This disclosure details a coolant distribution module as used in a thermal management systems for thermally managing electrified vehicle components. An exemplary coolant distribution module includes a module body including a plurality of inlet ports and a plurality of outlet ports, a first manifold valve encompassed within the module body, and a second manifold valve encompassed within the module body. The first manifold valve includes a plurality of first valve inputs wherein each first valve input is in communication with at least one inlet port of the plurality of inlet ports, and a plurality of first valve outputs wherein each first valve output is in communication with at least one outlet port of the plurality of outlet ports. The second manifold valve includes a plurality of second valve inputs wherein each second valve input is in communication with at least one inlet port of the plurality of inlet ports, and a plurality of second valve outputs wherein each second valve output is in communication with at least one outlet port of the plurality of outlet ports.

A backplane management and configuration system includes a chassis housing a first storage system having a first backplane, a second storage system having a second backplane, a second computing device coupled to each of the first backplane and the second backplane via a second multiplexer and a communication bus, and a first computing device coupled to each of the first backplane and the second backplane via a first multiplexer and the communication bus. A backplane configuration/management subsystem in the first computing device detects a multi-computing-device configuration including the first and second computing devices in the chassis and, in response, determines a first computing device location in the chassis. Based on the first computing device location, the backplane configuration/management subsystem identifies a first backplane identifier for the first backplane and, in response, configures the first backplane for management by the backplane configuration/management subsystem and ignores the second backplane.

Example implementations relate to an electronic port of an electronic device, having a locking assembly to secure an electronic plug within the electronic device. The electronic port includes a receptacle, and the locking assembly including a rocker switch, a bracket, and an elastic arm. The receptacle is releasably connectable to a connector of the electronic plug. The rocker switch is pivotably connected to an enclosure of the electronic device. The bracket extends from the rocker switch, and disposed around a first end portion of the receptacle. The elastic arm includes a locking tab engaged with the bracket, and a seating tab seated on a second end portion of the receptacle. Where, in relaxed state of the elastic arm, lock features of the locking tab protrudes into the receptacle, and where the elastic arm is deformable from relaxed state to biased state to pull the lock features out of the receptacle.

A method includes forming a release film over a carrier, attaching a device over the release film through a die-attach film, encapsulating the device in an encapsulating material, performing a planarization on the encapsulating material to expose the device, detaching the device and the encapsulating material from the carrier, etching the die-attach film to expose a back surface of the device, and applying a thermal conductive material on the back surface of the device.

A control-cabinet system includes a base module and a plurality of functional modules. The base module housing has a face with openings, first connection elements and second connection elements. The first connection elements provide data and extra-low voltage connections, and the second connection elements provide low voltage connections. The first connection elements are arranged within the housing, in the area of the openings. The data connections are connected to a data line, the extra-low voltage connections are connected to an extra-low voltage line, and the low voltage connections are connected to a low voltage line. The functional modules each have a housing, an electronic circuit, and a module connection element connected to the electronic circuit. The module housing has a face with an opening. The module connection element comprises a first plug-in element extending through the opening, and adapted to engage the first connection elements of the base module.

An electronic device includes a window, a display module, a pressure sensor, and a bracket. The window includes a flat area and a curved area. The display module is disposed on a lower surface of the window to overlap with the flat area and the curved area. The pressure sensor is disposed on a lower surface of the display module to overlap with the curved area. The bracket is disposed on the lower surface of the display module and coupled to at least one of the window and the display module. The pressure sensor is disposed between the window and the bracket. The lower surface of the window and the lower surface of the display module face the same direction.

Embodiments include apparatuses, systems and methods for a computer device with a casing and a substance in the casing substantially surrounding a computer component in the casing. In embodiments, the computer device may be a command and control computer, such as for example, an autonomous or semi-autonomous vehicle. In embodiments, the substance may be an electrically isolative and shear-thickening fluid to provide thermo-mechanical protection to a computer component. In the described embodiments, the substance may dampen mechanical shock or vibrational impact on the processor and the memory. The shear-thickening gel may further be thermally conductive in embodiments. In the embodiments, the casing may be substantially filled with the substance and the substance is to conduct heat away from the processor and the memory toward an outer edge of the casing. Other embodiments may also be described and claimed.

An operating device for a bicycle is disclosed. The operating device includes a display ring and a coaxially arranged operating ring arranged to rotate relative to the display ring. The display ring includes a display for displaying information and a first magnetic element that cooperates with a second magnetic element arranged on or in the operating ring. In a first position of the operating ring relative to the display ring, the first magnetic element is proximate to the second magnetic element, and if the operating ring is rotated away from the first position, the first magnetic element and the second element magnetically cooperate to bias the operating ring back to the first position. The display ring further includes a sensor that receives a signal when in proximity of a signal providing element.

A power distribution panel with a backplane, an insulating panel covering the backplane, and at least one electronic component mounted to the insulating panel. A set of feet can be mounted to the insulating panel and configured to absorb stress applied to the insulating panel where the set of feet are located in the same plane as the backplane.

A wall mount system for mounting a plurality of monitors on a wall. The system has a plurality of wall mount assemblies, a plurality of monitor interfaces adapted to receive an electronic display respectively, and a depth adjustment feature operably coupling each monitor interface to one of the wall mount assemblies and enabling the monitors to be positioned and adjusted to account for recesses or raised portions of the wall and present a continuous, planar monitor display surface.