Disclosed are a data disaster recovery storage device and a carrier. The data disaster recovery storage device comprises: a housing; a fire-resistant shell; a liner; an internal data line; and a memory. The memory is connected to the internal data line, and is suspended inside the liner. The water absorption resin is filled at the outer side of the memory. According to the present invention, a plurality of thermal insulation and heat-dissipation means are used for ensuring the safety of the memory during vehicle burning. The memory is mounted in a suspended manner, and is not in direct contact with other structures, which can effectively avoid direct heat conduction, and effectively perform shock absorbing. The invention utilizes the property that water boils at a constant temperature under the standard atmospheric pressure, and uses a method for storing water in a liner shell to ensure that the memory is not damaged at a certain external high temperature within a certain period of time.

An energy dampener for use in an electronic device can include a carbon nanotube-aerogel matrix, including carbon nanotubes embedded in an aerogel and a rubber composited with the carbon nanotube-aerogel matrix.

An energy dampener for use in an electronic device can include a carbon nanotube-aerogel matrix, including carbon nanotubes embedded in an aerogel and a rubber composited with the carbon nanotube-aerogel matrix.

A suspension includes a load beam with first and second openings, a flexure including first and second outriggers, and first and second damper members. The first damper member is attached to the load beam and part of the first outrigger that overlaps the first opening of the load beam. The second damper member is attached to the load beam and part of the second outrigger that overlaps the second opening of the load beam. The first opening includes a region which is not covered by the first damper member, and the second opening includes a region which is not covered by the second damper member.

A storage apparatus includes a disk-shaped recording medium, a motor configured to drive and rotate the recording medium, a head configured to read information from and write information to the recording medium, and a support member configured to support the recording medium when the recording bends in response to external vibration or shock. The support member supports the recording medium by making contact with the recording medium only when the external vibration or shock is applied to the storage apparatus.

An information handling system may include a backplane configured to couple at a first side thereof to a plurality of physical storage resources, an air mover configured to provide cooling to the information handling system, and a shelf coupled to the backplane at a second, opposite side thereof, wherein the shelf is disposed between the first side of the backplane and the air mover. The shelf may include an acoustically absorbent material.

A data storage system includes a chassis housing multiple data storage devices, such as hard disk drives, a compartment housing cooling fans, and an air plenum positioned between the fans and the storage devices. A multibody chambered acoustic attenuator, which may be installed in the air plenum, includes a plate part having airflow holes therethrough and may include a convex arched part having airflow holes therethrough and coupled with the plate part to form a chamber. Acoustic damping material lines an interior surface of the plate part and the interior and exterior surfaces of the arched part, and the airflow holes of the plate part and of the arched part are not aligned, such that direct acoustic emissions and reflections would contact the acoustic damping material and a circuitous airflow path is provided from the cooling fans to the storage devices, to reduce the acoustic sound pressure upon the devices.

A data storage system includes a chassis housing multiple data storage devices, such as hard disk drives, a compartment housing cooling fans, and an air plenum positioned between the fans and the storage devices. A multibody chambered acoustic attenuator, which may be installed in the air plenum, includes a plate part having airflow holes therethrough and may include a convex arched part having airflow holes therethrough and coupled with the plate part to form a chamber. Acoustic damping material lines an interior surface of the plate part and the interior and exterior surfaces of the arched part, and the airflow holes of the plate part and of the arched part are not aligned, such that direct acoustic emissions and reflections would contact the acoustic damping material and a circuitous airflow path is provided from the cooling fans to the storage devices, to reduce the acoustic sound pressure upon the devices.

A shock absorber apparatus is provided. The shock absorber apparatus includes an elastic device and at least one mounting device connected to the elastic device. Each mounting device includes two securing elements. Each securing element is configured to secure an opposing portion of a structure. Each mounting device can also include two sliders. Each slider can have at least two surfaces, which are interconnected by an inclined surface facing an opposing slider, and a ground surface. The inclined surface can be slidably connected to one of the at least two securing elements. Each slider can be arranged to move in response to an applied force. The ground surface is configured to slidably connect to an inner wall of a box.

A shock absorber apparatus is provided. The shock absorber apparatus includes an elastic device and at least one mounting device connected to the elastic device. Each mounting device includes two securing elements. Each securing element is configured to secure an opposing portion of a structure. Each mounting device can also include two sliders. Each slider can have at least two surfaces, which are interconnected by an inclined surface facing an opposing slider, and a ground surface. The inclined surface can be slidably connected to one of the at least two securing elements. Each slider can be arranged to move in response to an applied force. The ground surface is configured to slidably connect to an inner wall of a box.