A hard disk drive enclosure base includes a non-uniform disk shroud surface extending from a top to a floor, the shroud surface including a first portion having a first radius and clearance along the circumference of the shroud surface and a second portion having a lesser second radius and clearance. The second portion of the shroud surface may be positioned at multiple locations where the drive form factor is especially constraining and in view of the need for a sufficient seal land surface for applying a gasket seal around the perimeter of the inner cavity of the base part. Widening the disk shroud clearance where possible can reduce the shear stress exerted at the disk edges thereby reducing the windage drag and associated disk spindle motor power consumption, especially in the context of helium-filled drives in which disk flutter is less of an issue.

A hard disk drive enclosure base includes a non-uniform disk shroud surface extending from a top to a floor, the shroud surface including a first portion having a first radius and clearance along the circumference of the shroud surface and a second portion having a lesser second radius and clearance. The second portion of the shroud surface may be positioned at multiple locations where the drive form factor is especially constraining and in view of the need for a sufficient seal land surface for applying a gasket seal around the perimeter of the inner cavity of the base part. Widening the disk shroud clearance where possible can reduce the shear stress exerted at the disk edges thereby reducing the windage drag and associated disk spindle motor power consumption, especially in the context of helium-filled drives in which disk flutter is less of an issue.

A disk device includes a magnetic disk, a magnetic head configured to read information from and write information to the magnetic disk, a housing having a mounting space in which the magnetic disk and the magnetic head are mounted, a substrate, and a sensor. The housing includes a wall and a hole extending therethrough to the mounting space. The substrate is attached to an outer side of the wall and sealing the hole. The sensor is mounted on the substrate.

A computer-implemented method is provided for cooling hard disk drives (HDDs). The method may include determining a threshold fan speed for one or more fans that provide cooling for HDDs based upon a target HDD vibration performance. The method may also include controlling the one or more fans, by a controller, to alternately run at a first fan speed for a first period and at the threshold fan speed for a second period, when the one or more fans reach the threshold fan speed. The first fan speed is higher than the threshold fan speed.

Provided is an optical disc drive that can implement a conveying roller position manipulation mechanism, a centering mechanism, and a chucking pulley operation mechanism, while allowing the number of components to be reduced. A base frame includes a spindle motor and an optical element. An inner case houses the base frame, and supports a conveying mechanism configured to convey an optical disc to the position of the spindle motor. An outer case houses the inner case. The base frame is fixed in the inner case via a first damper, and the inner case is fixed in the outer case via a second damper.

A disk drive suspension according to an embodiment comprises a load beam comprising a dimple, and a flexure overlaid on the load beam. The load beam and the flexure are fixed by a first fixing portion and a second fixing portion closer to a distal end of the load beam than the first fixing portion. The flexure comprises a tongue opposed to the dimple, and an outrigger connected to the tongue. The outrigger is bent in a thickness direction of the load beam at a bent portion located between the dimple and the first fixing portion in a length direction of the load beam.

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 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 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.

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.