An internal component and external interface arrangement for a cylindrical compact computing system is described that includes at least a structural heat sink having triangular shape disposed within a cylindrical volume defined by a cylindrical housing. A computing engine having a generally triangular shape is described having internal components that include a graphics processing unit (GPU) board, a central processing unit (CPU) board, an input/output (I/O) interface board, an interconnect board, and a power supply unit (PSU).

The present disclosure provides a liquid cooling assembly and a liquid cooling apparatus. The liquid cooling assembly includes: two heat conducting plates, configured to perform heat dissipation on a storage module attached to each of the heat conducting plates; a liquid cooling tube, disposed on an end of the each heat conducting plates and configured to perform liquid cooling on the heat conducting plates; and an elastic support, disposed between the two heat conducting plates and configured to apply elastic pressure to the heat conducting plates during attachment between the heat conducting plates and the storage modules, to cause the heat conducting plates to be tightly attached to surfaces of the storage modules, and cause the storage modules to be easily separated from the heat conducting plates after the elastic support is removed from the two heat conducting plates.

In various embodiments, laser devices feature means, such as fasteners, for attaching a laser package to a cooling plate, which allow motion of the laser package in response to thermal cycles resulting from operation of a beam emitter therewithin. Embodiments of the invention additionally or instead include laser devices featuring segmented barrier layers for electrically isolating the laser package from the cooling plate.

A thermal bridge includes an upper bridge assembly including upper plates arranged in an upper plate stack and a lower bridge assembly including lower plates arranged in a lower plate stack. Outer ends of the lower plates face and thermally couple to an electrical component. The upper plates and the lower plates are arranged in plate pairs. A spring element forces the upper plates and the lower plates of the plate pairs apart. The upper plates include upper limit tabs and the lower plates include lower limit tabs. The upper limit tabs and the lower limit tabs operate to limit spreading apart of the upper plates and the lower plates against the opening forces of the spring element.

There is provided a docking station capable of docking and undocking a portable computing device. The docking station includes: an engaging lever engageable with an engaging hole located in a portable computing device; and a docking sensor which detects when the engaging lever is engaged with the engaging hole.

Heat transfer devices and systems for thermally coupling electrical components to a heatsink can comprise one or more all-metal heat transfer device(s) thermally coupling at least one electrical component to a heatsink. A heat transfer device can comprise a metal cup attached to a metal heatsink, and a metal piston and a compliant device disposed in the cup. The piston is forcible to a secured first position, upon reflowing solder, while compressing the compliant device. Upon reflowing solder again, the compliant device causes the piston to bias and attach to the electrical component to provide an all-metal thermal path and absorb assembly tolerances to avoid using thermal gap fillers. A method is provided for thermally coupling a heatsink to a plurality of electrical components via a plurality of all-metal, expandable heat transfer devices.

A sprung frame assembly that can accommodate varying tolerance device heights while still exerting sufficient pressure/force required to a heatsink to contact and cool a bare die device, or other device of the like. Adapted for space constrained modules where placement of mounting holes is limited, and module density is high. Sprung frames are secured to mounting points at available locations on support structures as to eliminate any mounting holes in the PCB. The required force/pressure can be evenly achieved by methodically tightening a plurality of screws with springs at the corners of the sprung frames in sequence, pressure is applied evenly without damaging the device, while also taking up any tolerances in the device height.

An internal component and external interface arrangement for a cylindrical compact computing system is described that includes at least a structural heat sink having triangular shape disposed within a cylindrical volume defined by a cylindrical housing. A computing engine having a generally triangular shape is described having internal components that include a graphics processing unit (GPU) board, a central processing unit (CPU) board, an input/output (I/O) interface board, an interconnect board, and a power supply unit (PSU).

A connector, comprises: a cage having a chamber having a top wall; a radiator mounted on the top wall of the chamber; an elastic clip fixing the radiator on the top wall of the chamber and having a first side and a second side opposite to the first side in a lateral direction of the chamber; a first latch on the cage and having a slot; a second latch on the cage and having a slot; a first hook on the first side of the elastic clip engaged into the slot of the first latch from an outer side of the first latch; and a second hook on the second side of the elastic clip engaged into the slot of the second latch from an inner side of the second latch far away from the first latch and facing the first latch.

A socket for an electric component includes a socket body in which a contact pin is provided in a housing part and a cover member provided so as to be rotatable with respect to the socket body. The cover member has a cover member body and a heat slug in contact with an electric component. The heat slug is configured so as to move downward and press the electric component by being pressed from above by a cooling head in a state in which the cover member is closed. In a state in which the electric component is housed in the housing part, a restricting mechanism allows the downward movement of the heat slug, whereas in a state in which the electric component is not housed in the housing part, the restricting mechanism prevents the downward movement of the heat slug.