A display device is disclosed. The display device includes a display panel, a rear case positioned in a rear of the display panel, and of which a back surface is exposed to the outside, a backlight unit positioned between the display panel and the rear case and providing the display panel with light, a plurality of ribs extended from a front surface of the rear case and contacting at least a portion of the backlight unit, a boss forwardly extended from the front surface of the rear case, and a controller positioned between the backlight unit and the rear case and coupled with the boss.

The technology relates to a cage configured to removably receive a module. The cage may include a frame comprising a plurality of panels joined to one another, a lever pivotably coupled to the frame, and a heatsink pivotably coupled to the lever. The panels together may extend around a longitudinal recess configured to receive the module therein. The longitudinal recess may define a longitudinal axis thereof. A first one of the panels may have an aperture defined therein in communication with the longitudinal recess. A first end of the lever may extend into the longitudinal recess. The heatsink may be pivotably coupled to a second end of the lever opposite the first end. The heatsink may be movable in a translation direction transverse to the longitudinal axis. The heatsink may be translatable between a first position outside of the longitudinal recess and a second position partially inside the longitudinal recess.

An electronic device includes a substrate, at least one electronic element and a heat dissipating electromagnetic shielding structure. The heat dissipating electromagnetic shielding structure is disposed on the substrate and covers the at least one electronic element, wherein the heat dissipating electromagnetic shielding structure includes a shielding frame and a heatsink. The shielding frame includes a plurality of spring members. The spring members are bent toward the substrate and partially abut against the heatsink. When the heatsink and the shielding frame are correspondingly arranged, a shielding space is defined, the electronic element is disposed in the shielding space, and a heat generated by the at least one electronic element is conducted out of the shielding space via the heatsink.

A heat sink assembly for a cage for a field replaceable computing module includes a heat sink, a thermal interface material (TIM), and an actuation assembly. The heat sink includes a mating surface. The TIM includes a first surface that is coupled to the mating surface and a second surface that is opposite the first surface. Thus, the second surface can engage a heat transfer surface of a field replaceable computing module installed adjacent the heat sink. The actuation assembly includes a shape memory alloy (SMA) element. When the SMA element is in a first position, the second surface of the TIM contacts the heat transfer surface of the computing module. When the SMA element moves to a second position, the second surface of the TIM is moved a distance away from the heat transfer surface of the computing module.

An optical module heat dissipation structure, disposed inside an enclosure, where the optical module heat dissipation structure includes an optical module, an elastic component, a fixed wall, and a heat dissipation wall, where the fixed wall and the heat dissipation wall are both connected to the enclosure, the optical module is disposed between the fixed wall and the heat dissipation wall, the elastic component elastically abuts between the fixed wall and the optical module, and elasticity of the elastic component makes the optical module tightly cling to the heat dissipation wall, to improve the heat dissipation efficiency of the optical module heat dissipation structure. An electronic product is further provided where the electronic product includes the optical module heat dissipation structure.

A device and method for assembling an electrical device that includes components attached to a carrier plate and is produced in accordance with an assembly method, wherein at least one component produces dissipated power which is dissipated via a thermal connection to a heat sink.

A member to be fastened on one side of which a member to be fixed is placed; a plate-shaped holding spring member which is disposed on the member to be fixed on one side thereof opposite to the member to be fastened; a support which extends outward of an end part of a longitudinal central part of the plate-shaped holding spring member and which has a through hole formed therein; a supporting column which is provided on the support and bends toward the member to be fastened; a fixing screw hole which is provided in the member to be fastened and disposed at a position corresponding to the through hole of the support so as to have the same axial center as the through hole; and a fixing screw which is inserted into the through hole of the support and screwed to the fixing screw hole.

A data storage system may include multiple data storage devices, such as solid-state drives, an enclosure housing the devices, and a thermal bridge positioned in a gap between and in contact with each of the enclosure and a device, where the enclosure is cooler than the device. Thus, heat is conducted away from a hot spot of the device and to the enclosure. The thermal bridge may be flexible enough to bridge different sized gaps, while stiff enough to generate contact forces applied to the enclosure and the device. For example, the thermal bridge may be constructed primarily of copper and configured to function like a compression spring.

Provided is a cover for pressing a printed circuit board on a heat sink, the cover comprising a metal sheet and one or more domes arranged in the metal sheet, wherein each dome is associated with one or more slits in the shape of ring segments in the metal sheet, the ring segment-shaped slits being provided in the metal sheet side by side and spaced apart from each other, the ring segment-shaped slits surrounding the dome they are associated with. At least at one end of each ring segment-shaped slit a slit extension may be provided in the metal sheet, the slit extension at least in part pointing away from the dome the ring segment-shaped slit is associated with. Further provided is an electronic appliance that includes such a cover, a heat sink and an electronic circuit board sandwiched there between.

Particular embodiments described herein provide for an electronic device that can be configured to enable a segmented heatsink. The electronic device can include a printed circuit board, a substrate, where the substrate is over the printed circuit board, at least two heat sources over the substrate, and a segmented heatsink secured to the printed circuit board, where the segmented heatsink has at least two independent heatsink segments, where each heatsink segment corresponds to at least one heat source and is configured to draw heat from the corresponding heat source. In an example, the heat sources are at a different height.