Methods for redeploying used battery units can include capturing performance data of an energy storage unit containing a battery unit at the end of its useful life for a primary application, and determining, based on the performance data, a remaining energy output capacity. If the battery unit meets or exceeds threshold performance criteria, the battery unit can be incorporated into a second energy storage unit and reconfigured to reflect the remaining energy output capacity. The second storage unit can include the redeployed battery unit alone, or in combination with any suitable number of additional battery units.

A method of operating a power generation system, such as a fuel cell power generation system, includes providing a first electrical power up to a threshold amount of power to a load from at least one power module via a plurality of DC/DC converters and a DC power bus, determining whether electrical power from a utility is available, and providing a second electrical power from the at least one power module to a rectifier path via a plurality of DC/AC inverters in response to determining that the electrical power from the utility is available. The second electrical power includes electrical power generated by the at least one power module in excess of the threshold amount of electrical power.

An uninterruptible power supply (UPS) system with stranded power recovery has a plurality of UPS modules with one or more of the UPS modules usable to provide stranded power to a recovered power bus. When a UPS module is used to provide stranded power to the recovered power bus, the AC/AC converter associated with that UPS module provides AC power that is synchronized with AC power being provided to the recovered power bus by each of the other AC/AC converters that are providing AC power. In this manner all of the AC/AC converters that are providing AC power to the recovered power bus have the same voltage, the same frequency, and are in phase.

A method includes selectably controlling a power supply from a renewable energy source based power system and an energy storage device charged thereby and/or an Alternating Current (AC) power system to a computing system including one or more data processing device(s) using an electronic control system, and continuously updating, through a computing power management system associated with the electronic control system, a parameter of operation of the energy storage device in response to analyzing data pertinent to prior energy usage/production and/or predicted energy usage/production relevant to execution of a high computational workload through the one or more data processing device(s). The method also includes optimizing the power supply from the energy storage device to the one or more data processing device(s) using the computing power management system based on the continuously updated parameter of operation of the energy storage device.

A data center includes a server rack and a back-up battery rack. The back-up battery rack includes a plurality of battery modules, each of which has completed a primary usage as an emergency power source for the server rack. A monitoring device determines a system configuration of the plurality of battery modules in the back-up battery rack, based on a specification required for the back-up battery rack and a history characteristic of each of the battery modules that has completed the primary usage in the server rack.

A system and method for operation of an uninterruptible power supply using redundant control systems to prevent UPS failure due to a control system failure are described. The system includes multiple control modules for each UPS of a data center operating in parallel, with a primary control board controlling operations and a secondary control board monitoring data values monitored as part of the operation by the primary control board. In the event of discrepancies between the data values at the primary and secondary control boards, the control boards may be swapped such that the secondary board becomes primary, and the faulty control board may be hot-swapped to prevent downtime of the UPS.

An asset manager controls power distribution within an aggregated distributed energy resources system (“DERs system”) having a plurality of assets. The asset manager is configured to operate with a given asset. As such, the asset manager has 1) an interface to receive asset information relating to the given asset and to communicate with another asset manager in the DERs system, and 2) a function generator configured to produce a local cost function using data relating to the given asset only. The local cost function represents a portion of a system cost function for the DERs system. The asset manager also has 3) a controller configured to use the local cost function for the given asset to manage operation of the given asset in the DERs system. In addition, the controller also is configured to determine, using the local cost function, an operating point for the given asset.

Systems include one or more critical datacenter connected to behind-the-meter flexible datacenters. The critical datacenter is powered by grid power and not necessarily collocated with the flexible datacenters, which are powered “behind the meter.” When a computational operation to be performed at the critical datacenter is identified and determined that it can be performed more efficiently or advantageously at a flexible datacenter, the computational operation is instead obtained by the flexible datacenters for performance The critical datacenter and flexible datacenters preferably share a dedicated communication pathway to enable high-bandwidth, low-latency, secure data transmissions. A queue system may be used to organize computational operations waiting for distribution to either the critical datacenter or the flexible datacenter.

The present disclosure relates to methods and devices (101, 106) of controlling reactive power of a power grid. In an aspect, a method of a radio base station (101) of controlling reactive power of a power grid is provided. The method comprises measuring (S101) an electrical property indicating a level of the reactive power supplied by the power grid to which the radio base station (101) is connected, and performing (S102) an action to stabilize the level of the reactive power of the power grid upon the measured electrical property reaching a certain value.

Systems include one or more critical datacenter connected to behind-the-meter flexible datacenters. The critical datacenter is powered by grid power and not necessarily collocated with the flexible datacenters, which are powered “behind the meter.” When a computational operation to be performed at the critical datacenter is identified and determined that it can be performed more efficiently or advantageously at a flexible datacenter, the computational operation is instead obtained by the flexible datacenters for performance. The critical datacenter and flexible datacenters preferably share a dedicated communication pathway to enable high-bandwidth, low-latency, secure data transmissions. A queue system may be used to organize computational operations waiting for distribution to either the critical datacenter or the flexible datacenter.