermal contact with substantially all of the inactive portion 32. For example, the inactive portion extends 8 mm from the periphery, and the thermal link 42 joins the front of the LCD panel to 8 mm from the peripheral edge. In another embodiment, the thermal links 42 contact at least 50% of the inactive distance from the peripheral edge. In another embodiment, the thermal link contacts at least 75% of the inactive distance from the peripheral edge. In yet another embodiment, the thermal link substantially contacts the entire inertial distance from the peripheral edge.

The additional pairs of thermal links 46 couple to the front of the LCD panel 26 along the respective side surfaces, respectively. As can be seen, the thermal link 46 extends upwardly from each of the lower corners and contacts substantially all of the inactive area 32 over the length of the link 46. The link 46 can extend up to about 15% of the total length of each of the side peripheral edges.

6 showing a cross-section of the thermal link 42, each of the thermal links 42 and 46 may include a generally J-shaped body and a first leg 48 may be mounted on the LCD panel 26, In the inactive region 32 on the front or back side of the substrate 32, and therefore coplanar within it. The second leg 50 extends generally rearwardly from the first leg 48 toward the chassis 12. The third leg 52 then extends back substantially coplanar with the chassis 12, preferably in thermal contact with its rear face. In this way, the thermal energy from the peripheral edge of the LCD panel 26 is transferred to the chassis 12 serving as a heat sink.

It should be understood that, although the disclosed figures illustrate thermal links extending along three edges of an LCD panel, as described above, the thermal links can extend along only one edge or all four edges. It should also be understood that, although the disclosed figures illustrate thermal links extending along the front of an LCD panel, the thermal links may extend along the back or even both sides at the same time.

As disclosed herein above, the removal of heat from the corners and / or edges of the LCD panel has been found to eliminate black light scattering. Thus, in one embodiment, the thermal solution couples to at least a portion of the inactive front or back of the LCD panel 26. In at least one embodiment, the thermal solution is provided in the vicinity of one or more corners. In these or other embodiments, the thermal solution couples with the front or rear surface of the panel 26. In one embodiment, the separate thermal solution couples to the LCD panel in a separate location. In one embodiment, the thermal solution is fixed to the front or back surface of the inactive portion of the LCD panel 26 at a distance that extends from the corner to about a quarter of the total length of each side. In this or other embodiments, the thermal solution is located near the entire four corners of the LCD panel 26. In another embodiment, the thermal solution is located in the vicinity of at least two corners of the LCD panel 26.

Each of the thermal solutions preferably provides a thermal resistance of less than about 25 DEG C / W, more preferably less than about 15 DEG C / W, and more preferably less than about 5 DEG C / W. According to one embodiment, the thermal solution can preferably be implemented with the thermal bridge described above, but other solutions can be used and the thermal resistance performance described above can be obtained. For example, a graphite or metal product may have a different physical configuration than the thermal bridges described above, and a heat sink, thermal pastes, active cooling, or any other method may be used to achieve a thermal resistance value as described herein above Can be used.

It has also been found that not only the above solution but also the flexibility or distortion of the chassis 12 during use can be increased and cause an overall dark screen unevenness. In FIG. 7, the modified chassis 112 is shown including an emboss 114 pattern, which provides additional strength and consequently improves dark screen mura. In one embodiment, the muffler pattern 114 is generally "X" shaped. The chassis 112 also includes mounting holes 114 near the four corners 116 of the chassis 112. These mounting holes 114 are configured to receive fasteners (not shown) from the wall mount or pedestal mount assembly. In one embodiment, the mounting holes 114 are within at least 10 cm from each of the corners 116 of the chassis 112. More preferably, the mounting hole 114 is within about 5 cm from the corner 116 of the chassis 112.

By mounting the chassis 112 at a location near the corner instead of a commonly mounted vicinity of the center of the television, the chassis 112 is effectively strengthened, thus reducing flexibility. This is because of the mounting position, and because the wall-mount assembly is often made of high-strength material and is highly rigid.

All patents and publications cited herein are incorporated by reference. It will be apparent that the invention described may be varied in various ways. Such modifications are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.

(12): Chassis
(14): Emboss
(16): Heat dissipation sheet
(20): reflector
(22): front face of the reflector
(24): Light guide plate
(26): LCD panel
(28): front face of the light guide plate
(30): Brightness improving film
(31): Bezel
(32): inert portion
(34): External bezel
(38): inert portion
(42): Thermal link
(46): Thermal link

Claims (10)

delete delete delete delete delete delete An thermal link for a display device, comprising an LCD panel and a heat sink, wherein the LCD panel includes an inactive area extending around the periphery,
A first portion in contact with at least a portion of the inactive region and having a first end in contact with at least a portion of the inactive region and a second end extending outwardly from the inactive region, ,
A second portion extending from the second end of the first portion and terminating in a third portion arranged generally parallel to the first portion and generally perpendicular to the first portion,
The third portion being in contact with the heat sink,
The first, second and third portions are continuous anisotropic graphite materials which generally form a J-shaped cross-section,
Wherein the heat sink comprises a metal chassis,
Thermal link. 8. The thermal link of claim 7, wherein the anisotropic graphite material comprises a compression-peelable particulate sheet of at least one natural graphite or at least one thermally decomposed graphite layer and exhibits a horizontal thermal conductivity of at least 300 W / mK. delete delete

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