In aspects of processor heat dissipation in a stacked PCB configuration, a computing device includes a processor for executable instructions processing during which the processor generates heat. The computing device also includes a main printed circuit board (PCB) in a stacked PCB configuration, and the processor is affixed to the main printed circuit board. The stacked PCB configuration forms an enclosed cavity through which heat dissipation is restricted. The computing device includes a heat spreader having a first end connected to the processor via the main printed circuit board by a conductive material, and a second end connected to a heat sink located external to the stacked PCB configuration. The heat spreader exits the enclosed cavity via an opening in the enclosed cavity between the stacked PCB configuration, and the heat spreader transfers the heat away from the processor to the heat sink.

A heat exchange ribbon includes a base portion to be attached to a spacer to be mounted to a circuit board, a tail portion substantially parallel to the base portion, and a leg connecting the tail portion to the base portion. A height of the leg extends in the same direction as a height of the base portion and the tail portion so as to create an opening at least partially surrounded by the base portion, the leg, and the tail portion. The base portion, the tail portion, and the leg portion have a one-piece construction. The leg extends below a lower edge of the base portion such that at least a portion of the tail portion is located below a lower edge of the base portion, and at least a portion of an inner surface of the tail portion does not oppose the outer surface of the base portion.

A system that may include a rigid bus bar body portion having one or more first conductive pathways, and a flexible bus bar body portion extending from the rigid bus bar body portion and having a lower modulus of elasticity than the rigid bus bar body portion, the flexible bus bar body portion including one or more second conductive pathways. The one or more first conductive pathways and the one or more second conductive pathways may be configured to be conductively coupled with a first electronic device to form a conductive connection between the first electronic device and at least a second electronic device.

A battery module, a vehicle, and a method of manufacturing a battery module, the battery module including a housing accommodating a plurality of secondary batteries; and a thermoelectric element assembly on the housing and in contact with the plurality of secondary batteries through at least one contact opening in the housing, the thermoelectric element assembly being configured to heat or cool the plurality of secondary batteries.

A liquid-cooled plate and a heat dissipation device are disclosed. The liquid-cooled plate includes a single-phase channel and a two-phase channel. First fins are spaced apart in the single-phase channel and second fins are spaced apart in the two-phase channel. The first fins are configured to perform a heat exchange with a liquid-state coolant flowing through the single-phase channel to convert the liquid-state coolant after the heat exchange into a gas-liquid two-phase coolant, and the second fins are configured to perform a heat exchange with a gas-liquid two-phase coolant flowing through the two-phase channel to output a coolant after the heat exchange.

In one aspect, thermal management units are described herein which, in some embodiments, offer one or more advantages compared to other units for managing or controlling thermal energy. In particular, units and systems described herein incorporate one or more phase change materials (PCMs), such as one or more PCMs having a certain phase transition temperature, latent heat, and/or phase transition type. The PCMs are contained in equipment housing with the application of various components to provide management or controlling of thermal energy.

A heat sink comprises a bottom plate and a plurality of fins. The bottom plate is formed in a T-shape of a head portion and a body portion and includes a coupling region in which the body portion is thermally coupled to a heat generation element; and the plurality of fins that are erected at the head portion and the body portion of the bottom plate and extend in a direction from the head portion toward the body portion. With the plurality of fins, a pressure loss of first air which flows through a center portion of the head portion is smaller than a pressure loss of second air which flows through a side portion of the head portion in a case where air flows between the plurality of fins along the direction.

A thermal management system includes an ionic motion generator to direct fluid flow towards a heated component (e.g., equipment to be cooled or a heatsink mounted thereat). In certain systems, the fluid is directed through a conduit arrangement. In certain systems, the fluid is directed past the heated component to a heat exchanger. Certain types of thermal management systems have no moving components to create the fluid flow.

According to one embodiment, a memory system includes a first plate, an intermediate member, and a substrate. The intermediate member includes a second plate and a pair of side walls. The second plate includes a first opening, and is arranged to have a gap with respect to the first plate. The second plate includes a first face facing the first plate and a second face located on a side opposite to the first face. The pair of side walls is arranged on the second face. The substrate is placed between the pair of side walls. The substrate includes a third face on which a first non-volatile memory package and a controller package are mounted. The third face faces the second plate. The first non-volatile memory package is thermally connected to the second plate. The controller package is thermally connected to the first plate through the first opening.

An information handling system includes a heatsink interface component, a printed circuit board assembly, and an upstream heatsink. The heatsink interface component aligns the upstream heatsink on the printed circuit board assembly. The heatsink interface component includes first, second, third, and fourth sides. The heatsink interface component also includes multiple posts. Each of a first set of the posts is located on a top surface of the second side, and each of a second set of the posts is located on a top surface of the fourth side. The heatsink interface component also includes recesses located within the second and fourth sides. Each of a first set of the recesses extends from a bottom surface to the top surface of the second side, and each of a second set of the recesses extends from a bottom surface to the top surface of the fourth side.