A server system comprises a base, a front panel (13) arranged on the base and defining a collecting space; two doors (16) arranged on opposite sides of the base, and being perpendicular to the front panel; two storage cases (171) arranged between the doors in a back to back arrangement, and configured to receive multiple rows and columns of a plurality of storage drives horizontally, wherein two first corridors are each defined between one of the doors and one of the storage case facing the one door; two circuit boards (18) arranged between the two storage cases, wherein the two circuit boards comprise a plurality of slits, wherein a second corridor is defined between the two circuit boards; a storage cover (121) disposed above the base over the two first corridors, the second corridor, the two storage cases, and the two circuit boards.

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.

The present invention aims at improving a cooling efficiency and a maintenance workability related to heat generating components in a storage subsystem. Therefore, the present invention provides multiple cooling fans configured to cool multiple components for operating the storage subsystem, a first wind direction panel defining a passage configured to blow a cooling air generated by the cooling fans to a first component, a second wind direction panel defining a passage configured to blow a cooling air generated by the cooling fans to a second component having a smaller heating value than the first heat generating component and having a low temperature, and a chassis configured to store the multiple components, the cooling fans and the first and second wind direction panels, wherein the second wind direction panel is configured to be integrated with a side wall of the chassis and detachable from the chassis.

An electronic apparatus includes a plurality of parts, a frame having an outer periphery surrounding the plurality of parts and formed from resin, a circuit board disposed at one side in a first direction with respect to the plurality of parts, a chassis disposed at the one side in the first direction with respect to the plurality of parts, attached to the frame, and formed from metal, and a metal plate disposed at the other side in the first direction with respect to at least one of the plurality of parts and attached to the frame.

The present disclosure provides a chassis and an electronic device applying the chassis. The chassis includes: a chassis body; the chassis body is a 2U chassis body or a 4U chassis body; a hard disk module, installed in a front end area of the chassis body; a power supply module, installed at one side of a rear end area of the chassis body; a controller module, installed in a remaining rear end area of the chassis body except the power supply module, parallel with the power supply module, and including a plurality of pluggable functional modules; a middle board, connected with the power supply module, the hard disk module, and the control module, respectively, to realize the electrical connection between the power supply module, the hard disk module, and the control module. The present disclosure can improve the versatility of the chassis modules.

To provide enhanced operation of data storage devices and systems, various systems and apparatuses are provided herein. In a first example, a data storage assembly includes an enclosure configured to house at least one data storage device and a fan assembly configured to provide airflow within the enclosure to ventilate the at least one data storage device. A plurality of acoustic waves emanate into the data storage device from one or more fans of the fan assembly during operation. An acoustic attenuation device is positioned within the enclosure and configured to deflect at least a first portion of the plurality of acoustic waves away from the at least one data storage device and absorb a portion of acoustic wave energy of at least a second portion of the plurality of acoustic waves.

Technology is provided for a data storage server drawer. The server drawer includes a drawer chassis having first and second lateral drive bays separated by a central channel. The drawer chassis includes a front wall including one or more air flow openings, a bottom wall having one or more louvers opening toward the front wall, and a pair of sidewalls. A pair of drawer slides are each disposed on a corresponding one of the pair of sidewalls and configured for attachment to a rack. A first plurality of data storage devices is positioned in the first drive bay and a second plurality of data storage devices is positioned in the second drive bay. At least one data server is disposed in the central channel.

A system for cooling hard disk drives (HDDs) includes: an enclosure having (i) a lower volume within which a cooling liquid is heated to a boiling point to cause some of the cooling liquid to evaporate, creating a plume of rising vapor and (ii) an upper volume having (a) a HDD cooling area with HDD(s) placed in the direct path of the rising vapor, which cools the HDD(s) during functional operation of the HDD(s) and (b) a condenser located above the HDD cooling area and which cools a substantial portion of the rising vapor that impacts the condenser within the upper volume such that the rising vapor condenses back into liquid phase on contact with the condenser; and a heat source that dissipates heat into the lower volume of the enclosure, sufficient to heat the cooling liquid to the boiling point temperature.

A system, according to one embodiment, includes: a first frame of an automated tape library, wherein an interior of the first frame includes one or more tape drives, an area for storing tape cartridges, and an accessor channel, and a first air conditioning unit coupled to the first frame. The first air conditioning unit is configured to cool the interior of the first frame. Moreover, one or more fans of the one or more tape drives are configured to generate air flow within the interior of the first frame. Other systems, computer-implemented methods, and computer program products are described in additional embodiments.

Systems, methods and computer-readable media for reducing upstream preheat for high-density hard disk drive storage. A system can include first and second rows of storage devices installed in a storage rack, the first and second rows having a first distance between consecutive storage devices. The second row can be located behind the first row and farther away from a source of an airflow than the first row. The system can monitor a temperature associated with the second row and when the temperature rises above a threshold, the system can remove a storage device from the first row. The system can then adjust placement within the first row such that the remaining devices have a second, larger distance between each other to increase airflow to storage devices in the second row and reduce system impedance.