A method for monitoring an electric power source changeover switch, including a step of identifying all of the combinations of operating modes and availability states of the power sources, a step of associating a configuration of a state of switches with each combination, a step of watching for a change in configuration. Upon a change in configuration, a step of controlling the switches is executed in order to place the switches in a state complying with the configuration. In the absence of a change in configuration, a step monitors the compliance of the configuration with the actual state of the switches. A method further including monitoring a source changeover switch implemented in a test device, and to a source changeover switch implementing such a method.

A method for monitoring an electric power source changeover switch, including a step of identifying all of the combinations of operating modes and availability states of the power sources, a step of associating a configuration of a state of switches with each combination, a step of watching for a change in configuration. Upon a change in configuration, a step of controlling the switches is executed in order to place the switches in a state complying with the configuration. In the absence of a change in configuration, a step monitors the compliance of the configuration with the actual state of the switches. A method further including monitoring a source changeover switch implemented in a test device, and to a source changeover switch implementing such a method.

The present disclosure relates to an energy storage system for managing power of a system and a DC power distribution network linked with the system. In one embodiment, the system, comprises a first converter connected between the system and the DC power distribution network so as to control voltage of the DC power distribution network; a second converter connected to the DC power distribution network; a battery which is connected to the second converter and in which a charging/discharging operation is controlled by the second converter; a third converter connected to the DC power distribution network; an emergency generator which is connected to the third converter and in which a power is controlled by the third converter; a fourth converter connected to the DC power distribution network; and a first load which is connected to the fourth converter and in which a voltage is controlled by the fourth converter.

A Remote Monitoring and Control System (RMCS) for an electrical power system includes a control/communication module and a test apparatus. The test apparatus includes electrical power system test components electrically coupled in or to an automatic transfer switch of the electrical power system and the control/communication module. The test components are operable by the control/communication module for controlling, monitoring, assessing, and testing one or more functions of the electrical power system. A method of assessing a backup power system includes: coupling electrical power system test components to an automatic transfer switch of the backup power system; communicatively coupling the electrical power system test components to a control/communication module; and operating the electrical power system test components to measure or test conditions in the backup power system. The RMCS can provide seamless 24/7 monitoring coverage and control capabilities to enhance system performance and reliability.

A Remote Monitoring and Control System (RMCS) for an electrical power system includes a control/communication module and a test apparatus. The test apparatus includes electrical power system test components electrically coupled in or to an automatic transfer switch of the electrical power system and the control/communication module. The test components are operable by the control/communication module for controlling, monitoring, assessing, and testing one or more functions of the electrical power system. A method of assessing a backup power system includes: coupling electrical power system test components to an automatic transfer switch of the backup power system; communicatively coupling the electrical power system test components to a control/communication module; and operating the electrical power system test components to measure or test conditions in the backup power system. The RMCS can provide seamless 24/7 monitoring coverage and control capabilities to enhance system performance and reliability.

The present disclosure relates to a system for controlling power walk-in for an uninterruptible power supply (UPS) being switched to receive AC power from an AC generator. The system may have a control system and a power walk-in (PWI) subsystem. The PWI subsystem may be controlled in part by the control system. The PWI subsystem may be configured to control at least one of an input current or an input power of an AC signal being provided by an AC generator during a power walk-in operation to attempt to maintain a minimum frequency of the AC signal from the AC generator during the power walk-in operation.

Systems, apparatuses, and methods for a modular inverter system having a single device enclosure with a plurality of module receptacles capable of receiving one or more modules having tailored functionality. Such modules work in conjunction with each other to handle control of various power sources and power sinks in a mixed use power generation and consumption system. In various embodiments, these swappable modules include a charge controller module configured to control charging a battery, an inverter/charger module configured to convert an AC voltage to a DC voltage for charging the battery and configured to invert a DC voltage to an AC voltage for supplying AC power, a controller module configured to control the plurality of inverter/charger modules and the charge controller module; and a backplane disposed in the enclosure such that each module receptacle facilitates engaging a respective module with the backplane.

Systems, apparatuses, and methods for a modular inverter system having a single device enclosure with a plurality of module receptacles capable of receiving one or more modules having tailored functionality. Such modules work in conjunction with each other to handle control of various power sources and power sinks in a mixed use power generation and consumption system. In various embodiments, these swappable modules include a charge controller module configured to control charging a battery, an inverter/charger module configured to convert an AC voltage to a DC voltage for charging the battery and configured to invert a DC voltage to an AC voltage for supplying AC power, a controller module configured to control the plurality of inverter/charger modules and the charge controller module; and a backplane disposed in the enclosure such that each module receptacle facilitates engaging a respective module with the backplane.

During power running operation of a load, a control unit turns off a switch unit to supply AC power from an uninterruptible power supply unit to the load. During regenerative operation of the load, in a case where an AC power supply can recover regenerative power, the control unit turns off the switch unit to supply the regenerative power to the AC power supply via the uninterruptible power supply unit. In contrast, in a case where the AC power supply cannot recover the regenerative power, the control unit turns on the switch unit to cause an auxiliary load unit to consume the regenerative power.

A power supply unit (PSU) dynamically limits total recovery current. The PSU includes at least a power input, a power output, a historic maximum power draw memory, an update logic, and a recovery current limiting logic. Some implementations include a latest power measurement register, an hourly max power register, and a rolling max register, and controlling firmware. The update logic monitors a power level. The update logic updates the historic maximum power draw memory to match the monitored level. After a power interruption, the recovery current permitted to flow into the PSU is limited based on the historic usage. The recovery current may be limited in a constant, stepped, or ramped manner. The PSU may also provide power distribution. Multiple PSUs may be treated as a group, allowing an individual PSU to exceed its historic usage while the group's recovery currents are limited to the sum of historic usage levels.