According to various embodiments of the disclosure, an electronic device may include: a housing, a display accommodated inside the housing, a support supporting the display and including a opening and a side wall surrounding the opening, and a heat dissipation structure at least a portion of which is positioned in the opening and bonded to the side wall, wherein the heat dissipation structure may include a heat dissipation layer having a first thermal conductivity and a protective layer having a second thermal conductivity, is the second thermal conductivity being lower than the first thermal conductivity, the protective layer covering at least a portion of the heat dissipation layer.

An electronic device allows the user to notice that no image capturing is being performed and increases the user comfort as well as includes a small open-close device incorporated in a limited space. A camera module is covered by a blade. This allows the user to notice that no image capturing is being performed and increases the user comfort. A base is attached to a first surface of a module board, and a cover has a first end in the longitudinal direction attached to the base and a second end in the longitudinal direction supported by the first surface of the module board. The base may not extend to the second end of the cover in the longitudinal direction and can have a shorter length (miniaturized), further miniaturizing a blade open-close device.

A dynamic texture device coupled to an information handling system input/output device adjusts texture at the input/output device surface based upon texture information generated at the information handling system, such as a walking surface in a virtual world defined by a gaming application. Texture at an elastic cover is adjusted by applying variable magnetic fields to a magnetorheological fluid (MRF) disposed under the elastic cover in a reservoir. For example, an electromagnet changes pole orientation and magnetic strength at MRF contained in a reservoir under a keyboard palm rest to simulate walking in a virtual world on different types of surfaces.

A small blade driving device is incorporated in a limited space. A cover includes a first cover fixed to a base and a second cover protruding from the first cover in a movement direction of a blade. A support leg protrudes from the second cover toward a first surface of a module substrate and is supported by the first surface. The base may not have the same length as the cover and have a shorter

An electronic device is provided. The electronic device includes a housing including first and second housings, a display including a first display region connected to the first housing and a second display region connected to the second housing, and a hinge module connected to the first housing and the second housing. The hinge module may include a rotation bracket including a first accommodation space providing a first rotation axis and a second accommodation space providing a second rotation axis, a rotation member including a first rotation member connected to the first display region and a second rotation member connected to the second display region, and a rail member including a first rail member connected to the first rotation member and configured to rotate in the first accommodation space, and a second rail member connected to the second rotation member and configured to rotate in the second accommodation space.

The display module (100) includes: a supporting member (2) and a display panel (2), supporting member (1) includes an interlayer part (11) and a supporting part (12), the surface of the side of the supporting part (12) that is away from the interlayer part (11) is a supporting curved face (121), the supporting curved face (121) protrudes in the direction away from the interlayer part (11), the display panel (2) includes a non-bending part (21), a bending part (22) and a connecting part (23), the non-bending part (21) and the connecting part (23) are located on the two sides of the interlayer part (11) in the thickness direction of the interlayer part (11), the bending part (22) supports the side of the supporting part (12) that is away from the interlayer part (11), and the inner surface of the bending part (22) adheres to the supporting curved face (121).

Techniques for overlay components for compute devices are disclosed. In one embodiment, an overlay component on a base portion of a compute device can be moved from a folded or closed position (in which it does not cover the keyboard) to an unfolded or open position (in which it covers part of the keyboard). The base portion includes a touch sensor that allows the overlay component to be used as a touch surface. In another embodiment, an overlay component of a compute device is movable from one position adjacent a display of the compute device to another position adjacent a base of the compute device. The overlay component is electrically switchable from a transparent state to an opaque state, allowing the display to be seen through it in one position and allowing it to be used as an opaque drawing surface in another position.

An example computing device includes a flexible display coupled to a housing that includes a support plate having a first joint coupled to a first end of the support plate and a second joint coupled to a second end of the support plate. A slide module has a slot that guides a linear slide movement of the second joint along a linear path of movement within the slot as the support plate pivots about the first joint, where the support plate moves according to the first joint and the second joint to support at least the portion of the flexible display when the flexible display is unfolded and moves according to the first joint and the second joint to create a gap between at least a portion of the support plate and at least the portion of the flexible display when the flexible display is folded.

A flexible display device and a flexible display apparatus are provided. The flexible display device includes a flexible display module; an attaching frame fixed and connected with the flexible display module; a bending component disposed below the flexible display module, and fixed and connected with the attaching frame; and an elastic layer disposed between the flexible display module and the bending component, and attached on a bottom of the flexible display module. The elastic layer is bendable around a bending axis. Thus, the characteristics of easy assembling and flatness can be improved.

Thermal management systems having pre-stressed biasing elements and related methods are disclosed. An example electronic component includes a circuit board, a processor coupled to the circuit board, and a thermally conductive structure positioned adjacent the processor. The thermally conductive structure is to dissipate heat generated by the processor. The electronic component includes a pre-stressed biasing element coupled to the thermally conductive structure and positioned between the processor and the thermally conductive structure. The pre-stressed biasing element is pre-stressed prior to attachment to the thermally conductive structure and the circuit board.