A drive carrier for a device of an information handling system includes first and second portions. The first and second portions are placed in physical communication with the device. The first portion includes first and second side rails to secure the device within the drive carrier. The first and second side rails slide within a first slot of a bay of the information handling system. The second portion is located on top of the first portion and floats away from and toward the first portion when the drive carrier is inserted with the bay of the information handling system. An amount of float for the second portion is based on a bay pitch of the bay.

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 drive carrier for a device of an information handling system includes first and second portions. The first and second portions are placed in physical communication with the device. The first portion includes first and second side rails to secure the device within the drive carrier. The first and second side rails slide within a first slot of a bay of the information handling system. The second portion is located on top of the first portion and floats away from and toward the first portion when the drive carrier is inserted with the bay of the information handling system. An amount of float for the second portion is based on a bay pitch of the bay.

A storage device includes a hard disk backplane, a first cascading board, and a hard disk array. The hard disk array includes a plurality of hard disks, and is located on a first side of the hard disk backplane. The first cascading board is a field-replaceable unit FRU, and is located on a second side of the hard disk backplane.

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 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.

A data storage array has a backplane at the base of an enclosure. A plurality of data storage drives are coupled to connectors of the backplane. A hot-swappable protocol expander module is coupled between the drives and the backplane through a top of the enclosure or to the backplane through a side of the enclosure.

A data storage chassis includes a plurality of data storage cartridges, and printed circuit board assembly (PCBA) electronics selectively connectable to one or more of the plurality of data storage cartridges. The data storage chassis also includes a wireless interface controller communicatively coupled to the PCBA electronics. The wireless interface controller facilitates wireless communication of data between the data storage chassis and a host using at least one frequency in a range of frequencies including fifth-generation (5G), millimeter, and sub-millimeter frequency ranges.

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.

Implementations of the subject matter described herein provide an input/output (I/O) card for storage device and a storage device. The I/O card and the disk drive for the storage device have the same form factor and comply with the same protocol, to enable the I/O card and the disk drive can be arranged at the same end of the storage device.