A container data center is provided. The data center is provided in a shipping container, and the container data center includes a cooling system including a plurality of cooling devices for cooling the data center; a power supply and distribution system including a power supply circuit for supplying power to the data center; and a control system electrically connected to the cooling system and the power supply and distribution system; wherein the control system comprises a plurality of control devices, the plurality of control devices each configured to control a part of the cooling devices, and when a first part of the plurality of control devices cannot work, a working mode of a second part of the control devices is adjusted to control the plurality of the cooling devices.

Technologies for allocating resources of managed nodes to workloads to balance multiple resource allocation objectives include an orchestrator server to receive resource allocation objective data indicative of multiple resource allocation objectives to be satisfied. The orchestrator server is additionally to determine an initial assignment of a set of workloads among the managed nodes and receive telemetry data from the managed nodes. The orchestrator server is further to determine, as a function of the telemetry data and the resource allocation objective data, an adjustment to the assignment of the workloads to increase an achievement of at least one of the resource allocation objectives without decreasing an achievement of another of the resource allocation objectives, and apply the adjustments to the assignments of the workloads among the managed nodes as the workloads are performed. Other embodiments are also described and claimed.

The present disclosure provides a power system that includes a set of power devices and addressing lines. The set of power devices are electrically connected to a main power source, a standby power source and a server node. The addressing lines are electrically connected to the set of power devices, so that the set of power devices can correspond to a plurality of different addressing signals respectively. The set of power devices are switched at different times based on the different addressing signals, so that one of the main power source or the standby power source supplies power to the server node though the set of power devices.

A server memory device provides highspeed storage to a computer system. The server memory device has a connector that can make electrical coupling with the computer system. The server memory device includes two memory modules, each with one or more memory chips. Each memory module is coupled and bonded with an interposer. Each interposer is coupled and bonded with the server memory device connector. The connector and interposers provide a high-density interconnect that connects two memory modules to a computer system. The server memory device has a form factor that uses a single unit (1U) of a server rack, doubling the memory capacity provided to the computer system through a single unit (1U) equipment rack.

Several transportable datacenters are described. The transportable datacenters include transport systems allowing them to be transported between an assembly location and an operating location. The transportable datacenters also include a ventilation system for cooling processors positioned in racks in the datacenters. The ventilation system draws cold air from the environment, through processor bays containing the processors and then exhausts the air back to the environment.

The disclosure provides a network equipment power supply and a heat dissipation system therefor. The heat dissipation system includes a liquid-cooling heat dissipation device and an air-cooling heat dissipation device. The liquid-cooling heat dissipation device includes a liquid inlet, a liquid outlet, and a liquid-cooling pipe between them, wherein liquid-cooling medium flows inside the liquid-cooling pipe and takes away heat generated by components arranged around the liquid-cooling pipe; The air-cooling heat dissipation device includes an air inlet, an air outlet, and an air-cooling channel between them, wherein airflow passes through the air-cooling channel and takes away heat generated by components arranged around the air-cooling channel. The disclosure conducts hybrid heat dissipation combining characteristics of liquid-cooling heat dissipation and air-cooling heat dissipation to effectively enhance heat dissipation efficiency, and provides a new choice for design of a power supply unit with high power density.

According to one embodiment, a control system for a rack that includes a RMC that is communicatively coupled to pieces of equipment, each piece of equipment including a leak sensor and is fluidly coupled to a rack liquid manifold that circulates liquid coolant through the piece of equipment, several switches, and a control device that has a memory storage device that includes several of switch control and operation configurations, where in response to the RMC receiving a leak signal from a leak sensor, the control device determines each switch configuration based on the leak sensor from which the leak signal is received, and sets the switches in the configuration in which each of one or more switches, including a switch that controls the flow of coolant into the piece of equipment, exit the equipment, and prevents coolant from flowing from the manifold into a respective piece of equipment.

A system is provided. The system includes a computing resource, a cable insertable into the computing resource, a locking element and a controller. The locking element is configured to assume a locked condition in which the cable is locked to the computing resource or prevented from insertion into the computing resource and an unlocked condition in which the cable is removable from the computing resource and permitted to be inserted into the computing resource. The controller is configured to define rules for users. The rules are associated with respective identifiers (IDs) of each of the users and establish criteria associated with each user for causing the locking element to assume one of the locked and unlocked conditions.

A floor system in a server room includes a main panel and a sub-panel. The main panel includes main panel inlaid cables and main panel connectors where the main panel inlaid cables connect a first set of the main panel connectors to a second set of the main panel connectors. The sub-panel includes sub-panel inlaid cables and sub-panel connectors where the sub-panel inlaid cables connect the sub-panel connectors to one another. The floor system provides an operating floor via the main panel and the sub-panel where the operating floor is raised relative to a sub-floor and the main panel is a removable floor panel to access a space between the operating floor and the sub-floor. The main panel inlaid cables and the sub-panel inlaid cables establish a current pathway from a power source.

A server rack assembly includes a pair of mounting units each including a panel, an adjustment plate, and rails. The panel has a first panel flange to connect a front support post. The adjustment plate is movably connected to the panel for connecting a rear support post and is adjustable to suit varying distances between front and rear support posts. The rails are detachably mounted on the panel; a gap between two rails is adjustable to accommodate different server devices.