A circuit board includes a first thermally conductive structure comprising a cavity or a recess portion. At least a portion of the first thermally conductive structure is inserted into an insulating part. An electronic device comprising a portion thereof inserted in the cavity or the recess portion.

A heat dissipation member includes a body formed of a metal; and an epoxy resin layer formed on a surface of the body and having insulating properties. A printed circuit board includes a heat dissipation member embedded in the printed circuit board, the heat dissipation member including a body formed of a metal and an epoxy resin layer formed on a surface of the body and having insulating properties, and an insulator formed to surround the heat dissipation member.

The present disclosure discusses an improved optical transceiver. The optical transceiver of the present disclosure includes an optical transmitter and an optical receiver coupled to an area of a printed circuit board that includes a plurality of thermal microvias. The thermal microvias are coupled to a heat sink or other heat dissipater and provide a path from the components of the optical transceiver to the heat dissipater for heat to travel.

Among other things, an electronics assembly within an imaging system is provided. The electronics assembly includes a circuit board assembly through which a signal is delivered. The circuit board assembly defines a heat transfer opening between a first side and a second side. An electronics component is electrically coupled to the first side of the circuit board assembly. A heat transfer component supports the electronics component. The heat transfer component includes a base portion coupled to the electronics component and to the circuit board assembly. The heat transfer component includes a heat dissipation portion extending through the heat transfer opening of the circuit board assembly. The heat dissipation portion dissipates heat generated by the electronics component.

The printed circuit with a multi-layer structure comprises: a first layer machined to form a spotface passing through the layer, a second layer comprising a first cavity passing through the layer, a third layer comprising, on one face, an electronic component that is in the first cavity, a fourth layer comprising a second cavity, a heat-conducting element with two parts: one made of metal, called a thermal cover, inserted into the spotface of the first layer so as to close, mechanically and electrically, the first cavity, the other made of a dielectric material with heat conduction >30 W/(m.Math.K), placed in the first cavity so as to be in contact with the electronic component.

A method of producing a printed circuit board (10) with a plurality of inlays (21, 22, 23, 24), having the following steps: supplying a plurality of inlays (21, 22, 23, 24), of which at least one inlay has at least one positioning element (21.1, 21.2; 22.1 to 22.7; 23.1, 23.2; 24.1, 24.2); building up a layer sequence from a plurality of printed-circuit-board layers, with at least one recess (14) for accommodating inlays, wherein, prior to the step of the plurality of inlays (21, 22, 23, 24) being inserted, the recess (14) is defined in an uppermost layer (12) by a frame made of non-conductive printed-circuit-board material; inserting the plurality of inlays (21, 22, 23, 24) into the recess (14) defined by the frame; covering the inlays (21, 22, 23, 24) with a non-conductive printed-circuit-board material; laminating the layer sequence, and removing at least the positioning elements (21.1, 21.2; 22.1 to 22.7; 23.1, 23.2; 24.1, 24.2) which establish a conductive contact between neighboring inlays.

A manufacturing method of a package carrier is provided. A substrate having a through hole is provided, wherein a profile of the through hole from top view is a first rounded rectangular. A heat conducting slug is disposed inside the through hole, wherein the heat conducting slug and an inner wall of the through hole are separated with a gap, and a profile of the heat conducting slug from top view is a second rounded rectangular. An insulating material is filled in the through hole so as to fix the heat conducting slug in the through hole. A conductive through hole structure, a first and a second patterned circuit layers are formed. The first and the second patterned circuit layers are respectively formed on two opposite sides of the substrate. The conductive through hole structure penetrates the substrate and connects portions of the first and the second patterned circuit layers.

A module for use in a hardware platform for networking, computing, and/or storage includes a printed circuit board assembly; components disposed on a primary side of the printed circuit board assembly; a primary side heatsink for a pluggable module, wherein the primary side heatsink is disposed to one or more pivot points on the pluggable module, for applying a uniform and controlled external force against the pluggable module. The module further includes a cage attached to the printed circuit board assembly for supporting the pluggable module, wherein the one or more pivot points are external to the cage.

A component carrier includes a stack having at least one horizontal electrically conductive layer structure, at least one electrically insulating layer structure, a semiconductor component embedded in the stack, and at least one vertical via being laterally offset from the semiconductor component. The at least one horizontal electrically conductive layer structure electrically connects the vertical via to a bottom main surface of the semiconductor component. The component carrier is configured for a current flow from the vertical via to the horizontal electrically conductive layer structure, from the horizontal electrically conductive layer structure to the bottom main surface of the semiconductor component, from the bottom main surface of the semiconductor component to an upper main surface of the semiconductor component, and from the upper surface of the semiconductor component to the outside of the component carrier.

A micromobility transit vehicle may include a wheel, an electric motor associated with the wheel, and a motor controller configured to control a motive force provided by the electric motor to the wheel. The motor controller may include a printed circuit board (PCB), one or more MOSFETs attached to the PCB, and a respective aperture defined through the PCB below each MOSFET. The motor controller may include a thermal assembly associated with each MOSFET and capable of dissipating heat from the MOSFETs to a heat sink. Each thermal assembly may include a heat transfer plug positioned at least partially within an associated aperture of the PCBA to contact an associated MOSFET, and a thermal interface material positioned between the heat transfer plug and the heat sink and capable of dissipating heat from the heat transfer plug to the heat sink.