The present disclosure provides a latch mechanism, applied to a rack-mount server system. The rack-mount server system includes a server and a manifold, and the server includes a casing and a fluid connector. The manifold includes a manifold connector. The latch mechanism includes a fixing member, a fixing frame and a hook member. The fixing member is disposed on the manifold and includes a fixing pin. The fixing frame is secured to the server and includes a shaft. The hook member is rotatably disposed on the shaft and includes a hook portion. By rotating the hook portion to latch with the fixing pin, the fixing frame and fixing member are secured with each other, and the fluid connector of the server is coupled to and in fluid communication with the manifold connector of the manifold.

A server rack assembly includes a pair of mounting units each including a panel, an adjustment plate, and rails. The panel has a first panel flange to connect a front support post. The adjustment plate is movably connected to the panel for connecting a rear support post and is adjustable to suit varying distances between front and rear support posts. The rails are detachably mounted on the panel; a gap between two rails is adjustable to accommodate different server devices.

Support bracket and support bracket assemblies for a peripheral component interconnect (PCI) card are shown and disclosed. In one embodiment, the support bracket includes a first planar member having opposed first and second end portions, and a second planar member attached to, or formed with, the second end portion. The second planar member is perpendicular to the first planar member and is attachable to an I/O PCI bracket. The support bracket additionally includes a ledge attached to, or formed with, the first planar member. The ledge extends between the first and second end portions and is perpendicular to the first and second planar members. The ledge is sized to support an end portion of the PCI card when the PCI card is attached to the I/O PCI bracket and when the second planar member is attached to the I/O PCI bracket.

A peripheral device includes one or more processors and a memory storing program instructions that when executed implement virtualization offloading components of a virtualized computing service, including a storage manager. The offloading components establish network connectivity with a control plane of the service. Based on detecting that a hardware server, in a separate enclosure, has been linked to the peripheral device, the hardware server is presented as a virtualization host of the service. The offloading components initiate compute instance configuration operations at the server in response to commands issued to the control plane, including at least one configuration operation initiated by the storage manager to enable access to a logical storage device from a compute instance.

A rack adapting device for an electronic equipment rack is disclosed. The electronic equipment rack is configured to house first electronic equipment modules having a first module width between left and right equipment supports laterally spaced apart from one another by a rack housing width corresponding to the first module width. The rack adapting device is configured to adapt the electronic equipment rack to house a plurality of second electronic equipment modules having a second module width and comprises: an adapter body; a plurality of rack-engaging features disposed on a first lateral side thereof and configured to engage rack mounting features of one of the left and right equipment supports; and a plurality of adapter mounting features disposed on a second lateral side such that, in use, the second electronic equipment modules are mounted between the rack adapting device and an other one of the left and right equipment supports.

A tray assembly is detachably disposed on a casing and includes a tray body, at least one gear set, a handle, and at least one side cover. The tray body is adapted to be accommodated in the casing. The least one gear set is disposed at a side of the tray body. The at least one gear set has a first engagement portion configured to be engaged with the casing. The handle is rotatably connected to the tray body via the at least one gear set. The at least one side cover is fixed to the tray body and covers the at least one gear set.

A server chassis includes a housing, a support frame, and a back plate. The housing includes a substrate. A fixing portion is vertically disposed on the substrate and is fixedly connected with the back plate. The support frame is fixedly connected with the substrate. A first protrusion is disposed on the support frame and is inserted into the back plate. The interior of the server chassis is rendered more compact, and the server chassis can accommodate eight hard disks. A server including the server chassis is also disclosed.

The present disclosure relates to a compact keyboard, monitor, and mouse (KMM) system for use in an equipment rack. The system includes a tray subsystem including a pair of drawer slides configured to mate with the equipment rack, each drawer slide having a bottom plane parallel to the ground when installed in the equipment rack. The system further includes a console housing supported by the tray subsystem. The console housing has a top surface that defines recesses for a keyboard and a monitor. The system also includes a keyboard. When secured in the keyboard recess, the keyboard is positioned parallel to the bottom plane of the tray subsystem. When positioned in the monitor recess, the monitor is canted at an angle relative to the bottom plane of the tray subsystem. The angle is selected to minimize the overall height of the KMM system while maximizing user ergonomics.

A server chassis includes at least one first tray, at least one second tray, a housing, a first interface, the housing includes a bottom wall and a side wall, the bottom wall and the side wall surrounds and forms a receiving cavity with an opening. The first interface is located in the receiving cavity; the first interface is placed at a corner of the bottom wall close to the opening and the side wall. The first tray and the second tray are stacked in the receiving cavity, and the first tray is located below the second tray. The first tray slides out or retracts the receiving cavity through the opening. The second tray slides out or retracts the receiving cavity through the opening; the first tray and the second tray are configured to carry hard disks of a plurality of arrays. The present disclosure also provides a server.

A chassis for a computing device includes a base component and a top cover. The base component includes guide slots therein. The top cover includes stamped protrusions extending from one or more side slider structures. The slider structurers extend downwardly from a top surface of the top cover. The stamped protrusions are unitary one-piece structures with the one or more side slider structures. The stamped protrusions correspond to respective guide slots of the base component such that the stamped protrusions are positioned in corresponding guide slots when the base component and the top cover are in a mating position.