An equipment assembly for cooling heat-generating electrical components is disclosed. The assembly includes a housing for containing a heat-generating electrical component. The housing includes an open end having a planar area. A closed-loop liquid cooling system includes a liquid coolant conduit in proximity to the heat-generating electrical component. The conduit allows circulation of a liquid coolant to extract heat from the heat-generating electrical component. A heat exchanger is fluidly coupled to the liquid coolant conduit to extract heat from circulated liquid coolant within the heat exchanger. The heat exchanger includes a shaped front facing the open end of the housing. The surface area of the shaped front is greater than the planar area of the open end. An air flow system propels ambient air through the shaped front of the heat exchanger.

A node sled is for installation into an electronics chassis. The node sled includes a housing that contains electronic components. The housing includes a front bracket and a catch mechanism. The node sled further includes a lever having an engagement arm, an actuation arm, and a mounting portion. The mounting portion is pivotably mounted to the housing. The actuation arm is manually moveable between a first position in which the engagement arm locks the node sled into the electronics chassis, and a second position in which the engagement arm is released from the electronics chassis. The actuation arm has a latch that engages the catch mechanism in response to the actuation arm being in the first position.

Several transportable datacenters are described. The transportable datacenters include transport systems allowing them to be transported between an assembly location and an operating location. The transportable datacenters also include a ventilation system for cooling processors positioned in racks in the datacenters. The ventilation system draws cold air from the environment, through processor bays containing the processors and then exhausts the air back to the environment.

A plenum for processing one or more byproducts output from a generator, and systems and methods thereof, can have the plenum in the form of a hollow elongate rectangular box having a first end and a second end opposite the first end. The plenum can have a frame and a sidewall fixed to the frame, and can be adapted to be oriented vertically when operatively coupled to receive the one or more byproducts from the generator. The sidewall can include an opening adapted to receive heated air from the generator as one of the byproducts from the generator.

A method for converting a computing device from a first configuration to a second configuration is provided. A power supply unit of the computing device is moved from a first location at a second end of the computing device to a second location at a first end of the computing device. The power supply unit is rotated such that a power interface of the power supply unit is visible from the first end of the computing device. A set of fans of the computing device is rotated such that airflow direction of the set of fans matches an airflow direction of the power supply unit at the second location. Converting the computing device from the first configuration to the second configuration can allow communication ports to be accessed from a front end or from a rear end of the computing device.

A data center cooling system, including a support structure having a lower portion and an upper portion, one or more fans supported by the support structure at a height that is equal to or greater than a height of the electronics cabinets, and a heat exchanger having one or more cooling coils supported at the upper portion of the support structure. In some embodiments, the cooling coils can be supported by the upper portion of the support structure so as to be above the top of and/or over one or more of the electronics cabinets. The fans can be configured to draw air from the one or two rows of electronics cabinets and to cause the air to be passed through the heat exchanger to cool the warmer air from the electronics cabinets.

An information handling system includes an enclosure having a front portion and a rear portion. An exhaust duct is located in between a first central processing unit and a first set of downstream components within the rear portion. The exhaust duct directs first airflow from the first central processing unit out of the information handling system without the first airflow reaching an inlet of the first set of downstream components. A first top cover is attached to the rear portion. The first top cover includes a first hole cut above the exhaust duct. The first hole enables the first airflow to escape from the rear portion.

A system includes at least one storage tank configured to store at least one of first compressed air or liquid air. The system also includes a power supply system comprising a turbine, a generator, and a flywheel. The power supply system is configured to receive second compressed air from the at least one storage tank, wherein the second compressed air comprises either the first compressed air or the liquid air which has been heated into a gaseous state; spin the turbine and the flywheel using the second compressed air, wherein the spinning of the turbine generates electrical energy at the generator; provide the electrical energy to a data center for powering electronic devices of the data center; and provide at least a portion of the second compressed air exhausted by the turbine to the data center for cooling the electronic devices of the data center.

This disclosure describes systems for arranging racks within a data center for a smaller and/or more flexible footprint, more efficient and/or resilient cooling, and/or easier installation. In some examples, this disclosure describes a data center rack system that includes an aisle and a plurality of rack stations adjacent to the aisle. The aisle includes an aisle guidance track defining an aisle axis. Each rack station of the plurality of rack stations includes a station guidance track defining a station axis. The station guidance track is configured to receive a rack from the aisle guidance track and position the rack in the respective rack station at a rack angle formed between the aisle axis and the station axis that is less than 90 degrees.

A rack and system for cooling computing devices such as in a data center is disclosed. In one embodiment, the rack supports a plurality of computing devices and comprises a plurality of planar annular sector or trapezoidal shelves, each having one or more positions for holding computing devices. A number of vertical supports may hold the shelves in a vertically spaced arrangement, and an air barrier may be affixed to the rack. The air barrier may have openings for the computing devices to permit exhaust air to flow through the air barrier into a hot aisle. The rack maybe configured to be connected to other similar racks to form a vertical annular hyperboloid or a vertical hyperbolic annular paraboloid, and the computing devices may be installed to discharge exhaust at an angle relative to a centerline of the vertical annular hyperboloid or a vertical hyperbolic annular paraboloid to improve airflow.