A frame structure for a cabinet enclosure has a front frame assembly having first and second front pillars, a rear frame assembly having first and second rear pillars, a first side brace member, and a second side brace member, each having a beam that has opposite ends, with the opposite ends of each side brace member connected to one of the front pillars and one of the rear pillars. The frame structure also includes cable management and air flow management features and functions.

Vibration shock mitigation for components in a server rack includes a server rack comprising: a first server component chassis and a second server component chassis installed in adjacent locations within the server rack; and a chassis gap filler comprising: an elastic dampening sheet configured for placement between the first server component chassis and the second server component chassis, wherein the elastic dampening sheet is further configured to cover a portion of one side of the first server component chassis; and at least two attachment points configured to secure the elastic dampening sheet to the server rack.

Disclosed is a prefabricating and stacking combined data center. The data center is formed block structures in a multi-dimensional stacking manner. The block structures are disposed to be a fire protection layer, an air return layer, a bridge architecture wiring layer, a top-cabinet wiring layer, a cabinet device layer, and an air supply layer from up to down, which are independent from each other. Provided is a prefabricating and stacking combined data center. Operation difficulty of site construction is greatly reduced by prefabricating block structures by a factory, forming the data center by multi-dimensional stacking, and connecting the block structures with each other by splicing on site. In addition, according to different requirements of customers, corresponding ancillary facilities may be designed based on volume of an IT device, and the device and a computer room may be reasonably and effectively arranged according to the corresponding national standards and specifications.

An apparatus may include a plastic frame; a plurality of mounting features coupled to the plastic frame such that the plastic frame is configured to maintain the plurality of mounting features in a desired orientation, wherein the plurality of mounting features, when in the desired orientation, are operable to receive and retain information handling systems; and a base coupled to the plastic frame and disposed below the plastic frame along a central vertical axis of the apparatus that is defined by the orientation of the plurality of mounting features.

A power system and method of operating the same. In one embodiment, the power system includes a plurality of power converters configured to power a host system. The power system also includes a power converter controller configured to provide a status of and control the plurality of power converters and at least one system element of the host system responsive to a plurality of host system signals. The control includes a scripted sequence of events as function of a change of an operational condition of at least one of the plurality of power converters and the host system.

A shock absorber apparatus is provided. The shock absorber apparatus includes an elastic device and at least one mounting device connected to the elastic device. Each mounting device includes two securing elements. Each securing element is configured to secure an opposing portion of a structure. Each mounting device can also include two sliders. Each slider can have at least two surfaces, which are interconnected by an inclined surface facing an opposing slider, and a ground surface. The inclined surface can be slidably connected to one of the at least two securing elements. Each slider can be arranged to move in response to an applied force. The ground surface is configured to slidably connect to an inner wall of a box.

A modular compute chassis, that includes a chassis divider wall assembly that includes a chassis grommet wall that includes a first side, a second side, and a hole; a grommet that includes a groove and at least partially disposed within the hole and mechanically coupled to the chassis grommet wall using the groove; and a first compute unit cage wall in contact with a first portion of the grommet, where the first portion of the grommet is interposed between the first compute unit cage wall and the first side; and a second compute unit cage wall in contact with a second portion of the grommet, where the second portion of the grommet is interposed between the second compute unit cage wall and the second side, where the second compute unit cage wall is rigidly mechanically coupled to the first compute unit cage wall.

Provided is a rack, comprising: a plurality of rack units; and a plurality of lockers each housing a different respective subset of the rack units, wherein respective lockers among the plurality comprise: a first respective barrier disposed between a respective pair of the rack units; a second respective barrier disposed between another respective pair of the rack units; a third respective barrier that is orthogonal to the first barrier and the second barrier, the third respective barrier being moveably or removeably coupled to the rack; a respective volume configured to receive one or more computing devices; and a respective lock configured to secure the third respective barrier to the rack in the closed position when in a locked state.

Described herein is an integration cell that can be preinstalled with plural electronic equipment units at a location remote from a datacenter. One or more preinstalled integration cells can be shipped on a single standard shipping palette to the datacenter location and moved into the data center through standard doorways and using standard elevators. Inside the datacenter, the integration cell can be inserted into a seismic electronic equipment storage rack to allow for bulk installation or removal of plural electronic equipment units.

A system according to one embodiment includes a pair of members for mounting to a computer rack in a parallel orientation relative to one another, at least two bezels configured for extending between the members and mounting to the members, and at least two locks for selectively locking the bezels to at least one of the members. A system according to another embodiment includes a frame for mounting to a computer rack. The frame includes members oriented in a rectangular configuration, at least two bezels configured for extending between opposite members of the frame, and at least two locks for selectively locking the bezels to at least one of the members. A system according to another embodiment includes a pair of members for mounting to a computer rack in a parallel orientation relative to one another, and an array of locks coupled to one of the members.