Abstract: In an embodiment, a monitoring system may monitor a selected number of battery packs residing within a battery energy storage system. The monitoring system may include a plurality of battery pack monitoring devices each configured to monitor a battery pack. In an embodiment, the battery pack monitoring device may include a battery pack monitoring controller having a memory and a processor. The battery pack monitoring device may also include a voltage sensor, an ambient temperature sensor, an electric current sensor, a cell voltage sensor, and a cell temperature sensor, each coupled to the processor of the battery pack monitoring controller. The measured voltages, temperatures, and electric current may be stored in the memory of the battery pack monitoring controller.

Abstract: Embodiments are directed to a microgrid power system, and applications thereof. In an embodiment, the microgrid power system comprises a power station including an AC power source and a stabilizing battery system. The power station may be configured to generate an AC power and to provide the first AC power to a power distribution network. A plurality of load centers may be connected to the power distribution system. Each load center may include a local battery and a switch connecting the power station to a local load. A system controller may open the switch to provide power from the local battery to the local load, and close the switch to provide power from the power station to the local load. In an embodiment, a microgrid controller may determine an amount of AC power generated by the power station that may be consumed by each load center.

Abstract: The present disclosure provides techniques and solutions for obtaining state of charge estimates for one or more battery cells. A set of values is obtained for a set of one or more battery cells. The set of values includes a least one voltage measurement, at least one present current measurement, and at least one temperature measurement. The set of input values is submitted to a state of charge estimation model, as well as at least one prior current value for the set of one or more battery cells. A state of charge estimate is received for the set of one or more battery cells. In various implementations, the state of charge estimation model can be implemented as a machine learning model or as a lookup table. An estimate from the charge estimation model may be combined with one or more other state of charge estimates.

Abstract: Embodiments are directed to a microgrid power system, and applications thereof. In an embodiment, the microgrid power system comprises a power station including an AC power source and a stabilizing battery system. The power station may be configured to generate an AC power and to provide the first AC power to a power distribution network. A plurality of load centers may be connected to the power distribution system. Each load center may include a local battery and a switch connecting the power station to a local load. A system controller may open the switch to provide power from the local battery to the local load, and close the switch to provide power from the power station to the local load. In an embodiment, a microgrid controller may determine an amount of AC power generated by the power station that may be consumed by each load center.

Abstract: Techniques and solutions are provided for controlling fans associated with battery racks located in an enclosure. The fans can be ranked according to different criteria, such as using an average temperature of cells in a battery rack, a temperature of an enclosure housing the battery racks, an average temperature of battery racks in the enclosure, or using information about the spread of cell temperature of cells in particular racks. Higher-ranked racks can have their fans turned to an active state. In some cases, different ranking techniques can be used for different operational modes of an HVAC unit in communication with the enclosure. Disclosed techniques can have various benefits, such as improving ventilation of the enclosure, prioritizing heating or cooling of particular racks, or reducing temperature gradients, or temperature spread, between battery racks in an enclosure.

Abstract: A modular unit, for use in a modular battery system, that can include a housing having a roof portion, a base portion, and two side portions; a central component disposed within the housing; and one or more electrical distributor units coupled to the housing and operatively coupled to the central component. The modular unit can be configured to be operatively connected to one or more additional modular units to create a modular battery system.

Abstract: One or more of the present embodiments provide for a battery cell balancing system and strategy that delivers more efficient use of battery capacities as needed for different use cases. For example, a balancing circuit is provided to support targeted battery cell passive and active balancing according to a balancing strategy for the use cases. Further the balancing circuit allows for cell balancing to be performed while the battery cells are collectively being charged or discharged.

Abstract: Embodiments are directed to a microgrid power system, and applications thereof. In an embodiment, the microgrid power system comprises a power station including an AC power source and a stabilizing battery system. The power station may be configured to generate an AC power and to provide the first AC power to a power distribution network. A plurality of load centers may be connected to the power distribution system. Each load center may include a local battery and a switch connecting the power station to a local load. A system controller may open the switch to provide power from the local battery to the local load, and close the switch to provide power from the power station to the local load. In an embodiment, a microgrid controller may determine an amount of AC power generated by the power station that may be consumed by each load center.

Abstract: One or more of the present embodiments provide for a battery cell balancing system and strategy that delivers more efficient use of battery capacities as needed for different use cases. For example, a balancing circuit is provided to support targeted battery cell passive and active balancing according to a balancing strategy for the use cases. Further the balancing circuit allows for cell balancing to be performed while the battery cells are collectively being charged or discharged.

Abstract: Embodiments are directed to a microgrid power system, and applications thereof. In an embodiment, the microgrid power system comprises a power station including an AC power source and a stabilizing battery system. The power station may be configured to generate an AC power and to provide the first AC power to a power distribution network. A plurality of load centers may be connected to the power distribution system. Each load center may include a local battery and a switch connecting the power station to a local load. A system controller may open the switch to provide power from the local battery to the local load, and close the switch to provide power from the power station to the local load. In an embodiment, a microgrid controller may determine an amount of AC power generated by the power station that may be consumed by each load center.

Abstract: Embodiments are directed to a microgrid power system, and applications thereof. In an embodiment, the microgrid power system comprises a power station including an AC power source and a stabilizing battery system. The power station may be configured to generate an AC power and to provide the first AC power to a power distribution network. A plurality of load centers may be connected to the power distribution system. Each load center may include a local battery and a switch connecting the power station to a local load. A system controller may open the switch to provide power from the local battery to the local load, and close the switch to provide power from the power station to the local load. In an embodiment, a microgrid controller may determine an amount of AC power generated by the power station that may be consumed by each load center.

Abstract: One or more of the present embodiments provide for a suite of preset and customizable balancing applications that can be configured, selected and implemented to match the requirements a present use case. The suite of preset and customizable balancing applications may be presented to and selected by a user to tailor the balancing system to a particular use case. Alternatively, the balancing system may automatically select a balancing application, such as based on one or more inputs, to tailor the balancing system to the present use case.