Embodiments of the invention provide a system and method for housing electrical components of a high-density liquid cooling unit to liquid cool electrical components. The system includes a first electrical cabinet housing at least one electrical switch and a controller. The first electrical cabinet is swingable outward to open, and the first electrical cabinet opens while the high density liquid cooling system continues to operate to liquid cool electrical components. The system includes a second electrical cabinet housing a first motor drive and a second motor drive. The second electrical cabinet is accessible when the first electrical cabinet swings outward. One of the first motor drive and the second motor drive are replaceable while the high density liquid cooling unit continues to operate.

A cable manager includes a backbone assembly and at least one side wall extending from the backbone assembly. The at least one side wall optionally includes one or more cable finger units. The backbone assembly includes a spine member having an extruded construction. The spine member includes one or more channels extending substantially an entire length thereof to facilitate easy attachment, removal and/or repositioning of a structure relative to the spine member. The cable manager optionally includes an accessory rod, a half-spool assembly, a cable finger accessory, a strap/buckle accessory, and/or a door assembly having an interference-free hinge set.

A data center cabinet has a base frame with a pair of front vertical posts, first bottom and top side-to-side beams connected to the front vertical posts, a pair of back vertical posts, second bottom and top side-to-side beams connected to the back vertical posts, and front-to-back beams connecting the front vertical posts and back vertical posts. The first and second bottom side-to-side beams each comprise an opening configured to allow a removable transport caster to pass through the opening, a first set of keyholes configured to receive and retain a set of mounting buttons of a first removable transport caster, and a second set of keyholes configured to receive and retain a set of mounting buttons of a second removable transport caster.

A server includes a chassis; a base panel fixedly coupled to the chassis; a movable panel coupled to the base panel; and a locking member fixedly coupled to the movable panel. The movable panel is movable relative to the base panel in a moving direction between an unlocked position where the locking member is configured to be disengaged with a locking panel of an electronic rack, and a locked position where the locking member is configured to be engaged with the locking panel of the electronic rack.

The disclosure provides a data center with high density server racks that are solely air cooled. A data center comprises a processor to use one or more computational fluid dynamics (CFD) models to indicate a placement of one or more servers within one or more server racks to substantially maintain a temperature within the one or more server racks during operation without using additional cooling sources.

Described herein is a first system that includes sleds each having sidewalls, a mounting plate, and a first cover. The first cover is movable relative to the sidewalls between a closed position and an open position. The first cover includes at least one first opening. The system additionally includes at least one data storage device fixed to each mounting plate. A first air gap is defined between the at least one data storage device and the mounting plate, and a second air gap is defined between the at least one data storage device and the at least one first opening of the first cover. The sleds are stacked together such that the first covers of adjacent sleds are directly adjacent each other, and the at least one first opening of the first cover of one sled at least partially overlaps the at least one first opening of an adjacent sled.

A data center cabinet has a base frame with a pair of front vertical posts, first bottom and top side-to-side beams connected to the front vertical posts, a pair of back vertical posts, second bottom and top side-to-side beams connected to the back vertical posts, and front-to-back beams connecting the front vertical posts and back vertical posts. The first and second bottom side-to-side beams each comprise an opening configured to allow a removable transport caster to pass through the opening, a first set of keyholes configured to receive and retain a set of mounting buttons of a first removable transport caster, and a second set of keyholes configured to receive and retain a set of mounting buttons of a second removable transport caster.

Example implementations relate to an adaptive cooling assembly. For example, an adaptive cooling assembly includes a removable shelf installed in the adaptive cooling assembly, an adaptive cooling bay located in a slot formed by the removable shelf, and a removable thermal bus bar installed in the adaptive cooling bay and connected to a pair of connectors. The adaptive cooling bay includes the pair of connectors and the removable thermal bus bar provides liquid cooling to an electronic device.

A chassis structure is provided and includes a main body, a lateral plate and a restraining mechanism. The lateral plate is detachably installed on the main body. The restraining mechanism is disposed between the main body and the lateral plate. The restraining mechanism includes a first restraining component and a second restraining component. The first restraining component is disposed on one of the main body and the lateral plate. The second restraining component is disposed on another one of the main body and the lateral plate. The first restraining component is configured to abut against the second restraining component to restrain a pivotal angle of the lateral plate relative to the main body for positioning the lateral plate at a supporting position relative to the main body, so as to prevent the lateral plate from falling off. Besides, an electronic device having the aforementioned chassis structure is provided.

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.