An apparatus includes a main substrate, a device, and a heat spreader. The main substrate is configured for mounting the device in a mounting location thereon and having a cavity located below the mounting location. The device is mounted in the mounting location, and the heat spreader is fitted into the cavity and coupled to the device and to a heat sink. The heat spreader is configured to conduct heat from the device to the heat sink and to provide electrical insulation between the device and the heat sink.

An electronic device includes a press-fit terminal, an electronic component and a substrate. The substrate includes a first through hole, a second through hole and an inlay. The press-fit terminal is press-fitted in the first through hole. The second through hole is located between the first through hole and a part of the substrate at which the electronic component is mounted. The inlay is made of a metal material and press-fitted in the second through hole. The inlay restricts a strain in the substrate and restricts decrease of a holding force of the substrate holding the press-fit terminal.

A multilayer substrate includes a base including insulating layers stacked on one another, a first principal surface, and a second principal surface, a heat transfer member extending through a first insulating layer nearest to the first principal surface, a second coefficient of thermal conductivity of a material of the heat transfer member is higher than a first coefficient of thermal conductivity of a material of the insulating layers, a first metal film adhered to the first principal surface, the first metal film overlapping the heat transfer member when viewed from the layer stacking direction, and a first joining member disposed between the heat transfer member and the first metal film and being made of a material with a coefficient of thermal conductivity which is higher than the first coefficient of thermal conductivity of the material of the insulating layers.

A heat transfer assembly may be used to provide a thermal conduit from a module mounted on a circuit board through the circuit board, allowing a thermal path away from the module. The heat transfer assembly generally includes a thermally conductive base with at least one raised thermal pedestal accessible through at least one heat transfer aperture in the circuit board and in thermal contact with the module. In an embodiment, the heat transfer assembly is used in a remote PHY device (RPD) in an optical node, for example, in a CATV/HFC network. The RPD includes an enclosure having a base with at least one raised thermal pedestal in thermal contact with an optical module (e.g., an optical transmitter or transceiver) on a circuit board through at least one heat transfer aperture in the circuit board.

An electrical power supply device for at least one light source of the light emitting diode type and at least one electronic component, including a circuit for driving the electrical power supply of the light source or each light source, the drive circuit including at least one electrical conductor track and a housing for accommodating an insert, and an insert in an electrically conducting material, the insert being inserted in the accommodation housing and including a first end portion electrically connected to the conductor track, and a second end portion suited to being electrically connected to at least one electronic component so as to supply electrical power to the electronic component.

A component carrier for carrying and cooling at least one heat generating electronic component is presented. The component carrier comprising includes an outer layer structure, an electrically insulating layer arranged adjacent to the outer layer structure, and a heat conducting structure arranged adjacent to the electrically insulating layer on a side opposite to the outer layer structure. The heat conducting structure is thermally coupled to the at least one heat generating electronic component such that the outer layer structure receives thermal radiation irradiated by the heat conducting structure and transports corresponding heat away from the component carrier via convection by a heat transfer medium surrounding the component carrier.

The present disclosure provides a circuit board assembly, a TOF camera module including the circuit board assembly and applications thereof. The circuit board assembly is used to support an electronic component, and includes a conductive portion and an insulating portion. The insulating portion is integrally bonded to the conductive portion, and the conductive portion extends through the insulating portion. The electronic component is supported by the conductive portion and is communicated with the conductive portion, so that the electronic component directly dissipates heat through the conductive portion during operation.

A high-density memory system includes at least one memory-dense compute unit with a printed circuit board (PCB) having a half-width one rack unit (1 U) form factor, more than 20 memory module slots arranged depth-wise from a front to a rear of the PCB with a horizontal orientation that is parallel to the half-width 1 U form factor, at least one processor positioned in between the memory module slots, a dripless connector with a first port that receives a cooling solution from a manifold of a cooling unit and a second port that returns the cooling solution into the manifold, tubing that extends the full length of the PCB from the first port past the memory module slots and the at least one processor and back to the second port, and cooling blocks that are located in between the memory module slots and that are connected to the tubing.

A drive unit for an elevator system, the drive unit including a multilayer, power circuit board; a first DC link formed in a layer of the power circuit board; a second DC link formed in a layer of the power circuit board; a first switch having a first terminal, the first switch mounted to a surface of the power circuit board; a first via electrically coupling the first terminal to the first DC link; a second switch having a second terminal, the second switch mounted to the surface of the power circuit board; and a second via electrically coupling the second terminal to the second DC link; the first via conducting heat from the first switch to the first DC link; the second via conducting heat from the second switch to the second DC link.

Techniques and mechanisms for providing efficient heat dissipation by a circuit assembly. In an embodiment, the circuit assembly includes an inductor and a packaged device coupled thereto, where the inductor forms heat dissipation structures on various respective sides of a ferromagnetic body. The packaged assembly includes a circuit board disposed in a mold material, where a metal core of the circuit board is thermally coupled to transfer heat from one or more circuit components of the packaged device to the inductor via one or more conductors extending from the package mold. In another embodiment, portions of the metal core have different respective vertical spans which contribute to different thermal conductivity characteristics across various regions of the circuit board.