Various aspects of the present disclosure are directed toward a disc drive actuator assembly including an e-block, a plurality of bearings, and one or more heat transfer components. The heat transfer component(s) operates to conductively draw heat from the plurality of bearings through the e-block, and convectively dissipate the heat into an atmosphere in contact therewith. The heat transfer component(s) mitigates temperature rise of the bearings during operation of a disc drive, thereby mitigating bearing lubricant outgassing from within the bearings.

Apparatus for dissipating heat during the operation of a device. In accordance with some embodiments, the apparatus compares spaced-apart first and second heat sources. A thermally conductive plate is disposed between the first and second heat sources. A thermal interface layer is contactingly disposed between the plate and the first heat source, and has a relatively higher thermal conductivity so that heat generated by the first heat source passes through the thermal interface layer and to the plate. A thermal barrier layer is contactingly disposed between the plate and the second heat source to mechanically support the plate relative to the second heat source. The thermal barrier layer has a relatively lower thermal conductivity to thermally isolate the conductive plate from the second heat source.

A heat sink can be used as part of a storage drive to perform multiple functions, both structural and thermodynamic. It can be used as a heat dissipating element and it can be used as the key mechanical mounting structure for storage drives, such as hard disk drives (HDD), and any circuit boards.

A near-field transducer includes an enlarged portion and a peg protruding from a first edge. The enlarged portion has a second edge facing away from the first edge. The near-field transducer includes a heat sink disposed on the enlarged portion and with an outline shape that matches that of the enlarged portion. The heat sink is disposed at a first separation distance from the first edge of the enlarged portion and a second, greater, separation distance from the second edge of the enlarged portion. The first separation distance is greater than the second separation distance.

A fanless industrial computer enclosure dissipates heat generated by the hottest components on heat sinks dedicated to respective heat zones within the enclosure. Heat generated by the component that operates at the highest temperature in each heat zone is conducted to a heat sink on the exterior of the enclosure. Using a heat sink dedicated to each heat zone, heat generated by components such as an industrial computer, storage devices, power supply, or other electrical components, is dissipated on the outer surface of the enclosure to the surrounding ambient environment. Providing a low resistance heat conductive path from the hottest components to respective heat sinks to dissipate heat outside the enclosure from each heat zone creates an environment within the enclosure where disk drives do not exceed the specified upper operating temperature rating without regard to the operating temperature of other electrical components in the enclosure.

A heat sink can be used as part of a storage drive to perform multiple functions, both structural and thermodynamic. It can be used as a heat dissipating element and it can be used as the key mechanical mounting structure for storage drives, such as hard disk drives (HDD), and any circuit boards.

A heat dissipation structure for an external apparatus is a heat dissipation structure for an external apparatus in an electronic apparatus including a housing section configured to removably house an external apparatus. The heat dissipation structure for an external apparatus includes a heat dissipation portion, which is removably attached to the external apparatus and which has thermal conductivity for transferring heat generated by the external apparatus to the housing section.

Embodiments of apparatuses, systems and methods related to Solid State Drive (SSD) cooling in dense storage are described. An embodiment of an apparatus may include a housing. The apparatus may also include a first set of peripheral heatsink fins disposed parallel to a first axis of the housing. Additionally, the apparatus may include a second set of peripheral heatsink fins disposed parallel to a second axis of the housing. Also, the apparatus may include a set of heatsink members disposed adjacent the first set of peripheral heatsink fins and the second set of peripheral heatsink fins, the set of heat sink members configured to align with at least one of the first set of peripheral heatsink fins and the second set of peripheral heatsink fins.

A spoiler (40) that is a rectifying component for a magnetic disk device including a flat plate-like plate portion (41) arranged to face a magnetic disk (10), and a support portion (42) that supports the plate portion (41) includes a body portion (401) made of a resin, and a metal plating layer (402) that covers an entire surface of the body portion (401).

Various aspects of the present disclosure are directed toward a disc drive actuator assembly including an e-block, a plurality of bearings, and one or more heat transfer components. The heat transfer component(s) operates to conductively draw heat from the plurality of bearings through the e-block, and convectively dissipate the heat into an atmosphere in contact therewith. The heat transfer component(s) mitigates temperature rise of the bearings during operation of a disc drive, thereby mitigating bearing lubricant outgassing from within the bearings.