Detector modules, systems and methods for detecting signal beams are disclosed using a detector module and a support comprising a feedthrough.

Furthermore, apparatuses, systems, and methods for sealing a vacuum system configured to provide an atmospheric environment and a vacuum chamber environment are disclosed. In some embodiments, a printed circuit board (PCB) comprising a first side for exposing to the atmospheric environment and a second side for exposing to the vacuum chamber environment and for covering an aperture in the vacuum chamber environment, wherein the second side is opposite to the first side. The apparatuses, systems, and methods may include a rigid body on the first side of the PCB and a device connected to the second side of the PCB and positioned on a portion of the PCB that covers the aperture. The PCB may be configured to provide an interface between the device and the rigid body.

In one example, a first tubular member has a first diameter and is configured to attach to a printed circuit board. A second tubular member has a second diameter different from the first diameter and is configured to hold an environmental sensor for collecting data relating to an environment of the printed circuit board. The second tubular member is vertically adjustable relative to the first tubular member.

A power electronics module includes a cold plate manifold, a heat sink base layer at least partially embedded in the cold plate manifold, an electrically-insulating layer in direct contact with the heat sink base layer, a conductive substrate positioned on the electrically-insulating layer, and a power electronics device coupled to and in direct contact with the conductive substrate.

A thermal management system that include an electronic circuit boards having at least two circuit boards with a space in between and further includes one or more air tubes or conduits. The electronic circuit board and air tubes are configured for drawing air into the space to facilitate cooling of the electronic circuit board concurrent with cooling of a heat sink of a heat pump connected with the electronic circuit board. The system can further include a partition to isolate airflow from the heat sink from airflow through the electronics circuit board, and can further include one or more interface components for maintaining isolation and control of air flow, improving air intake and/or supporting auxiliary components.

In one embodiment, an electronic system includes a printed circuit board, one or more packaged semiconductor devices, and a vapor chamber having a top and a bottom and enclosing a sealed cavity that is partially filled with a coolant. The vapor chamber comprises a thermo-conductive and electro-conductive material. The top of the vapor chamber has one or more depressions formed therein, each depression receiving and thermo-conductively connected to at least part of a bottom of a corresponding packaged semiconductor device, which is mounted through a corresponding aperture in the PCB. A heat sink may be thermo-conductively attached to the bottom of the vapor chamber.

Examples described herein relate to cooling system for an electronic circuit module. The cooling system includes a frame disposable on the electronic circuit module and comprising a plurality of compartments defined by compartment walls. The cooling system further includes a plurality of cold plates disposed in the plurality of compartments of the frame and in thermal contact with the electronic circuit module, wherein the plurality of cold plates includes one or more passages to allow flow of a coolant there-through to conduct heat away from the electronic circuit module. Further, the one or more cold plates of the plurality cold plates include a guide feature to allow vertical movement of the one or more cold plates in respective compartments.

A method of manufacturing a driver board assembly includes embedding one or more power device assemblies within a first PCB material layer, forming one or more cooling channels within a surface of the first PCB material layer such that the one more cooling channels extend proximate to the one or more power device assemblies, forming a plurality of thermally conductive vias extending between a surface of the one or more power device assemblies and the one or more cooling channels, and bonding a second PCB material layer to the first PCB material layer to enclose the one or more cooling channels between the first PCB material layer and the second PCB material layer.

A printed circuit board for high-power components includes at least two dielectric layers. A thermally-conductive embedded layer is disposed between two of the dielectric layers and includes one or more internal coolant channels. Thermal vias extend from the embedded layer to an exterior surface of at least one of the dielectric layers. At least one of the dielectric layers in the printed circuit board has an exterior surface on which one or more high power components may be mounted. In some implementations, there are at least two dielectric layers on a same side of the embedded layer and high power components may be located inside the printed circuit board between two dielectric layers. Thermal resistance between the high-power components and the embedded layer is decreased in comparison to typical surface-mounted cold plates, resulting in more efficient heat dissipation. In some implementations the embedded layer is also an electrical ground plane.

In one embodiment, an apparatus includes an enclosure configured for connection to a printed circuit board, a substrate within the enclosure, a plurality of components mounted on the substrate, a fluid inlet connector, a fluid outlet connector, and a plurality of flow channels within the enclosure, at least one of the components disposed in each the flow channels and segregated from other components in another of the flow channels. The enclosure is configured for immersion cooling of the components.

Disclosed is an electronic device including a heat dissipation structure that includes a first printed circuit board; a thermal diffusion member arranged in parallel to the first printed circuit board; a second printed circuit board which is arranged to be separated from the first printed circuit board and which is electrically connected with the first printed circuit board; and a heat transfer member of which at least a partial area faces a heat dissipation member, and of which at least another partial area, formed to be bent, is arranged to face one surface of the second printed circuit, and additional other various embodiments are possible.