A connector is provided with a base, a terminal, a cover and a heat conductive member. The base has a holding portion, and the terminal is held by the holding portion. The cover is provided with a main portion having an inner surface and an outer surface. The heat conductive member is fixed on the inner surface. When the connector is connected to a card-type device, the terminal pushes a card-type device against the heat conductive member in a predetermined direction perpendicular to a circuit board. When the connector is connected to the card-type device, an interval between the main portion and the holding portion is kept constant in the predetermined direction.

A circuit board assembly for electronic devices includes a circuit board having a first surface and a second surface opposite the first surface, and a heat sink carrier disposed on the first surface of the circuit board. The heat sink carrier includes at least one clamp portion. The assembly also includes a heat sink. The heat sink is positioned in the at least one clamp portion of the heat sink carrier to transfer heat from one or more electronic devices to the heat sink via the heat sink carrier.

A package which comprises a carrier, electronic components mounted on the carrier, an encapsulant at least partially encapsulating the carrier and the electronic components, a clip connected to upper main surfaces of the electronic components, and an electrically conductive bulk connector which is electrically connected with and mounted above the electronic components.

The present disclosure is directed to systems and methods of improving the thermal performance of processor-based devices. Such thermal performance improvement may include limiting the degree of tilt experienced by a semiconductor device as a thermal solution coupled to the semiconductor device is tightened to the substrate. Such thermal performance improvements may include increasing the available heat transfer area associated with a particular heat producing semiconductor device. Such thermal performance improvements may include thermally coupling one or more cool blocks thermally coupled to one or more remote heat-producing devices to a central cool block that may be cooled using a cooling medium or coupled to a central heat-producing semiconductor device.

Provided are an electric device and a heat radiator capable of suppressing vibration caused by external stress of the heat radiator. The electric device includes a substrate; an electronic component attached to the substrate; and a heat radiator including at least one first fin, and a second fin facing the first fin, thermally connected to the first fin, and provided at a position closer to an attachment surface of the substrate than any of the first fins. The heat radiator is thermally connected to the electronic component, and one end of an attachment member is attached to the first fin, and another end of the attachment member is attached to the substrate. The attachment member has a height with respect to the attachment surface that is higher than a thickness of the first fin.

An electronic assembly and a heat dissipation assembly thereof. The electronic assembly includes a circuit board and a heat dissipation assembly. The circuit board includes a plate body and a heat source disposed on the plate body. The heat dissipation assembly includes a fin assembly, a mounting plate body, and a heat dissipation pillar. The mounting plate body is fixed to the fin assembly and includes a mounting hole. The heat dissipation pillar is engaged in the mounting hole of the mounting plate body. One end of the heat dissipation pillar is in thermal contact with the fin assembly, and another end of the heat dissipation pillar is in thermal contact with the heat source of the circuit board.

A thermal chamber includes multiple sides, such as a back side, a front side, a first end, a second end, a top side, and a bottom side. The multiple sides form a cavity. The top side includes one or more ports. Each of the one or more ports includes a top side open area that exposes the cavity within the thermal chamber. Each of the one or more ports is configured to receive a temperature control component that transfers thermal energy to and from an electrical device exposed via the cavity. The top side open area of the one or more ports has a corresponding bottom side open area of the bottom side located below the top side open area. The bottom side open area is configured to allow the temperature control component to contact the electrical device that is exposed via the bottom side open area.

A heat sink apparatus that utilizes a pivot couple and support with anchor-spring mounts to enable exertion of a uniform amount of force over the mounting surface of the apparatus that is thermally/physically coupled to a heat load. The apparatus can include a heat sink base that has a bottom side defining the mounting surface, and a top side to which a support is pivotally coupled by a pivot couple. The apparatus can include a first and second anchor that each have a first end connected to an anchor point and a second end coupled to a load surface on the support by a spring. The load surfaces can be symmetrically disposed on opposite sides of the pivot couple, which is centrally located relative to the mounting surface so that the force imparted by spring loads of the springs is evenly distributed over the mounting surface.

Provided herein are semiconductor packages with improved clamps. In some embodiments, a semiconductor package may include a housing having a wall extending from a main body, and a set of support walls extending from the wall. The semiconductor package may further include a clamp extending between the set of support walls, the clamp having a first planar section coupled to a first support wall of the set of support walls, a second planar section coupled to a second support wall of the set of support walls, and a third planar section between the first and second planar sections. The third planar section may include an opening operable to receive a fastener, and a plurality of stress relief openings.

A fastening mechanism for retaining a heat sink upon the CPU includes a fastening seat surrounding the connector, and a pair of fastening clips. The fastening seat includes four alignment posts at four corners, and the pair of fastening clips are attached at two corresponding diagonal corners. Each fastening clip includes a mounting section secured to the corresponding post, a latching section for temporarily holding the heat sink, and a resilient arm for upwardly urging the heat sink. Each alignment post is equipped with a screw nut and a coil spring so as to reinforce the downward pressing forces against the heat sink for assuring reliable connection between the CPU and the contacts of the electrical connector for better electrical transmission and intimate contact between the CPU and the heat sink for efficient heat dissipation.