Abstract: The electrical consumption mitigation provided by energy storage systems can be unreliable when a consumption peak lasts long enough to deplete the energy stored and the remainder of the peak is unmitigated. By implementing a waiting period between detecting the peak and discharging the energy storage in which characteristics of the peak are observed, a peak mitigation system can lengthen the effective discharge duration of the energy storage system and prevent unmitigated plateaus from appearing. For example, when a consumption plateau is detected, the system may discharge at a slower rate than when a spike is detected in order to prolong mitigation activities before the conclusion of the plateau. Thus otherwise-incurred demand-related utility charges can be reduced without having to increase the capacity of the mitigation system. In some cases, these processes are performed with respect to the bounds of demand-averaged time periods used to calculate demand charges.

Abstract: The electrical consumption mitigation provided by energy storage systems can be unreliable when a consumption peak lasts long enough to deplete the energy stored and the remainder of the peak is unmitigated. By implementing a waiting period between detecting the peak and discharging the energy storage in which characteristics of the peak are observed, a peak mitigation system can lengthen the effective discharge duration of the energy storage system and prevent unmitigated plateaus from appearing. For example, when a consumption plateau is detected, the system may discharge at a slower rate than when a spike is detected in order to prolong mitigation activities before the conclusion of the plateau. Thus otherwise-incurred demand-related utility charges can be reduced without having to increase the capacity of the mitigation system. In some cases, these processes are performed with respect to the bounds of demand-averaged time periods used to calculate demand charges.

Abstract: Systems of networking power management systems are disclosed, wherein the systems receive control parameters from a control terminal and bring about demand response, curtailment, and other load management actions. One control terminal may be used to control many zones in different ways, and the load management actions may be automated to improve efficiency and predictability of the results of demand response actions. Some of the systems may be mobile and connectable to different sites in the network to respond to changing needs in the utility distribution grid. Large demand response requirements may be distributed among multiple sites or systems in order to encourage and enable participation in demand response programs by customers that would not traditionally be able to do so because of not being able to produce sufficient demand response results individually.

Abstract: Modular consumption management systems provide benefits of adaptability, customization, and progressive investment to electrical utility customers, particularly those with loads and electrical systems capable of curtailment and mitigation. Providing modules based on measurements made and consumption patterns detected in load profiles of individual loads and the site as a whole is described. Control and mitigation capabilities and methods are described in conjunction with identifying correlative modules that will best serve the needs of the site being monitored by a measurement module. Combined measurement and control modules or control and mitigation modules are also described, as well as interchangeable modules that can be put in place when excess consumption patterns at the site change over time.

Abstract: A utility distribution control system and method for performing distribution control of energy within a utility service network including an energy distribution network in communication with a plurality of energy resources. The energy distribution network includes a plurality of energy storage and generation devices which receive energy from at least one of the energy resources of the plurality of resources and distribute energy, and a controller which controls the plurality of energy storage and generation devices, to distribute energy.

Abstract: The electrical consumption mitigation provided by energy storage systems can be unreliable when a consumption peak lasts long enough to deplete the energy stored and the remainder of the peak is unmitigated. By implementing a waiting period between detecting the peak and discharging the energy storage in which characteristics of the peak are observed, a peak mitigation system can lengthen the effective discharge duration of the energy storage system and prevent unmitigated plateaus from appearing. For example, when a consumption plateau is detected, the system may discharge at a slower rate than when a spike is detected in order to prolong mitigation activities before the conclusion of the plateau. Thus otherwise-incurred demand-related utility charges can be reduced without having to increase the capacity of the mitigation system. In some cases, these processes are performed with respect to the bounds of demand-averaged time periods used to calculate demand charges.

Abstract: The electrical consumption mitigation provided by energy storage systems can be unreliable when a consumption peak lasts long enough to deplete the energy stored and the remainder of the peak is unmitigated. By implementing a waiting period between detecting the peak and discharging the energy storage in which characteristics of the peak are observed, a peak mitigation system can lengthen the effective discharge duration of the energy storage system and prevent unmitigated plateaus from appearing. For example, when a consumption plateau is detected, the system may discharge at a slower rate than when a spike is detected in order to prolong mitigation activities before the conclusion of the plateau. Thus otherwise-incurred demand-related utility charges can be reduced without having to increase the capacity of the mitigation system. In some cases, these processes are performed with respect to the bounds of demand-averaged time periods used to calculate demand charges.

Abstract: Charging service vehicles with battery and generator sources are disclosed. The service vehicle is a vehicle having electric vehicle (EV) charging equipment, removably mounted battery module(s) or a battery module connection point, and an alternator or generator transported by the vehicle. The alternator or generator is configured to provide power to the battery module or to the charging equipment. Battery modules used may be quick-disconnecting or have their discharge monitored and controlled by an onboard controller device, and in some cases are automotive SLI batteries. Some embodiments have connection points that can be configured as charging points to recharge battery modules on the vehicle or as discharging points to provide power to the EV charging equipment. These features are beneficial to extend the utility of batteries in a service vehicle, provide additional power for EV charging, and to efficiently utilize vehicle electronics and generation capability.

Abstract: Charging and discharging an energy storage device (ESD) generates heat and may prevent its temperature from dropping to unsafe levels. By monitoring and managing the charge and discharge of an ESD with respect to the periods of time in which demand charges are determined, the heating will have minimal adverse effect on demand charges. ESDs may also exchange energy in a controlled manner for heating purposes and reduce reliance on utility grid-based energy sources. ESD heating may also be made more efficient by offsetting the heating with load shedding during charging periods. Precharging the ESD while heating or preheating the ESD by charging and discharging can prevent new maximum demand levels from appearing and thereby limit increases in demand charges.

Abstract: A computer-implemented method and system of providing utility service network information for a utility service network. The method includes obtaining utility service network information from a plurality of external sources, integrally combining the utility service network information obtained from each of the plurality of external sources into and displaying the utility service network information in real-time in a global positioning map to a user via a graphical user interface, selecting, via the user, specific utility service network information of the utility service network information, to be displayed, and automatically reconfiguring the system or manually reconfiguring the utility service network via the user, as needed based on the specific utility service network information selected.

Abstract: Charging service vehicles and methods using modular batteries are disclosed. The service vehicles are vehicles having electric vehicle (EV) charging equipment, and removably mounted battery modules or battery module connection points. The battery modules are connected to the EV charging equipment as a source of electrical energy. Some embodiments disclose integrating the EV charging equipment with the vehicle, recharging modules through a distribution grid connection, the manner of discharging the batteries, modes of connecting and disconnecting the modules, the size and weight of the modules, quick-disconnectability of modules, control and monitoring of the modules and charging equipment, and/or ways of connecting modules to the vehicle.

Abstract: The electrical consumption mitigation provided by energy storage systems can be unreliable when a consumption peak lasts long enough to deplete the energy stored and the remainder of the peak is unmitigated. By implementing a waiting period between detecting the peak and discharging the energy storage in which characteristics of the peak are observed, a peak mitigation system can lengthen the effective discharge duration of the energy storage system and prevent unmitigated plateaus from appearing. For example, when a consumption plateau is detected, the system may discharge at a slower rate than when a spike is detected in order to prolong mitigation activities before the conclusion of the plateau. Thus otherwise-incurred demand-related utility charges can be reduced without having to increase the capacity of the mitigation system. In some cases, these processes are performed with respect to the bounds of demand-averaged time periods used to calculate demand charges.

Abstract: Charging and discharging an energy storage device (ESD) generates heat and may prevent its temperature from dropping to unsafe levels. By monitoring and managing the charge and discharge of an ESD with respect to the periods of time in which demand charges are determined, the heating will have minimal adverse effect on demand charges. ESDs may also exchange energy in a controlled manner for heating purposes and reduce reliance on utility grid-based energy sources. ESD heating may also be made more efficient by offsetting the heating with load shedding during charging periods. Precharging the ESD while heating or preheating the ESD by charging and discharging can prevent new maximum demand levels from appearing and thereby limit increases in demand charges.

Abstract: A utility distribution control system and method for performing distribution control of energy within a utility service network including an energy distribution network in communication with a plurality of energy resources. The energy distribution network includes a plurality of energy storage and generation devices which receive energy from at least one of the energy resources of the plurality of resources and distribute energy, and a controller which controls the plurality of energy storage and generation devices, to distribute energy.

Abstract: A computer-implemented method and system of providing utility service network information for a utility service network. The method includes obtaining utility service network information from a plurality of external sources, integrally combining the utility service network information obtained from each of the plurality of external sources into and displaying the utility service network information in real-time in a global positioning map to a user via a graphical user interface, selecting, via the user, specific utility service network information of the utility service network information, to be displayed, and automatically reconfiguring the system or manually reconfiguring the utility service network via the user, as needed based on the specific utility service network information selected.

Abstract: An apparatus and method for managing consumption of electricity of loads at a site which includes energy storage, a system controller, and load shedding ability. The system controller monitors energy consumption of the site and discharges energy into the site when consumption exceeds a maximum consumption threshold. If energy storage is depleted while consumption remains in excess of the threshold the controller may engage load shedding to prevent consumption from exceeding the maximum threshold. Additionally, the energy storage device may recharge during a peak consumption period due to load shedding reducing consumption below the maximum threshold, and the energy storage device may use this recovered energy to further mitigate the peak; in some embodiments, repetitively. Supplemental and additional load mitigation techniques may also be implemented to increase effectiveness and efficiency of the systems and methods.

Abstract: A reduced size and complexity multi-mode electric vehicle charging station is provided which allows a user to select AC and DC powerform output and may provide those outputs to connectors for charging electric vehicles. A voltage source is provided to a DC converter that then outputs to a DC bus or electrical connection. The DC bus may be accessed by DC charging equipment or a DC-AC inverter that is connected to AC charging equipment, thereby providing DC and AC charging ability. In one aspect, the multi-mode electric vehicle charging station is used in a rescue vehicle for charging stranded EVs via multiple charging standards without requiring the rescue vehicle to carry independent charging systems for each charging standard. In another aspect, the charging station is used in a stationary charging station to reduce cost and complexity of using multiple independent charging systems.

Abstract: Charging service vehicles and methods with output points and cables are disclosed. The service vehicles are vehicles having electric vehicle (EV) charging equipment and output points affixed. The output points are configured as power outputs of the charging equipment to which connectors may be attached. Output points are located on multiple sides of the vehicle and can receive charging cables to connect the charging equipment to an EV. The charging cables, and potentially extension cables, may be limited in size and weight to allow a user to reach the charging port of an EV without mechanical assistance. In some cases the vehicle may be connected to multiple EVs at once to provide charging services from multiple output points. These embodiments permit a service vehicle operator to quickly and safely reach EVs in remote roadside environments that would otherwise be inaccessible to vehicles with limited ports and fixed charging connection devices.

Abstract: Charging service vehicle networks are among the embodiments disclosed herein, including battery module-powered EV charging roadside service vehicles. Battery modules are removably mounted to the service vehicles and manually exchanged within a system of battery module storage locations. Some embodiments provide resupply vehicles for delivering battery modules between storage locations and/or service vehicles, and may be used to exchange battery modules. Controllers are used to reserve battery modules at the storage locations to ensure availability for high priority activities. Some storage locations have charging apparatus to recharge battery modules stored there, and some storage locations are repositionable mobile units.

Abstract: Charging service vehicles and methods using modular batteries are disclosed. The service vehicles are vehicles having electric vehicle (EV) charging equipment, and removably mounted battery modules or battery module connection points. The battery modules are connected to the EV charging equipment as a source of electrical energy. Some embodiments disclose integrating the EV charging equipment with the vehicle, recharging modules through a distribution grid connection, the manner of discharging the batteries, modes of connecting and disconnecting the modules, the size and weight of the modules, quick-disconnectability of modules, control and monitoring of the modules and charging equipment, and/or ways of connecting modules to the vehicle.