An electronic control unit having a sealed housing including a main body and a cover fixed to one another and a sealing element in contact with one and/or the other of the main body and the cover. The control unit also includes a circuit board arrangement in the housing which a circuit board is located. In addition, the control unit also includes at least one housing stabilizing element in contact with the circuit board arrangement and one or the other of the main body and the cover.

A liquid-submersible thermal management system includes a cylindrical outer shell and an inner shell positioned in an interior volume of the outer shell. The cylindrical outer shell has a longitudinal axis oriented vertically relative to a direction of gravity, and the inner shell defines an immersion chamber. The liquid-submersible thermal management system a spine positioned inside the immersion chamber and oriented at least partially in a direction of the longitudinal axis with a heat-generating component located in the immersion chamber. A working fluid is positioned in the immersion chamber and at least partially surrounding the heat-generating component. The working fluid receives heat from the heat-generating component.

An electronic device maintains a pressure adjustment function of a breathable filter. The electronic device includes a connector that includes a connector housing that closes an opening portion of a housing accommodating a circuit board and holds a connection terminal enabling electric connection of the circuit board to an external connector and a communication hole that penetrates the connector housing and allows an internal space and an external space of the housing to communicate with each other, and a filter attached to the connector housing to cover a first opening that opens in the communication hole on an internal space side of the housing. The connector housing has a shielding wall surrounding the periphery of the second opening of the communication hole that opens to the external space side of the housing and protrudes toward the external space side of the housing from the second opening of the communication hole.

The present invention provides an in-vehicle electronic control device which further improves heat dissipation by forming a protrusion extending toward an electronic component on an inner surface of a cover portion formed of a highly thermally conductive resin in consideration of orientation of a filling material contained in the highly thermally conductive resin. An in-vehicle electronic control device of the present invention includes: a circuit board on which an electronic component is mounted; a base portion in which the circuit board is installed; and a cover portion with which the circuit board is covered together with the base portion, which is formed of a resin containing a filling material, and which has a protrusion protruding toward the electronic component, in which the protrusion is formed of a resin containing a filling material and a width of the protrusion is smaller than a width of the electronic component.

An electronic control device 1 includes: a circuit board 4 having a first surface 4A on which heat-generating components 21, 22, 23 and heat-degradable components 31, 32 are mounted; a first metallic case 2 covering the first surface 4A; a second case 3 covering a second surface 4B of the circuit board 4 opposite to the first surface 4A; supporting members 51, 52 provided between the heat-degradable components 31, 32 and the first case 2 to support the heat-degradable components 31, 32; and heat-dissipating members 41, 42, 43, each provided on at least any of the heat-generating components 21, 22, 23, and the first case 2, to transmit heat generated from the heat-generating component 21, 22, or 23, to the first case 2. A heat conductivity of the heat-dissipating members 41, 42, 43 is higher than a heat conductivity of the supporting members 51, 52.

A cassette system includes a base assembly and a cassette assembly configured to secure one or more batteries. The cassette assembly includes a battery case and a first electrical connector configured to couple to the one or more batteries. The base assembly is configured to include a wireless communication deice configured to control actuation of one or more sprinkler valves and a second electrical connector configured to electrically couple to the wireless communication device. The first electrical connector and the second electrical connector are configured to electrically couple responsive to the cassette assembly being removably attached to the base assembly.

Provided is a power conversion device, including: a casing that has a front surface with an opening; an insertion component including an insertion portion; and a gasket. The casing has an inner wall surface being in contact with the gasket and a casing-side guide surface. The insertion portion has an outer peripheral surface being in contact with the gasket and an insertion component-side guide surface. When a distance in the insertion direction between the front surface and an end of the casing-side guide surface, which is closer to the front surface in the insertion direction, is represented by L1 and a distance between an inner surface of the gasket in the insertion direction and a distal end of the insertion component-side guide surface in the insertion direction is represented by L2, the distance L2 is set larger than the distance L1.

A liquid-submersible thermal management system includes a cylindrical outer shell and an inner shell positioned in an interior volume of the outer shell. The cylindrical outer shell has a longitudinal axis oriented vertically relative to a direction of gravity, and the inner shell defines an immersion chamber. The liquid-submersible thermal management system a spine positioned inside the immersion chamber and oriented at least partially in a direction of the longitudinal axis with a heat-generating component located in the immersion chamber. A working fluid is positioned in the immersion chamber and at least partially surrounding the heat-generating component. The working fluid receives heat from the heat-generating component.

A potted electronic module includes an electronic assembly with a conductor such as a shunt that is arranged in a housing, and includes an electrical contact guided out through the housing wall, and a potting compound within the housing. The module may be produced by removing a protective layer from an area of the conductor by ablation, and then introducing a potting or casting compound into the housing, so that the potting compound covers a location at which the electrical contact passes through the housing wall, and the potting compound adheres directly onto the exposed conductor at the area at which the protective layer was removed.

A liquid-submersible thermal management system includes a cylindrical outer shell and an inner shell positioned in an interior volume of the outer shell. The cylindrical outer shell has a longitudinal axis oriented vertically relative to a direction of gravity, and the inner shell defines an immersion chamber. The liquid-submersible thermal management system a spine positioned inside the immersion chamber and oriented at least partially in a direction of the longitudinal axis with a heat-generating component located in the immersion chamber. A working fluid is positioned in the immersion chamber and at least partially surrounding the heat-generating component. The working fluid receives heat from the heat-generating component.