Abstract: A battery system for storing electric energy on a grid system comprises a stationary energy storage facility comprising a first bank of batteries comprising a first plurality of batteries of a first type, wherein the first type comprises stationary storage batteries, a local power conversion system for receiving output of the first plurality of batteries and outputting power to the grid system, and a local controller for integrating and operating the local power conversion system with the first bank of batteries; an augmentation battery system comprising a second bank of batteries comprising a second plurality of batteries of a second type, wherein the second type of batteries comprises electric vehicle batteries, a secondary power conversion system for receiving output of the second plurality of batteries and outputting power to the local power conversion system, and a battery management system for operating the second bank of batteries, the battery management system comprising part of the electric vehicle b

Abstract: A battery energy storage system comprises a first equipment unit comprising a first skid positionable on a surface, a first inverter and a first transformer mounted on the first skid, a second equipment unit comprising a second skid, a second inverter and a second transformer mounted on the second skid, and a support structure for positioning the second equipment unit longitudinally above and spaced apart from the first equipment unit in a laterally offset manner. A method of increasing energy storage capacity of a storage system comprises building a support structure over a first inverter and transformer unit installed at a first location, placing a second inverter and transformer unit on the support structure such that the second inverter and transformer unit is longitudinally spaced from and laterally offset from the first inverter and transformer unit and adding an additional battery container.

Abstract: A utility-scale energy storage and conversion system can operate two or more inverter groups such that their reactive power commands are proportional to their available reactive power range. The control system can therefore distribute the reactive power commands in proportion to the available Q range, thereby ensuring that all inverters in the utility-scale energy storage and conversion system 100 operate with the same Q “headroom”. In addition, the utility-scale energy storage and conversion system can use an on-load tap changer (LTC) to adjust a terminal voltage associated with a first group of inverters and a second group of inverters. The first group of inverters can be associated with a first rating and the second group of inverters can be associated with a second rating that is greater than the first rating.

Abstract: A utility-scale energy storage and conversion system can operate two or more inverter groups such that their reactive power commands are proportional to their available reactive power range. The control system can therefore distribute the reactive power commands in proportion to the available Q range, thereby ensuring that all inverters in the utility-scale energy storage and conversion system 100 operate with the same Q “headroom”. In addition, the utility-scale energy storage and conversion system can use an on-load tap changer (LTC) to adjust a terminal voltage associated with a first group of inverters and a second group of inverters. The first group of inverters can be associated with a first rating and the second group of inverters can be associated with a second rating that is greater than the first rating.

Abstract: A utility-scale energy storage and conversion system can operate two or more inverter groups such that their reactive power commands are proportional to their available reactive power range. The control system can therefore distribute the reactive power commands in proportion to the available Q range, thereby ensuring that all inverters in the utility-scale energy storage and conversion system 100 operate with the same Q “headroom”. In addition, the utility-scale energy storage and conversion system can use an on-load tap changer (LTC) to adjust a terminal voltage associated with a first group of inverters and a second group of inverters. The first group of inverters can be associated with a first rating and the second group of inverters can be associated with a second rating that is greater than the first rating.