A chassis node coupling system includes a chassis node configured to be received at a first end of a chassis assembly, wherein the chassis node size exceeds the chassis assembly size. A latch assembly with one or more coupling assemblies may be configured to releasably couple the chassis node to the chassis assembly.

A bladed chassis system facilitates installation of the bladed chassis system and replacement of the blades at the chassis. Blades can be inserted and removed from the front and/or the rear of the bladed chassis system at the discretion of the user. Blades can be moved between discrete positions. In examples, blades can be one-handedly released from the chassis to allow movement between discrete positions. In examples, accidental movement past a discrete position is inhibited. Accidental removal of the blades from the chassis is inhibited. The chassis and blades cooperate to manage the optical fiber cables routed through a cable port in the chassis to the blades.

A computer system including a frame, components and a pair of stacked controllers. The system also includes a plurality of midplanes positioned between the components and the controllers where each midplane includes a component edge and a controller edge, a first midplane connector coupled to the component edge and a second midplane connector coupled to the controller edge, where the first midplane connector is coupled to one of the component connectors and the second midplane connector is coupled to one of the controller connectors so that the midplanes are vertically oriented in parallel so as to define spaces therebetween. In one embodiment, the computer system is a data storage system, the components are storage drives and the controllers are storage controllers.

A partition for separating computer components in an apparatus holding the computer components is provided. The partition includes a body with a first side and a second side; one or more top tabs projecting from both the first side and the second side of the body; one or more bottom tabs projecting from the first side of the body; and one or more bottom protrusions projecting from the second side of the body. The one or more top tabs are secured in a first manner, e.g., through rivets, to a first panel of the apparatus. The one or more bottom tabs are secured in the first manner to a second panel of the apparatus. The one or more bottom protrusions are secured in a second manner to the second panel of the apparatus, e.g., tucking a protrusion under the second panel. The features allow different-sized compartments for different storage form factors.

A controller and a rectangular parallelepiped power supply apparatus are coupled to a rear surface of a midplane, to which a plurality of storage media drives are coupled in a front surface of the midplane. A plurality of interface connectors arranged in a left-right direction are provided at a front end of a controller substrate. The rear surface of the midplane includes a plurality of connectors for controller, which are a plurality of connectors arranged in the left-right direction to which interface connectors of the controller are respectively coupled, and a connector for power supply, which are connectors to which a power supply apparatus set horizontally is coupled. A part of a row of the connectors for controller is present below the power supply apparatus coupled sideways to the connector for power supply.

A server and a chassis of the server are disclosed. The server chassis includes a casing and a fan tray. The casing has a front side and an opposing rear side. The fan tray is disposed on the front or rear side of the casing in a flippable manner. This design allows the chassis to be applicable to different types of servers, resulting in reduced research, development and manufacturing cost of the server and chassis.

The present application provides a tool-free PCIE fixing apparatus, including: a Riser module bracket; a plurality of PCIE card connectors, each configured to fix a PCIE card; a die casting, in an upright state and fixed at one side of the Riser module bracket along a width direction thereof; and a pressing fixation plate, being in an upright state and pivoted at one side of the Riser module bracket along the width direction thereof Δn inner side of the pressing fixation plate is provided with locking pieces. The die casting defines therein locking holes configured to form elastic snap-fitting connection with the locking pieces, respectively. Each of the plurality of PCIE card connectors defines therein a locking slot configured to allow one of the locking pieces to pass through.

An electronic device includes a housing that includes a bottom plate and a standing wall erected over the bottom plate, and a conversion mechanism that includes a first coupler coupled to the standing wall and a second coupler by which the first coupler is coupled to the bottom plate, and configured to convert a tensile force to act on the first coupler toward a side of the standing wall into a pulling force to act on the bottom plate from the second coupler.

A device includes an interposer card that includes a processor, such as a system on a chip (SoC), and memory devices. The interposer card mounts to a mass storage device and has a shape that corresponds to a size of an end of the mass storage device to which the interposer card is mounted. The SoC of the interposer card is configured to implement an individual server for the mass storage device to which the interposer card is mounted. In some embodiments, a data storage system includes multiple mass storage devices mounted in a chassis and coupled to one or more backplanes, wherein interposer cards are connected between the mass storage devices and the one or more backplanes.

Technologies for composing a managed node with multiple processors on multiple compute sleds to cooperatively execute a workload include a memory, one or more processors connected to the memory, and an accelerator. The accelerator further includes a coherence logic unit that is configured to receive a node configuration request to execute a workload. The node configuration request identifies the compute sled and a second compute sled to be included in a managed node. The coherence logic unit is further configured to modify a portion of local working data associated with the workload on the compute sled in the memory with the one or more processors of the compute sled, determine coherence data indicative of the modification made by the one or more processors of the compute sled to the local working data in the memory, and send the coherence data to the second compute sled of the managed node.