A disk drive head suspension or flexure and method of manufacture. Embodiments include a portion such as a terminal pad or flying lead comprising a base layer, a dielectric layer on the base layer, a conductor layer, a seed layer between the dielectric layer and the conductor layer, and a noncorrosive metal layer on the seed layer side of the conductor layer. The seed layer has a strip that extends beyond the edge of the dielectric layer. The noncorrosive metal layer extends over the strip of the seed layer and into contact with the edge of the dielectric layer.

A method of manufacturing a chassis of an HIS includes manufacturing a chassis having a base panel with an upper chassis surface. The method further includes attaching at least one resilient component to the upper chassis surface and that upwardly presents an adhesive surface to fixedly engage and to provide vibration damping for a storage drive that is inserted on the adhesive surface during assembly of the IHS.

A drive carrier includes a latch wire, and a track that includes first and second segments. The latch wire is configured to move along a channel in the track to enable a handle of the drive carrier to transition between multiple positions within the track. The first segment is to be placed in physical communication with the latch wire while the latch wire is at a first position and a second position within the track. The second segment is in physical communication with the first segment. The second segment is to transition between a misaligned position and an aligned position with respect to the first segment, and the latch wire is to transition from the second position to a third position within the track in response to the second segment being in the aligned position.

A data storage device involves inner surfaces of sidewalls of a second cover overlapping with and adhesively bonded with the outer surfaces of sidewalls of an enclosure base having an uppermost top surface, where the second cover or an underlying first cover are removably adhered to the uppermost top surface of the base. The removable adhesive bond may comprise a pressure-sensitive adhesive, which can provide for reworkability during the manufacturing and testing process. The second cover-to-base sidewall bond may form a hermetic seal between the second cover and the base. Hence, a thinner base sidewall adjacent to the recording disks is enabled, leaving more space available for larger-diameter recording disks within a standard form factor, hermetically-sealed storage device, which may be filled with a lighter-than-air gas.

Embodiments of disk drive head suspensions are described that include a spring metal layer. The spring metal layer includes a base region, support arms extending from the base region, and a slider mounting region. The slider mounting region includes a proximal portion, a distal portion, and a pair of motor openings. The motor openings are configured to receive motors such that the longitudinal axes of the motors are non-parallel with the longitudinal axis of the slider mounting region. The suspensions include traces that include a base portion on the base region of the spring metal layer, a spring metal-unsupported portion extending from the base region to the slider mounting region, and a slider mounting portion extending from the spring metal-unsupported portion onto the slider mounting region. And, the suspensions include an insulating layer between portions of the spring metal layer and the conductor layer.

The present disclosure relates to using solid state deposition to selectively and strategically manage one or more properties of one or more portions of a data storage device. Material deposited via solid-state deposition can be used to prepare a surface for subsequent treatment (e.g., welding), to join two or more substrates together, and/or to seal one or more joints or surfaces to control, e.g., the humidity in the interior of a data storage device. The present disclosure also involves related data storage devices.

The present disclosure relates to using solid state deposition to selectively and strategically manage one or more properties of one or more portions of a data storage device. Material deposited via solid-state deposition can be used to prepare a surface for subsequent treatment (e.g., welding), to join two or more substrates together, and/or to seal one or more joints or surfaces to control, e.g., the humidity in the interior of a data storage device. The present disclosure also involves related data storage devices.

The present invention provides a method of feeding an agent, capable of stabilizing a remaining agent of a feeding part in characteristic and amount just before definitively feeding an agent to each definitive portion. The method includes intermittently moving a feeding part to a plurality of definitive portions defined on a structural object to definitively feed a flowable agent with a predetermined amount to each one of the definitive portions. The structural object includes a semi-finished product part with the definitive portions and a frame to be separated from the semi-finished product part. The frame includes a waste portion for the flowable agent. The waste portion has a same form as the definitive portions. The feeding part wastefully feeds the flowable agent to the waste portion with a same amount as the predetermined amount and thereafter starts the intermittently moving for the definitively feeding of the flowable agent.

A disk drive head suspension or flexure and method of manufacture. Embodiments include a portion such as a terminal pad or flying lead comprising a base layer, a dielectric layer on the base layer, a conductor layer, a seed layer between the dielectric layer and the conductor layer, and a noncorrosive metal layer on the seed layer side of the conductor layer. The seed layer has a strip that extends beyond the edge of the dielectric layer. The noncorrosive metal layer extends over the strip of the seed layer and into contact with the edge of the dielectric layer.

A data storage device involves inner surfaces of sidewalls of a second cover overlapping with and adhesively bonded with the outer surfaces of sidewalls of an enclosure base having an uppermost top surface, where the second cover or an underlying first cover are removably adhered to the uppermost top surface of the base. The removable adhesive bond may comprise a pressure-sensitive adhesive, which can provide for reworkability during the manufacturing and testing process. The second cover-to-base sidewall bond may form a hermetic seal between the second cover and the base. Hence, a thinner base sidewall adjacent to the recording disks is enabled, leaving more space available for larger-diameter recording disks within a standard form factor, hermetically-sealed storage device, which may be filled with a lighter-than-air gas.