A 0U, rack-mounted, power distribution, environment monitoring, and fire-protection apparatus including an environmental monitoring sensor system, including a fire detection and protection system located in a computer rack. The invention includes a system to localize damage to equipment, business interruption, and hazardous conditions to a computer rack.

A thermally and structurally optimized disaster resistant housing for a vertically stacked array of computer digital data storage devices such as hard drives is provided. An external, fire resistant housing has an internally mounted water resistant enclosure for the array. The water resistant enclosure includes a plurality of much thicker plates than known which significantly increase dissipation of heat and simultaneously greater increase the crush and impact load resistance of the device. An automatic method is also provided for producing complex molded gypsum or cement components.

Embodiments of the present invention are directed to systems, devices, and methods for data centers. In one example, a lockable enclosure for a data drive. The lockable enclosure includes a housing configured to house data drive circuitry and a port coupled to the housing and configured to connect to an external data device for transferring data from or to the data drive circuitry. The lockable enclosure also includes a sliding mechanism movable relative to the housing and configured to move within the housing between a position whereby the port is accessible to a position whereby the port is inaccessible.

In one example, a shell includes walls that collectively define an interior space of the shell, the interior space sized and configured to receive heat generating equipment. An internal heat exchanger disposed within the interior space is arranged for thermal communication with heat generating equipment when heat generating equipment is located in the interior space. Additionally, an external heat exchanger is located outside of the shell and arranged for fluid communication with the internal heat exchanger. Finally, a prime mover is provided that is in fluid communication with the internal heat exchanger and the external heat exchanger, and the prime mover is operable to circulate a flow of coolant through the internal heat exchanger and the external heat exchanger.

Embodiments of the present invention are directed to systems and methods for preventing unauthorized access to server racks. In one example, a system includes an electronic key and an electronic lock configured to be attached to the server rack. The electronic lock is configured to communicate with the electronic key for determining whether the electronic key is authorized to unlock or lock the lock. The electronic lock includes a handle configured to be disengaged from the electronic lock when the electronic key is authorized, and the handle is configured to be actuated to unlock the lock for accessing the server rack when the handle is disengaged from the electronic lock. The electronic lock is configured to re-lock only when the handle is engaged with the electronic lock.

In one example, a portion of a shell includes a shell wall portion that has an interior wall portion and an exterior wall portion located near the interior wall portion. In addition, fluid passageways are disposed between the interior wall portion and the exterior wall portion. One or more of the fluid passageways are defined in part by one or both of the interior wall portion and the exterior wall portion. The fluid passageways form part of heat exchanger that is integrated in the shell.

A system can include a key cartridge, which can include a housing, an enabling key component, and an electrical connector. The housing may be sized for placement at least partially over or around a latch release mechanism of a slidable rack sled and in a position to obstruct access to the latch release mechanism. The enabling key component can be positioned within the housing and enable operation of an electrical component situated within the slidable rack sled. The electrical connector can be coupled with the enabling key component and sized and positioned for establishing electrical connection between the enabling key component and the electrical component situated within the slidable rack sled when the pluggable key cartridge is installed relative to the server rack sled.

The systems and methods disclosed herein relate to shielding electronic devices with respect to, among other things, projectiles. In some embodiments, an apparatus comprises a plurality of projectile-resistant panels corresponding to exterior surfaces of an electronic device. The apparatus wraps the electronic device, wherein each of the plurality of projectile-resistant panels covers a solid surface of the exterior surfaces of the electronic device and does not cover a perforated surface of the exterior surfaces of the electronic device. In further examples, the apparatus further comprises at least one fabric sheet forming a plurality of pockets in which to receive the plurality of projectile-resistant panels; and an articulation located between a pair of adjacent pockets of the plurality of pockets. The articulation facilitates the apparatus wrapping the electronic device by enabling rotation, relative to one another and about the articulation, between a first projectile-resistant panel and a second projectile-resistant panel.

In some examples, a shock absorption bracket includes one or more damping pads coupled to a facing surface of an absorption leg. The absorption leg is attached to a support leg and defines an internal corner with the support leg. The support leg is configured to attach to an equipment cabinet. The shock absorption bracket may be configured to define a gap between the damping pads and one or more support surfaces of the equipment cabinet. The shock absorption bracket may be configured to attach to a rear section of an equipment cabinet having an equipment access in a front section of the equipment cabinet.

A data centre comprises a plurality of sections assembled together to define a unitary structure such that there exists at least one personnel area that spans at least two sections; wherein the sections comprise a first section with which there is associated a first service-carrying chassis and a second section with which there is associated a second service-carrying chassis, each of the first and second service-carrying chassis comprising a frame onto which is mounted components of at least two different services; the first and second chassis are connected to each other by means of a junction between the first and second chassis; and the first and second sections each include a ceiling and the first service carrying chassis is mounted on the ceiling of the first section and the second service carrying chassis is mounted on the ceiling of the second section.