The present invention is directed to a liquid and solid phase power connect for packaging of an electrical device using a using a phase changing metal. The phase changing metal transitions back and forth between a liquid phase and a solid phase while constantly maintaining connection to the electrical device. The packaging uses a substrate, a restraining housing, and a lid to encase an electrical contact on the electrical device and restrain the phase changing metal. In one embodiment, the entire electrical device is encased and a voltage isolator is utilized to limit the contact areas between the phase changing metal and the electrical device. A method for relieving contact stress by transitioning the phase changing metal from a solid to a liquid is also taught.

A component carrier including a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A component embedded in the stack, and a heat removal body configured for removing heat from the component is connected to the stack and preferably to the component. The heat removal body including a component-sided first heat removal structure thermally coupled with the component, and a second heat removal structure thermally coupled with the first heat removal structure and facing away from the component.

A thermal peak suppression device includes a heat dissipation fin set, a heat dissipator, a thermal phase change material, a filling gas, a fin-array frame and a capillary tube. The heat dissipator includes a thermal conductive block thermally coupled to the heat dissipation fin set, and a closed cavity formed inside the thermal conductive block to have a hot zone and a cold zone. The thermal phase change material is disposed within the hot zone. The filling gas is disposed within the cold zone. The fin-array frame is connected to the thermal conductive block within the cold zone. Two opposite ends of the capillary tube are respectively located within the cold zone and the hot zone. When the thermal phase change material is transformed into a liquid state, the thermal phase change material is sent to the hot zone through the capillary tube.

Thermal interface materials are disclosed that include or are based on thermally reversible gels, such as thermally reversible gelled fluids, oil gels and solvent gel resins. In an exemplary embodiment, a thermal interface material includes at least one thermally conductive filler in a thermally reversible gel.

Stacked semiconductor die assemblies with thermal spacers and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a thermally conductive casing defining a cavity, a stack of first semiconductor dies within the cavity, and a second semiconductor die stacked relative to the stack of first dies and carried by a package substrate. The semiconductor die assembly further includes a thermal spacer disposed between the package substrate and the thermally conductive casing. The thermal spacer can include a semiconductor substrate and plurality of conductive vias extending through the semiconductor substrate and electrically coupled to the stack of first semiconductor dies, the second semiconductor die, and the package substrate.

An apparatus and corresponding approaches for a combined energy dissipation include an energy dissipater forming a hollow chamber therein containing a partial pressure working fluid and a first adjustable thermal connector configured to be placed in an opening of the energy dissipater between an energy generating component to transfer energy there between. The first adjustable thermal connector includes a heat spreader at least partially disposed within the opening of the dissipater, an elastic member operably coupled to the energy dissipater, a flexible membrane coupled to the energy dissipater and the heat spreader, and a phase change material configured to at least partially fill an area defined by the opening, heat spreader, elastic member, and flexible membrane. Upon changing the phase change material to a first material phase, the elastic member applies a biasing force to the energy generating component to align the heat spreader with the energy generating component.

A circuit shielding structure, relating to a technical field of electronics, includes a substrate, wherein: at least one radio frequency component circuit is fixed on the substrate; a wave-absorbing material layer is embedded in the substrate; a shielding wall made of wave-absorbing material is arranged on the substrate and around the radio frequency component circuit; a conductive material layer covers the shielding wall; a closed space is formed among the substrate in which the wave-absorbing material layer is embedded, the shielding wall and the conductive material layer, and the radio frequency component circuit is sealed in the closed space, so that omnidirectional shielding is achieved.

An ultrathin heat dissipation structure includes a copper clad sheet, a cover, a number of bond blocks, and a phase-change material. The copper clad sheet is given containing grooves and a number of ribs round each containing groove. The containing grooves are formed by stamping. The copper clad sheet includes an insulation layer. The copper clad layer is inner surface of the containing groove. The bond blocks are arranged on the ribs and cover is pressed to the stamped copper clad sheet and secured using the bond blocks. The containing grooves form sealing cavities and the phase-change material in the sealed cavity gathers and transfers out any heat generated by components.

An electrically conductive element includes an electrically conductive material and a plurality of inclusions of a phase change material. The phase change material has a phase transition temperature Tc between 150° C. and 400° C. The inclusions are separated from each other and are embedded in the electrically conductive material.

In a wired substrate, heat dissipation performance is improved while an increase in an amount of metal is inhibited.

The substrate includes a transmission line, an insulating material, and a heat storage material. In the substrate provided with the transmission line, the insulating material and the heat storage material, the transmission line transmits a predetermined electrical signal from a semiconductor chip. The transmission line for transmitting the predetermined electrical signal from the semiconductor chip is wired in the insulating material. The heat storage material has a higher thermal conductivity than the insulating material to which the transmission line is wired and accumulates latent heat accompanying phase transition that occurs within an operating temperature range of the semiconductor chip.