In an example, a thermal interface material includes a polymeric phase-change material.

The invention relates to a manufacturing process for a heat dissipation heat sink composite having heat dissipation function and a manufacturing method for a finished product thereof. It comprises the steps of rolling a first heat conductive material and a substrate to adhere the first heat conductive material to the substrate for fixation; adhering a second heat conductive material to the substrate for combination; and rolling the second heat conductive material and the substrate for firmly combination and fixation to complete the manufacturing of a composite material.

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.

Embodiments of the disclosure relate to flexible electronic substrates for placement on an external surface of a vehicle motor assembly. In one embodiment, a motor assembly includes a motor comprising an external surface and one or more electronic assemblies positioned on the external surface of the motor. Each electronic assembly includes a metal substrate disposed on the external surface of the motor, a dielectric layer disposed on the metal substrate, a flexible metal base layer disposed on the dielectric layer, a bonding layer disposed on the flexible metal base layer, and one or more electronic devices disposed on the bonding layer. The bonding layer bonds the one or more electronic devices to the flexible metal base layer.

Embodiments of the disclosure relate to an MIO substrate with integrated jet cooling for electronic modules and a method of forming the same. In one embodiment, a substrate for an electronic module includes a thermal compensation base layer having an MIO structure and a cap layer overgrown on the MIO structure. A plurality of orifices extends through the thermal compensation base layer between an inlet face and an outlet face positioned opposite to the inlet face, defining a plurality of jet paths. A plurality of integrated posts extends outward from the cap layer, wherein each integrated post of the plurality of integrated posts is positioned on the outlet face between each orifice of the plurality of orifices.

A semiconductor package includes a semiconductor chip; a redistribution insulating layer including a first opening; an external connection bump including a first part in the first opening; a lower bump pad including a first surface in physical contact with the first part of the external connection bump and a second surface opposite to the first surface, wherein the first surface and the redistribution insulating layer partially overlap; and a redistribution pattern that electrically connects the lower bump pad to the semiconductor chip.

Embodiments of the disclosure relate to an electronic assembly including a substrate having a first surface and a second surface opposite to the first surface and one or more electronic devices bonded to the first surface of the substrate. A first heat-storing region is embedded within the substrate and proximate to the second surface. The first heat-storing region comprises a phase change material encapsulated by an encapsulating layer. A melting temperature of the encapsulating layer is higher than a melting temperature of the phase change material and a maximum operating temperature of the one or more electronic devices. A heat transfer layer is embedded within the substrate and thermally connects the first heat-storing region to the one or more electronic devices.

This application provides a method for manufacturing a heat dissipation structure of an electronic element, a heat dissipation structure, and an electronic device. The method includes: placing a substrate having an electronic element in an environment that meets a preset temperature condition; and in the environment that meets the preset temperature condition, covering a periphery of the electronic element with a heat dissipation cover, fixedly connecting the heat dissipation cover to the substrate, and placing a solid-state phase-change thermally conductive material in an accommodation cavity surrounded by the substrate and the heat dissipation cover.

A thermal management unit includes a heat sink, which includes a base portion having a first side and a second side opposite the first side. The heat sink also includes a first protrusion structure and a second protrusion structure. The first protrusion structure protrudes from the first side of the base portion, and the first protrusion structure includes a plurality of fins. The second protrusion structure protrudes from the second side of the base portion, and the second protrusion structure includes a plurality of ribs.

A method for manufacturing the ultrathin heat dissipation structure includes providing a copper clad sheet, the copper clad sheet comprising an insulation layer and a copper clad layer; stamping the copper clad sheet to form a plurality of containing grooves and a plurality of ribs around each of the plurality of containing grooves, the cooper clad layer is used as an inner surface of the containing groove and the insulation layer is then an outer surface of the containing groove; providing bond blocks on each of the plurality of ribs; infilling phase-change material into the containing grooves of the copper clad sheet; providing a cover, pressing the cover to the bond blocks, the cover is fixed with the copper clad sheet by the bond blocks, the cover seals the containing grooves, and the phase-change material is received in the containing grooves; and solidifying the bond blocks.