A power module including at least one substrate, a housing arranged on the at least one power substrate, a first terminal electrically connected to the at least one power substrate, a second terminal including a contact surface, a third terminal electrically connected to the at least one power substrate, a plurality of power devices arranged on and connected to the at least one power substrate, and the third terminal being electrically connected to at least one of the plurality of power devices. The power module further including a base plate and a plurality of pin fins arranged on the base plate and the plurality of pin fins configured to provide direct cooling for the power module.

A cold plate is configured to use isolated primary and secondary liquid coolants and comprises: a thermally conductive body defining an internal volume and arranged for mounting with respect to an electronic device, so as to transfer heat from the electronic device to the internal volume; a coolant inlet for receiving the secondary liquid coolant into the internal volume to receive the transferred heat; and a coolant outlet for the secondary liquid coolant to flow out of the internal volume. The thermally conductive body is configured to define an external receptacle having a volume arranged to receive and retain the primary liquid coolant for heat transfer between the primary and secondary liquid coolants. The cold plate may form part of a system for cooling electronic devices.

Integrated Thermal Interface Detachment Mechanism for Inaccessible Interfaces are disclosed. According to an aspect, an exemplary device for an electronic component having a thermal interface material, comprising a heat sink configured to contact the thermal interface material and configured to heat transfer interface with the electronic component while the thermal interface material is in contiguous contact with both the heat sink and the electronic component, and a separator mechanism configured to advance a separator ram with respect to the heat sink and effect a force upon the thermal interface material, such that advancing the ram breaks the contiguous contact of the thermal interface material with at least one of the heat sink and the electronic component.

A substrate-fastening device and a substrate-assembling structure are disclosed. The substrate-fastening device includes a base and a fastening component. The base correspondingly carries a substrate including a perforation. The fastening component is disposed on the base, corresponds to the perforation, and includes a supporting portion, a positioning portion, a resin-attaching portion, an end portion and a fixation resin. The supporting portion is disposed on the base to support the substrate. The positioning portion is disposed on a supporting surface of the supporting portion and extended along the perforation. The resin-attaching portion is extended along the perforation. The end portion is connected to the positioning portion through the resin-attaching portion. The fixation resin is disposed around the resin-attaching portion and connected between the end portion and the positioning portion. The fixation resin covers the second surface adjacent to the perforation, and fills the gap between the resin-attaching portion and the perforation.

An electronic device is provided, which is for coupling to another electronic device in a side-by-side manner, and the electronic device includes a substrate, a first thermal dissipation sheet and a thermal dissipation element. The substrate includes a first surface and a second surface. The first thermal dissipation sheet is disposed on the first surface. The thermal dissipation element is disposed on the substrate. The first thermal dissipation sheet is disposed between the thermal dissipation element and the substrate, and the thermal dissipation element at least partially overlaps the first thermal dissipation sheet.

A cooling device includes a cooling plate with a bottom wall portion with a lower surface which contacts a heat-generating component, a top wall portion which covers an upper surface of the bottom wall portion, a side wall portion which couples the bottom wall portion and the top wall portion, and an internal space which is surrounded by the bottom wall portion, the top wall portion, and the side wall portion to define a first cooling medium flow passage. The bottom wall portion includes blades on the upper surface. An inlet port or an outlet port is on one end side of the first cooling medium flow passage. An inner peripheral wall of the side wall portion includes a first bent portion which is bent convex inward between ends of the blades and the at least one of the inlet port and the outlet port.

This document describes a passive thermal-control system that can be integrated into an electronic speaker device and associated electronic speaker devices. The passive thermal-control system uses an architecture that combines heat spreaders and thermal interface materials to transfer heat from heat-generating electronic devices of the electronic speaker device to a housing component of the electronic speaker device. The housing component dissipates the heat to prevent a thermal runaway condition.

Various technologies described herein pertain to a heat spreader for an autonomous vehicle computing device. The heat spreader includes a top surface, a bottom surface, and a side surface. The top surface of the heat spreader is thermally conductive. The top surface of the heat spreader includes a section that is sized and shaped to align with a heat generating component (e.g., on a printed circuit board assembly). The top surface of the heat spreader is configured to receive heat from the heat generating component. The bottom surface of the heat spreader includes externally integrated fins. The heat spreader is configured to dissipate the heat from the heat generating component such that the heat from the heat generating component flows from the top surface to the externally integrated fins on the bottom surface.

A double-sided cold plate includes a manifold comprising openings extending from a first surface of the manifold through the manifold to a second surface of the manifold forming recesses within the manifold and an inlet channel and an outlet channel fluidly coupled to the recesses within the manifold, a plurality of first heat sinks coupled to the first surface of the manifold enclosing the openings on the first surface, and a plurality of second heat sinks positioned adjacent each other along a length of the manifold and coupled to the second surface of the manifold, enclosing the openings on the second surface, a width of the plurality of second heat sinks is greater than a width of the manifold thereby forming an overhanging portion on each lengthwise side of the manifold, the overhanging portion configured to mechanically support a plurality of electrical components positioned around a perimeter of the manifold.

A cold plate for cooling a heat-generating component in a computer system is disclosed. The cold plate includes a lid member with a lower supply manifold housing and a lower collection manifold housing. The cold plate includes a base member having coolant channels defined by fins. Each of the fins have a top section and a bottom section attached to the base member. An interior cavity is defined by an arc-shaped section of the fins, the interior surface of the base, and the lower supply manifold housing. An interior corner is formed by the lower supply manifold housing of the lower manifold housing at the top of the fins to trap debris. An upper inlet manifold has a connector to receive coolant. An upper outlet manifold has a connector to circulate coolant. The upper manifolds are in fluid communication with the collection manifold housings.