An equipment shelf includes at least one power supply unit (PSU) positioned in an upper region of the equipment shelf. The equipment shelf also includes at least one battery backup unit (BBU) positioned in a lower region of the equipment shelf. An airflow path extends through the equipment shelf between the upper region and the lower region. The airflow path separates the upper region of the equipment shelf from the lower region of the equipment shelf and thermally isolates the at least one PSU in the upper region from the at least one BBU in the lower region when air flows through the airflow path. Other example equipment shelves are also disclosed.

A cooling assembly includes an air mover and a vent panel coupled to the air mover. The vent panel includes an inlet. The cooling assembly includes a vane that is rotatable around a central vertical axis of the vane between an open position and a closed position to open and close the inlet.

A system for determining and displaying in a graphical user interface one or more of air temperature, pressure, or velocity in an information technology (IT) room including an IT equipment rack comprises a processor configured to receive an input comprising airflow resistance parameters through the rack, an IT equipment airflow parameter, a heat-dissipation parameter, an external pressure, and an external temperature, to run the input through a flow-network solver that solves for airflow velocities through at least one face of the rack and a rack air outflow temperature based on the input, provide an output including the airflow velocities and the rack air outflow temperature, and generate, based on the output, a display in a graphical user interface of the system illustrating one or more of air temperatures, air pressures, or airflow velocities within the IT room.

Systems and methods. The methods comprise: causing bellows to transition from expanded states to collapsed states by removing a first fluid therefrom (the bellows being coupled to opposing sidewalls of a chassis configured to structurally support at least one circuit card); receiving the at least one circuit card in a cavity of the chassis; causing the bellows to transition from the collapsed states to at least partially expanded states by allowing the first fluid to enter the bellows; applying a pushing force by each said bellow to an intermediary structure disposed between the bellow and the circuit card; and creating a seal between the intermediary structure and the circuit card when the bellow is in the at least partially expanded state.

A robot control apparatus controlling a robot includes a control board for controlling operation of the robot, a housing including a plurality of plate materials containing a first plate material and a second plate material and housing the control board in a space surrounded by the plurality of plate materials, an intake port for taking air into the housing, an exhaust port for exhausting the air within the housing to outside, and a cable coupling portion coupling a cable for communication with the robot, wherein the intake port, the exhaust port, and the cable coupling portion are provided in the first plate material, and the second plate material includes an installation surface facing an object on which the housing is installed.

An electric distribution module includes a plate bearing a main partition and lateral partitions that jointly delimit a plurality of housings, wherein the main partition has at least one channel, and wherein each lateral partition comprises at least one channel that is terminated by an opening leading into a housing that this lateral partition delimits and that communicates with a channel of the main partition, so to as to ensure, via these channels, independent ventilation of each housing and/or the routing and holding of control cables towards each housing.

Apparatus cools electronic circuitry. An enclosure surrounds the circuitry. Air intake holes are only in a portion of a first panel that faces a first direction. Air exhaust holes are only in a portion of a second panel that faces a second direction opposite the first. Air plenum piece is disposed within the enclosure, and a substantially planar portion extends from a first panel inner wall and ends a distance from a second panel inner wall. At least one tab extends from the substantially planar portion to an upper panel inner wall. The air plenum piece divides an enclosure interior into a first volume, enclosed by the first panel inner wall, substantially planar portion, at least one tab, and upper panel inner wall, into which the air intake holes open and a second volume into which the air exhaust holes open. The second volume is a remaining interior volume.

The present disclosure relates to an IED configured for use as a protection relay in an electric power system. The IED comprises a plurality of cassettes connected to a backplane, with at least two cassettes mounted adjacent each other. Each of the cassettes comprises a housing profile in the form of a rectangular tube having an envelope wall of a heat conducting material, and at least one electronic card arranged in a card slot within the tube formed by the housing profile, which at least one card is electrically connected to the backplane. Adjacent cassettes are separated a distance such that air canals are formed between their respective housing profiles.

In one embodiment, an apparatus includes a chassis base, a printed circuit board mounted on the chassis base, a heatsink positioned over the printed circuit board to prevent corrosion of components on the printed circuit board, wherein the heatsink comprises a plurality of upward extending fins and a plurality of downward extending walls, a seal interposed between an edge of the downward extending walls and the chassis base, and a cover extending over the heatsink.

An apparatus cools electronic circuitry. An enclosure surrounds the electronic circuitry and has plural surfaces. Air intake holes are disposed in at least one surface and face at least one first direction. Air exhaust holes are disposed in at least another surface and face at least one second direction different than the first direction. A heat sink is in thermal contact with the circuitry and conducts heat generated by the circuitry. When a fan operates, air is drawn from an exterior of the enclosure through the air intake holes, absorbs heat from the heat sink, and then is directed through the air exhaust holes into the exterior of the enclosure. The heat sink is further in thermal contact with the enclosure so that when the fan does not operate, heat is drawn from the circuitry to the enclosure via the heat sink and is dissipated from the exterior.