According to one embodiment, a disk device includes a recording medium of a disk form, a magnetic head, a housing, and a first protective member made of a resin. The recording medium includes a recording layer. The magnetic head is configured to read/write information from/to the recording medium. The housing includes a base provided with an inner chamber in which the recording medium and the magnetic head are accommodated, a cover that covers the inner chamber, and a welded part at which the base and the cover are welded to each other. The first protective member is located outside the housing, to cover at least part of the welded part.

According to one embodiment, a disk device includes a recording medium of a disk form, a magnetic head, a housing, and a first protective member made of a resin. The recording medium includes a recording layer. The magnetic head is configured to read/write information from/to the recording medium. The housing includes a base provided with an inner chamber in which the recording medium and the magnetic head are accommodated, a cover that covers the inner chamber, and a welded part at which the base and the cover are welded to each other. The first protective member is located outside the housing, to cover at least part of the welded part.

A storage enclosure includes a plurality of hard drive sub-boards, each configured to include a plurality of hard drives. A local logic device manages each hard drive sub-board. A master logic device manages the local logic devices. The master logic device receives management commands from a host computer system coupled to the storage enclosure, and routes those commands to specific local logic devices. The local logic devices then relay the commands to specifically targeted hard drives. Thus, each hard drive within the storage enclosure can be independently controlled, allowing a single hard drive to be powered down without powering down other hard drives in the enclosure.

A system includes a support frame residing within a region conforming to a 3.5-inch form-factor disk drive specification, and a plurality of data storage drives, wherein each data storage drive resides entirely within the region. Each data storage drive conforms to a 2.5-inch form-factor disk drive specification, is mounted on the support frame via at least one external mounting hole that is positioned on a surface of the data storage drive in conformance with the 2.5-inch form-factor disk drive specification, is communicatively coupled to a backplane via an electrical connection device, and the electrical connection device includes a flexible electrical connector that, when coupled to a first end of the data storage drive, does not extend beyond the region, and has a removal tab through which a removal force is exerted to urge the data storage drive away from the support frame.

A server capable of rotating and accessing storage devices accommodated therein includes a server chassis, a motherboard, a power supply module, two racks, and a system cooling module. The server chassis includes two side plates and an accommodating space between the two side plates. The power supply module is disposed in the accommodating space and arranged corresponding to the motherboard. The racks are arranged parallel to each other and detachably connected to the server chassis. A pivot structure and a handle for operating the rack are disposed at the rack near the motherboard. The rack is rotatable with respect to the server chassis by means of the pivot structure. The system cooling module is disposed adjacent to the rack. At least one cord passage is provided between the system cooling module and each of the side plates.

Disclosed herein are printed circuit boards (PCBs) with patterned ground structure filters and data storage devices comprising such PCBs. Each PCB comprises a resonator having an L-shape or a zig-zag shape in a plane of the printed circuit board and at least one signal trace. The resonator has a first dimension and a second dimension in the plane of the printed circuit board. A portion of the at least one signal trace is situated over the resonator and is separated by a distance from the resonator by a dielectric material. In some embodiments, at least part of the portion of the at least one signal trace extends in a same direction as the first dimension (in the case of an L-shaped resonator) or tracks the zig-zag shape of the resonator (in the case of a zig-zag-shaped resonator).

A hard disk drive carrier assembly includes a back panel, and a connection mechanism in physical communication with the back panel of the hard disk drive carrier assembly along a first surface of the connection mechanism. The connection mechanism includes guide pin extending away from a second surface of the connection mechanism. The guide pin to align the hard disk drive carrier assembly with a mid-plane module of an information handling system when the hard disk drive carrier assembly is inserted into a bay of the information handling system. A screw is in physical communication with the connection module to mount the connection mechanism onto the back panel. The screw includes a post, and is inserted through a hole in the connection mechanism and is connected to the back panel. A first diameter of the post is smaller than a second diameter of the hole.

Various embodiments of the present technology provide systems and methods for mounting and dismounting a computing component (e.g., a HDD) of a server system. The server system contains a motherboard that includes at least one designated base bracket. Each of the at least one designated base bracket is configured to enable a carrier of a computing component to be mounted on and detached from. A designated base bracket can include one or more movable pins, one or more fixed pins, and a close latch.

A system for storing data includes a rack, one or more data storage modules coupled to the rack, and one or more data control modules coupled to the rack. The data storage modules may include a chassis, two or more backplanes coupled to the chassis, and one or more mass storage devices (for example, hard disk drives) coupled to the backplanes. The data control modules may access the mass storage devices in the data storage modules.

A data storage rack may only have a subset of the HDDs therein operating in an active mode where read/write operations may be performed. Other HDDs may operate in an idle mode, which is a power-saving state that permits the HDDs to quickly change-over to the active mode, when needed. In storage racks containing numerous HDDs, a majority of the HDDs may be operated at idle mode for a majority of the time. Where a large number of HDDs are operated at idle mode, a fixed common idle speed shared by the numerous HDDs can cause unwanted excitation, vibration, and resonance. This can yield increased wear on rack components, decreased performance from the HDDs therein, and increased noise. Variable HDD idle spindle speeds mitigate the foregoing, which is caused by an idle spindle speed previously common to many, if not all HDDs within the data storage rack.