Computers and other electronic equipment utilize electronic displays, such as liquid crystal display (LCD) panels, gas plasma panels, and the like. For example, notebook computers, tablet computers, personal digital assistants (PDAs), and cellular telephones often utilize a LCD panel display apparatus or a gas plasma display apparatus disposed in a display enclosure. Similarly, entertainment systems, such as portable digital versatile disk (DVD) systems and flat panel televisions often use a LCD panel display apparatus or gas plasma display apparatus disposed in a display enclosure.
Typical display apparatus, such as a LCD display apparatus, which may be acquired by an electronic device original equipment manufacturer for integration into an electronic device, such as a notebook computer, comprise a metal frame surrounding the actual display to provide support structure and attachment points. For example, a frame of a typical LCD display apparatus may include integral mounting points, e.g., holes machined therein to accept mounting screws, along sides thereof. Although certain display apparatus, e.g., some 16:9 aspect ratio or “wide screen” displays, provide integral mounting points along 4 sides of a mounting frame, many commercially available display apparatuses provide integral mounting points only along 2 sides of a mounting frame. Accordingly, a display apparatus may be attached to a display enclosure making up a notebook computer display along only 2 sides (e.g., the 2 sides parallel to an X-axis of the display apparatus).
The display apparatus of such displays are often subject to appreciable motion, shock, and deflection pressure. For example, a notebook computer may be subject to substantial g-forces when transported by a user. Additionally, items, such as cell phones, power adaptors, etcetera, may be transported with a notebook computer which, when disposed in juxtaposition with a portion of the panel display, may cause substantial deflection pressure to be applied thereto.
Although the display apparatus of the aforementioned displays may be relatively rigid, such display apparatus is prone to planar deflection (e.g., the display surface bowing along the 2 sides parallel a Y-axis of the display apparatus) when exposed to motion, shock, deflection pressure, etcetera. Planar deflection of a display apparatus may result in the display surface contacting other structure, such as the keycaps, pointing stylus, or wrist rests of a notebook computer when the notebook computer is in a closed clamshell configuration. Such contact may result in marks being left on the display surface from dust, organic oil residues, etcetera. Additionally, such contact may result in the notebook computer being unintentionally awakened from a power conserving sleep due to the display apparatus engaging a pointing stylus or other input mechanism during transport. Even more problematic, such contact may result in the display apparatus being permanently damaged. For example, contact between the display surface and a hard surface, such as keycaps, may result in a hole or surface irregularity being worn into one or more layers of the display mechanism. A LCD display may comprise one or more thin membranes, such as polarizing layers, disposed upon a glass or other substrate which, when repeatedly contacted by a hard surface may develop the aforementioned holes or surface irregularity.
Various techniques have been used in the past to prevent display surfaces of such displays from contacting other structures or to prevent damage resulting therefrom. For example, spacers, such as may be made of rubber or other materials, have been used along the periphery of the display to maintain a spacing between a display surface and other structure sufficient to accommodate planar deflection without contact between the display surface and other structure. As one example, it may be determined that the expected maximum planar deflection associated with a display apparatus of an electronic device will be 2.5 mm. Accordingly, spacers may be implemented, particularly along the sides having no attachment points coupling the display apparatus to a display enclosure, which are sized (e.g., 3 mm) to provide a space accommodating the expected planar deflection without contact between the display surface and other structure. However, size is often an issue with respect to electronic devices, such as notebook computers. For example, the aforementioned spacing may consume 10-15% of the overall size in a corresponding dimension. Therefore, the use of such spacers is not without drawback.
Resilient pads, such as may be made of rubber or other materials, have been used (often in combination with spacers along the periphery of the display) to interface with one or more portions of a display surface and thereby prevent the display surface from contacting other structure, such as keycaps, pointing stylus, or wrist rests of a notebook computer, which presents a hard surface that may damage the display apparatus. For example, rubber pads have been disposed upon notebook computer wrist rest surfaces to interface with portions of a display surface appreciably toward the middle of the display surface and thus provide sufficient support of the display surface to prevent contact with other structure when a smaller gap is used than with the use of spacers along the edge of the display alone. However, such resilient pads have met with disapproval from some users due to their interfacing with the display surface leaving marks from dirt or oils thereon. Moreover, some users have expressed dissatisfaction with the feel of such pads against their hands during use of the notebook computer. Accordingly, the use of such pads is not without drawback.
Another technique used to prevent the display surface from contacting other structure has been through the use of more rigid materials or material configurations in the display enclosure (often in combination with spacers along the periphery of the display). For example, added plastic material, e.g., in the form of thicker surfaces and/or rib structures, may be used to make more rigid a display enclosure comprised of plastic. Alternatively, special materials, such as magnesium or engineered composites, may be used to provide a more rigid enclosure. The use of such more rigid materials or material configurations reduces the amount of planar deflection experienced, thus allowing smaller spacers (or perhaps no spacers) to be used. However, the foregoing typically results in added cost, weight, and/or size. Accordingly, the use of such more rigid materials or material configurations is not without drawback.
Although it is possible to manufacture display apparatus in aspect ratios other than the aforementioned 16:9 aspect ratio having integral mounting points along 4 sides of a mounting frame, such display apparatus configurations have heretofore not been widely available. Electronic equipment manufacturers often prefer to integrate widely available components, such as the aforementioned display apparatus, into their products in order to decrease costs and/or to ensure parts availability. Accordingly, display apparatus having integral mounting points only along 2 sides of a mounting frame continue to be used, despite the above-described planar deflection associated with the display surface bowing along the 2 sides having apparatus) and despite the drawbacks associated with the various techniques used to prevent display surfaces from contacting other structure or to prevent damage resulting therefrom.
Directing attention to
Display 100 of the illustrated embodiment comprises display apparatus 120, such as may comprise a LCD display panel, disposed in display enclosure base 130. Display enclosure base 130 may comprise, for example, a portion of a portable computer clamshell case. Display apparatus 120 comprises frame 121 surrounding the viewing or display surface thereof. Frame 121 has a plurality of integral mounting points along the 2 sides which are parallel to an X-axis of display apparatus 120. Specifically, integral mounting points 122 are disposed along side 123 of frame 121 and corresponding integral mounting points 122 are disposed along opposite side 124 of frame 121.
In a typical display configuration, without any embodiments of the present invention, integral mounting points 122 would provide the only points for fastening display apparatus 120 to display enclosure base 130. In such a configuration, display apparatus 120 may experience an appreciable amount of planar deflection due to a lack of support along the 2 sides which are parallel to a Y-axis of display apparatus 120, shown here as sides 125 and 126 (e.g., the display surface may be deformed in a slight “U” shape). For example, a typical display apparatus providing integral mounting points along only 2 opposite sides may deform or sag on the order of 2 mm, which in a notebook configuration presenting an overall thickness of 25-38 mm may be sufficient for a display surface of display apparatus 120 to contact keycaps of the notebook computer base.
However, the illustrated embodiment of display 100 comprises hold-down bracket assemblies 110, disposed along sides 125 and 126 of display apparatus 120 (e.g., disposed along the edge of frame 121 at sides 125 and 126), of an embodiment of the present invention. Accordingly, display apparatus 120 of the illustrated embodiment is provided hold-down points with respect to display enclosure base 130 in addition to integral mounting points 122.
Although hold-down bracket assemblies 110 of the illustrated embodiment are shown as being disposed equidistantly spaced along 2 sides of display apparatus 120, embodiments of the invention may utilize various hold-down bracket spacing and positions. For example, a single hold-down bracket may be utilized at the center of a side of display apparatus 120, such as where display apparatus 120 is the size of a traditional notebook computer display. Hold-down brackets of embodiments of the present invention may be utilized at any position (e.g., any position not otherwise provided an integral mounting point, at an integral mounting point position, etcetera). However, the presence of other structure, such as latch mechanisms, hinges, signal cables, etcetera, may suggest particular placements and/or prevent particular placements of hold-down brackets of embodiments of the invention. In general, however, the longer the distance between integral mounting points, the larger the number of hold-down points desired.
Hold-down bracket assemblies 110 of the illustrated embodiment are shown in a symmetrical implementation, e.g., hold-down brackets of a first side are disposed in juxtaposition with hold-down brackets of a second side. However, an asymmetrical arrangement may instead be implemented according to some embodiments of the present invention. For example, a single hold-down bracket may be implemented in the center of a first side while 2 equidistantly spaced hold-down brackets are implemented with respect to a second side of the display apparatus.
The use of hold-down points, such as those provided by hold-down bracket assemblies 110, disposed at positions not otherwise corresponding to integral mounting points 122, provides a more rigid display configuration. For example, a degree of freedom of movement or flexibility is eliminated or minimized through the use of hold-down bracket assemblies 110 of the illustrated embodiment to provide hold-down points with respect to display apparatus 120. Through the use of such hold-down points appreciably less planar deflection is experienced with respect to display apparatus 120. Accordingly, smaller spacers, or no spacers, may be utilized in a display configuration implementing hold-down brackets according to embodiments of the invention, thereby facilitating a thinner form factor for electronic devices. Additionally or alternatively, some embodiments use no resilient pads to support a surface of display apparatus 120, thereby avoiding marks left upon display apparatus 120 from interfacing with such pads. Moreover, providing more fastening points (e.g., integral mounting points and/or hold-down points) with respect to display apparatus 120, and frame 121 thereof, results in a display structure which is overall more rigid, enabling the use of less expensive, lighter, and/or thinner materials (e.g., plastic) in the enclosure material. In addition to facilitating embodiments of electronic devices which are thin (compact) without experiencing permanent damage to or undesired marks on the surface of their respective displays, embodiments of the invention provide increased user satisfaction in providing a low weight solution having a rigid display assembly.
Hold-down bracket assembly 110 of
The portion of display enclosure base 130 to which fastener 212 is attached illustrated in
Although various configurations of hold-down bracket 211 may be implemented according to embodiments of the invention, hold-down bracket 211 preferably provides a portion to interface with fastener 212 and a portion to interface with display apparatus 120. For example, hold-down bracket 211 may comprise a first portion to interface with display apparatus 120 sufficiently to resist substantial movement of display apparatus 120 when exposed to expected forces but which does not result in undesired interference with display apparatus 120. For example, the portion of hold-down bracket 211 which interfaces with display apparatus 120 of embodiments does not extend into a viewing area of the display apparatus. Moreover, the portion of hold-down bracket 211 of embodiments is sized not only to avoid obscuring a portion of the viewing area of display apparatus 120, but is further sized and disposed so as to avoid interference phenomena. For example, where display apparatus 120 comprises a LCD display, pressure on or near the viewing surface could cause distortion (referred to as “puddling”). Accordingly, hold-down bracket 211 of embodiments of the invention interfaces with a portion of frame 121 sufficiently removed from the viewing area of display apparatus 120 to avoid image distortion during normal use. Correspondingly, hold-down bracket assembly 110 is configured to provide sufficient pressure with respect to the interface between hold-down bracket 211 and display apparatus 120 to substantially eliminate a degree of freedom of movement without causing image distortion during normal use. Hold-down bracket 211 of embodiments comprises a second portion to interface with fastener 212 which is in the range of 5-6 mm wide in order to accommodate a fastener extended therethrough having a shaft diameter in the range of 2.5-3 mm.
Directing attention to
The embodiment of hold-down bracket 311 illustrated in
Hold-down brackets 211 and 311 may be formed of any material sufficiently strong to interface with display apparatus 120 and resist substantial movement of display apparatus 120 when exposed to expected forces. For example, hold-down brackets 211 and 311 may be comprised of steel, stainless steel, aluminum, composite resins, etcetera.
Hold-down brackets 211 and 311 of the embodiments illustrated in
Irrespective of the particular configuration of hold-down bracket assembly 110 implemented according to embodiments of the invention, hold-down bracket assemblies 110 provide hold-down points at positions other than the integral mounting points otherwise available with display apparatus 120. Accordingly, the use of hold-down bracket assemblies according to embodiments of the present invention avoids damage to a display surface of display apparatus 120 even when utilized in a thin or compact profile electronic device, such as a notebook computer. Moreover, use of hold-down bracket assemblies according to embodiments of the present invention provides a more rigid configuration of display assembly 100.
Directing attention to
Bezel 430 of the illustrated embodiment provides areas corresponding to hold-down bracket assemblies 110 for accepting a cover and/or spacer. Directing attention to
The present application claims benefit of priority to co-pending U.S. Provisional Patent Application No. 60/639,111, entitled “Display Hold-Down Systems and Methods, filed Dec. 23, 2004, the disclosure of which is hereby incorporated herein by reference.
Number | Date | Country | |
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60639111 | Dec 2004 | US |