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.

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.

An approach for assembling a hard drive to a hard drive carrier is provided. The approach includes an ergonomic tool to aid with assembly. The ergonomic tool allows for a reduction in assembly time and prevents damage to the components. The ergonomic tool comprising of a base having a first surface and a first end open for receiving the components. The tool has a set of walls rising from the base, a first wall rising from the base proximate a second end opposite the first end and a pair of opposing side walls including voids rising from the first surface between the first end and the second end, to form a slot there between to receive the components within and adjacent the first surface. The tool has a releasable hold mechanism that aligns the components during assembly.

An information handling system may include a processor and a storage subsystem. The storage subsystem may include a non-expander backplane, a first plurality of storage resources coupled to the processor via the non-expander backplane, and a second plurality of storage resources coupled to the processor via a communication path that does not include the non-expander backplane. The information handling system may be configured to provide slot numbers for the storage resources according to a numbering scheme in which a storage resource from the first plurality of storage resources and a storage resource from the second plurality of storage resources have the same slot number.

A fixing bracket is used to fix a plurality of storage devices in a housing. Each of the storage devices has a first sidewall and a second sidewall opposite and respectively having plurality of fixing holes. The fixing bracket includes a frame body and two pivotal members. The frame body has an opening and an accommodating space. The frame body includes a plurality of first fixing pins in the accommodating space. The storage devices can be accommodated in the accommodating space. Each of the first fixing pins is for being inserted into the corresponding fixing hole on the first sidewall. The pivotal members are pivotally connected to the frame body. Each of the pivotal members includes a plurality of second fixing pins. When the pivotal members cover parts of the opening, each of the second fixing pins is for being inserted into the corresponding fixing hole on the second sidewall.

A storage drive configured for use in a storage drive block and a storage drive block are provided. The storage drive block in one example includes a plurality of storage drives joined together into a substantially rigid storage drive block, a block communication element extending to the plurality of storage drives and adapted to communicatively link a plurality of communication boards of the plurality of storage drives to a mass storage chassis assembly, and one or more joining elements affixing the one or more mounting elements of each storage drive to form the storage drive block.

A method of controlling a computing device includes detecting a user input request to disengage a drive component from a computing device, the computing device comprising a multiple-drive storage system having a plurality of drive components forming a single logical unit, and determining whether or not disengaging the drive component would cause failure of the multiple-drive storage system. The method includes disallowing disengagement of the drive component from the computing device in response to determining that disengaging the drive component would cause failure of the multiple-drive storage system, and allowing disengagement of the drive component from the computing device in response to determining that disengaging the drive component would not cause failure of the multiple-drive storage system.

A chassis structure includes a chassis body and at least one holder module. The at least one holder module includes a frame, a handle, and a guiding assembly. The frame is detachably disposed in the chassis body and has a first linking portion. The handle has a holding portion, a second linking portion, and a third linking portion pivoted to the frame. The guiding assembly is disposed on the chassis body and has a first guiding slot, a second guiding slot, and a third guiding slot. The first guiding slot has a first segment, and the second guiding slot has a second segment and a third segment curvedly connected to each other. The first linking portion, the second linking portion, and the third linking portion are adapted to respectively move along the first segment, the third segment, and the third guiding slot simultaneously such that the frame moves upwards and rotates from a first position to a second position simultaneously.

A storage canister is provided. The storage canister in one example includes an enclosure, multiple Hard Disk Drives (HDDs) located within the enclosure, a plurality of mounting elements configured to receive the multiple HDDs, wherein each mounting element of the plurality of mounting elements is configured to receive a HDD, a plurality of suspension elements supporting the plurality of mounting elements, with each suspension element of the plurality of suspension elements supporting and providing vibration isolation to a corresponding HDD of the multiple HDDs, and an external connector configured to be externally accessible, with the external connector being electrically coupled to the plurality of mounting elements.