A package structure includes a bottom plate, a semiconductor package, a top plate, a screw and an anti-loosening coating. The semiconductor package is disposed over the bottom plate. The top plate is disposed over the semiconductor package, and includes an internal thread in a screw hole of the top plate. The screw penetrates through the bottom plate, the semiconductor package and the top plate, and includes an external thread. The external thread of the screw is engaged to the internal thread of the top plate, and the anti-loosening coating is adhered between the external thread and the internal thread.

A base of a connector defines an accommodation portion for accommodating a card-type device. The base has holding portions with surfaces directed to the accommodation portion. The holding portions hold held portions of terminals 40. Heat conductive members are provided on the surfaces of the holding portions. The heat conductive members are sandwiched between the card-type device and the holding portions when the card-type device is connected to the connector 10. In this way, heat conductive paths, which include the conductive members, are formed between the card-type device and held portions of the terminals 40.

Methods/structures of joining package structures are described. Those methods/structures may include a first side of a die disposed on a first side of a substrate, and a cooling structure on a second side of the die, wherein the cooling structure comprises a first section attached to the substrate, and a second section disposed on a second side of the die, wherein the first and second sections are separated by an opening in the cooling structure. The opening surrounds a portion of the second section, and at least one flexure beam structure connects the first and second sections.

A microprocessor carrier comprising a lever having an elongate arm and a wedge structure extending from one end of the elongate arm, and a frame comprising and a fulcrum structure to receive the lever and a microprocessor. The fulcrum structure is to couple the lever to the frame.

A semiconductor package structure includes a package substrate and a semiconductor die. The package substrate includes a plurality of hollow vias extending through the package substrate. The semiconductor die is electrically connected to the package substrate. The hollow vias are disposed under the semiconductor die.

A semiconductor device includes a chip package comprising a semiconductor die laterally encapsulated by an insulating encapsulant, the semiconductor die having an active surface, a back surface opposite to the active surface, and a thermal enhancement pattern on the back surface; and a heat dissipation structure connected to the chip package, the heat dissipation structure comprising a heat spreader having a flow channel for a cooling liquid, and the cooling liquid in the flow channel being in contact with the thermal enhancement pattern.

A semiconductor device comprising at least a semiconductor component, a heat sink, a connecting element and an electrical circuit connected to the heat sink in an electrically conductive manner; wherein the semiconductor component and the heat sink are arranged at a distance from one another and are electrically and thermally conductively connected via the connecting element, wherein an electrical current can be supplied to the electrical circuit via the heat sink.

Methods/structures of joining package structures are described. Those methods/structures may include a first side of a die disposed on a first side of a substrate, and a cooling structure on a second side of the die, wherein the cooling structure comprises a first section attached to the substrate, and a second section disposed on a second side of the die, wherein the first and second sections are separated by an opening in the cooling structure. The opening surrounds a portion of the second section, and at least one flexure beam structure connects the first and second sections.

An electromagnetic wave absorption sheet is arranged to contact an upper surface and side surfaces of an electronic component mounted on a wiring board, a heat conduction plate is arranged to contact the electromagnetic wave absorption sheet, a heat transfer sheet is arranged to contact the heat conduction plate, and a heat dissipation member is arranged to contact the heat transfer sheet. Heat conductive particles contained in the heat transfer sheet contact a flat surface portion of the heat conduction plate. The electromagnetic wave absorption sheet, the heat conduction plate, and the heat transfer sheet are interposed between the heat dissipation member and the electronic component, as a heat conduction member for conducting heat generated in the electronic component and the like to the heat dissipation member.

A semiconductor device includes a base plate, a semiconductor chip, a case, a heat dissipation member, and a plurality of attachment portions. The semiconductor chip is held on a front surface side of the base plate. The case is provided on a front surface of the base plate so as to house the semiconductor chip inside. The heat dissipation member is provided on a back surface of the base plate and contactable with a heat sink for cooling the semiconductor chip. The plurality of attachment portions have a function of attaching the case to the heat sink. Ends of the heat dissipation member in a direction extending along a long side of a plurality of sides that form a shape defined by connecting positions of the plurality of attachment portions in plan view are located between the two attachment portions that form the long side.