Abstract: A system for managing electric energy exchange devices is disclosed. The system comprises a processor and a memory. The processor is configured to receive a set of predefined parameters for electric energy exchange a vehicle using an electric energy exchange device for a time increment. The processor is further configured to receive a set of transaction specific parameters. The processor is configured to determine a price for electric energy exchange based at least in part on the set of predefined parameters and the set of transaction specific parameters. The memory is coupled to the processor and configured to provide the processor with instructions.

Abstract: Systems and methods are described that allow a Programmable Logic Controller (PLC) to receive Demand Response (DR) data and process the data in a PLC Function Block (FB). Embodiments provide a PLC demand response FB that solicits DR data and a demand response load manager FB that compares the DR data with predetermined demand constraints corresponding to electrical equipment. The demand constraints provide energy consumption strategies for buildings and factories.

Abstract: A system for providing demand response services relative to a resource. Demand response information may be conveyed by a provider of the resource to demand-response logic. The logic may translate the demand response information into one of a pre-defined finite amount or number of demand response levels. These levels may be translated to device states, and in turn the device states may be translated to device commands. The translations may be based on rules designed to effect a resource usage scenario. The rules may be easily changed. The commands may be provided to devices at one or more facilities. The devices may control loads, which consume the resource, in accordance with the device commands. The devices may also provide information, such as conditions and resource consumption, relative to the facilities to the provider of the resource. The commands and information may be conveyed via local and wide communication networks.

Abstract: A power control system/method implementing Internet based access to hybrid home automation networks is disclosed. The system utilizes a smart gateway power controller (SGPC) to selectively switch an AC power source to a load device under control of local or remote network commands that may be routed through a variety of network interfaces and protocols present within home or other structure-local communications network. SGPC configurations may be nested within a home automation network to permit separation of control for load devices within a common home automation environment. Present invention methods may include routing protocols between disparate home automation networks as well as remote access protocols that permit control of disparate home automation networks via the Internet using a wide variety of remote access interfaces including mobile devices, tablet computers, laptops, desktop computers, and the like.

Abstract: Privacy-preserving metering with low overhead is described. In an embodiment consumption of a resource such as electricity, car insurance, cloud computing resources is monitored by a meter and bills are created in a manner which preserves privacy of a customer but at the same reduces bandwidth use between a meter and a provider of the resource. For example, fine grained meter readings which describe customer behavior are kept confidential without needing to send large cryptographic commitments to meter readings from a meter to a provider. In an example, meter readings are encrypted and sent from a meter to a provider who is unable to decrypt the readings. In examples a cryptographic signature is generated to commitments to the meter readings and only the signature is sent to a provider thus reducing bandwidth. For example, a customer device is able to regenerate the commitments using the signature.

Abstract: A method of reducing electricity usage during peak demand periods includes the steps of establishing predetermined load reduction criteria representative of a desire by a power provider to reduce loading on an electricity supply grid, and coordinating with a facility having lighting equipment to permit the power provider to turn-off one or more of the lighting equipment by sending instructions to a master controller at the facility in response to the predetermined load reduction criteria, and establishing a list of lighting equipment to be turned-off in response to the instructions, and configuring the master controller to send an override control signal to the lighting equipment to implement the instructions, and configuring the lighting equipment to send a response signal to the master controller providing a status of the lighting equipment.

Abstract: Methods for controlling irrigation devices coupled to and receiving operational power from a multi-wire interface of an irrigation system, and related irrigation devices, are provided. In some forms, the methods define initialization of the irrigation devices having received operational power, including the timing of charging, discharging and recharging of the irrigation devices in order to provide a time staggered recharging of the energy reserves of the irrigation devices. In some forms, the methods involve the use of different delay periods at different irrigation devices coupled to irrigation valves to place multiple irrigation valves into a known position. In some embodiments, these methods spread out the usage of charging energy drawn from the multi-wire interface by the irrigation devices coupled thereto to reduce inrush currents.

Abstract: A method and apparatus for controlling circuits in an electrical power grid. Parameters in the circuits are monitored. Each circuit comprises nodes in the electrical power grid and a number of lines connected to the nodes in the electrical power grid. The number of lines is configured to carry electrical power. The nodes control the electrical power in the number of lines. A number of agent processes associated with the nodes communicate with each other using a communications network, configure the nodes in the electrical power grid into a number of circuits, and control a delivery of the electrical power through the number of circuits to loads. A determination is made as to whether to make a change to the number of circuits based on the number of parameters and a policy. The circuits are changed using the policy in response to a determination to make the change.

Abstract: A control device that controls a plurality of air conditioners includes a data memory section for storing performance model data representing the relationship between air conditioning capability and power consumption for each of the plurality of air conditioners. An overall air conditioning load calculating section calculates an overall load that is the sum of air conditioning loads of the plurality of air-conditioning apparatuses. An air conditioning capability allocation calculating section an air conditioning capability for each of the plurality of air conditioners on the basis of the performance model data and the overall load so that the sum of the air conditioning capability of the plurality of air conditioners is the overall load and the sum of the power consumption of the plurality of air conditioners is minimum. A control signal section sends a control signal related to the air conditioning capability to each of the plurality of air conditioners.

Abstract: An electrical equipment management system includes: a total electrical energy information acquiring unit disposed in a building having a plurality of sections, the unit to acquire total electrical energy information indicative of total electrical energy consumed in a whole of the sections; an individual electrical energy acquiring unit to acquire individual electrical energy information indicative of electrical energy consumption in each section depending on the total electrical energy; and a control information output unit to output control information for controlling operation of electrical equipment disposed in the sections so that electrical energy consumption thereof does not exceed an upper limit, in accordance with difference between the individual electrical energy information and upper limit information indicative of an upper limit of electrical energy consumption for each predetermined period for each of the sections as well as remaining period information indicative of a remaining period before a l

Abstract: The invention provides systems and methods for control of power charge/discharge from energy storage system. The invention also provides for power monitoring and management. A smart charge system may include a system sensor, one or more energy storage units, and a controller, which may receive information about the power demand, power provided by an electricity provider, and charge/discharge information from an energy storage unit. The information received may all be time synchronized in relation to a time based reference. The controller may provide instructions to an energy storage unit at a rapid rate.

Abstract: A pre-programmed energy saving ballast or driver is presented, having a pre-defined energy profile to which the output power is controlled in accordance with the current time ascertained from the input power connection via simplex clock information or from received broadcast time signals, and which allows a user to select from a number of pre-programmed profiles and/or to modify and store user-defined energy profiles.

Abstract: A method and system is disclosed that includes a controller that determines a sleep schedule for reduced function devices on a home network. The devices have various sleep schedules in which to operate in an active state or a reduced function state. The controller determines the different schedules by sending communication messages to each device via a communication module. A timer is used to determine a sleep schedule for reduced function devices (RFDs) on the network. The sleep schedule is used to monitor when the devices are communicating on the network and are no longer able to communicate with the controller.

Abstract: Method for distributing an energy flow to a cluster of a plurality of devices taking into account constraints relating to the energy to be delivered to the devices, comprising the steps of: A. gathering flexibility information of the respective devices in the cluster, combining the flexibility information of the devices of the cluster into flexibility information for the cluster, B. determining accumulated energy to be delivered in function of time over the predetermined period of time, C. supplying the determined accumulated energy to the cluster by obtaining, from the flow of energy, power in function of time based on the determined accumulated energy to be delivered in function of time, determining priority for power for all devices in the cluster and distributing the obtained power among the devices of the cluster.

Abstract: Techniques for controlling energy generation and/or storage systems. In one embodiment, a method is provided that can comprise receiving from a control server a plurality of schedules for controlling the charging and discharging of an energy storage device, where each schedule corresponds to a function that takes as input one or more input parameters and returns as output an output parameter corresponding to a power level for the energy storage device. The method can further comprise determining relative priorities for the plurality of schedules and controlling charging/discharging of the energy storage device based on the plurality of schedules and their relative priorities.

Abstract: A home energy management system simplifies the process of enabling and executing the Sabbath mode and similar operating modes on household devices. A central location, or central node device, is provided which enables the end user to selectively modify operation of the household devices, e.g., from a normal operating mode to the Sabbath mode.

Abstract: A control system (300) allows recognized standard premise electrical outlets, for example NEMA, CEE and BS, among others to be remotely monitored and/or controlled, for example, to intelligently execute blackouts or brownouts or to otherwise remotely control electrical devices. The system (300) includes a number of smart receptacles (302) that communicate with a local controller (304), e.g., via power lines using the TCP/IP protocol. The local controller (304), in turn, communicates with a remote controller (308) via the internet.

Abstract: Systems and methods are provided that integrate a modular load management solution within a general control architecture. One or more load modules deployed within a controller act as interlocks to energy consuming field devices or machines fed by an energy distribution system within a facility. One or more feeder modules deployed within the controller collect energy supply data from an energy source or feeder on the energy distribution system. The load and feeder modules publish their energy demand and supply data to a virtual energy bus, which facilitates exchange of energy data between the load and feeder modules. The load modules, feeder modules, and virtual energy bus generate multiple views of the facility's overall energy supply and demand status based on the energy data shared between the components, and perform automated load management for the energy distribution system based on the collected data.

Abstract: A microwave oven comprises a cooking cavity and a RF generation module configured to deliver microwave energy into the cooking cavity. A controller is operatively associated with the RF generation module. The controller receives and processes a signal indicative of current state of an associated energy supplying utility for determining whether to operate the microwave oven in one of a normal operating mode and an energy savings mode in response to the received signal. The controller is configured to at least temporarily block the signal when the RF generation module is activated if a frequency of the signal is at least partially degraded by a frequency of the RF generation module.

Abstract: An appliance network having a first networked appliance, an energy controller, at least one of a smart dimmer and smart adapter, and a communication network coupling the first networked appliance, energy controller, and the at least one of the smart dimmer and smart adapter for communication therebetween.

Abstract: A demand response system includes a mobile application of a mobile device that is configured to initiate altering an operating condition of a network device disposed at a site using location based services. A demand response application interface module is configured to enable access between a utility company and the network device to communicate energy management information therebetween. The network device is configured to be remotely altered by each of the demand response application interface module and the mobile application separately based on the location based services and the energy management information. A method of managing a demand response system includes detecting a user being disposed away from a site, detecting energy management information from a utility company associated with the site, and initiating a reduction in energy use at the site in response to the relative location of the user and the energy management information.

Abstract: A method and system for monitoring an appliance is disclosed. The method includes establishing a wireless communication connection between a communication module in an appliance and a communication network, transmitting operational data in real-time from the appliance to an external monitoring system over the communication network, determining a status of a component of the appliance from the real-time operational data, and if a failure mode of the component is detected, initiating a service protocol corresponding to the component.

Abstract: A method for managing an energy consuming load in a group of energy consuming loads. The method includes generating and compiling sets of load state data from the load and other loads, making an enablement state decision for the load using the compiled sets of data, wherein the enablement state decision reflects either a load enabled or load disabled state, and implementing the enablement state decision for the load. An apparatus for managing an energy consuming load in a group of energy consuming loads, including a transmitter for transmitting the set of load state data from the load, a receiver for receiving sets of load state data from other loads, a processor for processing the load state data to make an enablement state decision, and a controller for implementing the decision. A computer readable medium provides computer readable instructions for directing the processor, wherein the instructions perform the method.

Abstract: A network system is provided. The network includes: at least one component selected from an energy receiving unit receiving energy and an energy management unit managing the energy receiving unit. The energy receiving unit or the energy management unit receives energy rate related information; an energy usage amount or a usage rate of when the component is controlled on the basis of at least the energy rate related information is less than that of when the component is controlled without the basis of at least energy rate related information; and if the energy rate related information is high cost information, a function of one component constituting the energy receiving unit is limited and a function of another component constituting the energy receiving unit is performed.

Abstract: A device and method to automatically control timing of outside lighting are achieved. An ephemeris program and a calendar are loaded into memory on a timing device. Power is applied to the device wherein a GPS circuit on the device is energized, and Greenwich Mean Time (GMT), Current Day (CD), and physical location of the device are determined from satellite signals through an antenna or alternately from a repeater circuit or a key fob type device. GMT and CD that are retrieved are stored in memory. Lighting on and off times are calculated by the ephemeris program based on physical location, the calendar, GMT, CD, and the user selected distance of the sun below the horizon. Lights are turned on and off based on the calculated on and off times.

Abstract: Electronic supervision may be provided. First, a stock number may be sent to a database server. The stock number may correspond to an electrical cable. In response to sending the database server the stock number, specification information corresponding to the product may be received from a database stored on the database server. The specification information may be, for an electrical cable, a number of wires, a weight per thousand feet, and a diameter. Next, product production may be monitored to determine faults occurring during production. Monitoring the production may include displaying a data monitoring screen to production personnel. The data monitoring screen may provide data regarding the product and product comparison against a standard maintained within the database for the product. Fault data corresponding to the determined faults occurring during the production may be saved to the database.

Abstract: Electric vehicle charging stations are coupled with a circuit sharing controller. Multiple electric vehicle charging stations are wired on the same electrical circuit. The circuit sharing controller implements a circuit sharing process that dynamically allocates electric current to charging stations on the same electrical circuit such that the capacity of the electrical circuit is not exceeded while permitting each of those charging stations to draw electric current through that electrical circuit for at least some amount of time.

Abstract: The HEMS of each consumer transmits the amount of surplus electricity that is expected by to be generated by a PV system, and/or the amount of electric power that is needed by a controllable load, in a predetermined time slot on a predetermined date, to a server apparatus. The server apparatus, based on the notified amount of surplus electricity and the amount of electric power that is needed by the controllable load, combines a first consumer and a second consumer so that the amount of electric power needed by the controllable load will be equal to or greater than the amount of surplus electricity. Then, under the control the HEMS of the second consumer, the surplus electricity that is generated by the first consumer is consumed by each controllable load.

Abstract: Aspects of the present invention are related to systems, methods and apparatus for monitoring and controlling energy usage. Alert notifications may be generated based on a current power status of an energy-consuming device and location information of a mobile device associated with the energy-consuming device.

Abstract: A method for transmission network control, the transmission network being configured for use in providing electricity from a generator to an end user, the method including receiving a sensitivity parameter, identifying a switchable set of switches within the transmission network using the sensitivity parameter, determining a candidate switch from the switchable set to change a corresponding state, wherein the state can be changed from open to closed and closed to open, determining a proposed change of state of the candidate switch, updating an optimal power flow (OPF) problem as a function of the candidate switch and the proposed change of state, determining and storing in a memory a solution to the updated OPF problem, generating an updated sensitivity parameter based on the stored solution to the updated OPF problem, and determining, using the updated sensitivity parameter, if the stored solution to the updated OPF problem meets a predetermined criterion.

Abstract: An apparatus including a network operations center and a first control node. The network operations center provides configuration data to the system of energy consuming devices. The first control node coupled to the network operations center and a second control node via a network. The first control node has a node processor and a global schedule module. The node processor operates a first energy consuming device to maintain a first local environment. The global schedule module is coupled to the first node processor, and coordinates run times for the first energy consuming device and a second energy consuming device based on a replica copy of a global run time schedule disposed within the first and second control nodes, an adjusted first descriptor set characterizing the first local environment, an adjusted second descriptor set characterizing a second local environment, and the configuration data provided by the network operations center.

Abstract: An energy supply system includes: an energy supply device configured to supply electric power and/or heat; and a controller configured to set a first maximum operation time of a first specified period including a plurality of second specified periods, the first maximum operation time being an upper limit of an operation time of the energy supply device in the first specified period; calculate and set a second target maximum operation time of each of the second specified periods of the first specified period such that the operation time of the energy supply device in the first specified period does not exceed the first maximum operation time, the second target maximum operation time being a target value of an upper limit of the operation time of the energy supply device in the second specified period; and reconfigure the second target maximum operation time of a future second specified period of a certain first specified period based on a time in which the energy supply device has been actually operated in a p

Abstract: An apparatus for controlling peak demand of a system of energy consuming devices, including a first control node coupled to a second control node via a demand coordination network. The first control node has a node processor and a global schedule module. The node processor is coupled to a first energy consuming device, and operates the first energy consuming device within an acceptable operating margin to maintain a first local environment by cycling on and off. The global schedule module is coupled to the first node processor, and coordinates run times for the first energy consuming device and a second energy consuming device, where the coordination is based on a replica copy of a global run time schedule disposed within the first and second control nodes, an adjusted first descriptor set characterizing the first local environment, and an adjusted second descriptor set characterizing a second local environment.

Abstract: An apparatus including a monitor node and a first control node. The monitor node determines and broadcasts whether a non-system device is consuming an energy resource over a network. The first control node coupled to the monitor node and a second control node via the network. The first control node has a node processor and a global schedule module. The node processor operates a first energy consuming device to maintain a first local environment. The global schedule module is coupled to the first node processor, and coordinates run times for the first energy consuming device and a second energy consuming device based on a replica copy of a global run time schedule disposed within the first and second control nodes, an adjusted first descriptor set characterizing the first local environment, an adjusted second descriptor set characterizing a second local environment, and energy consumption data broadcast by the monitor node.

Abstract: Data comprising a request specifying a desired change in electrical load for a defined period of time is received. The electrical load is associated with a plurality of resources under control of resource agents and on a utility grid. Available capacity of resources within the control of each resource agent over the defined period of time is determined. Each available capacity is determined at least using a resource load model. Using the determined available capacity of resources over the defined period of time, resource scheduling instructions are calculated for a subset of resources. The resource scheduling instructions satisfy the desired change in electrical load of the request. Data characterizing the resource scheduling instructions is provided. Related systems, apparatus, methods, and articles are also described.

Abstract: In a method for managing energy demand in an infrastructure, a coefficient of performance (COP) of the infrastructure as a function of time is determined. The COP is a measure of efficiency of the infrastructure. In addition, an energy demand on the infrastructure as a function of time is determined and an energy demand schedule for the infrastructure that temporally reallocates the energy demand based upon the determined COP of the infrastructure is determined.

Abstract: A dishwasher includes a tub having a door that provides access to the tub. The door has a handle which extends a top surface of the door beyond a front surface of the door. A touchscreen panel is mounted to the top surface of a door to provide a user interface. The user interface includes a carrousel of icons via which a user may select a wash cycle. The user interface further includes a programmed delay interface via which a user may specify a desired start time and/or stop time for the wash cycle. The user interface may further provide the user with usage guidance to aid the user in the usage of the dishwasher.

Abstract: A system and method of operating an energy data management and control system has a first communication network to transmit and receive data to and from a user interface, a second communication network to transmit and receive data to and from a Utility company, and a third communication network to access data from and provide data to accessories within a home. The system reformats the data from any of the first, second and third communication networks for communication with another of the first, second and third communication networks, wherein at least one of the communication networks operate on a protocol different from another one of the communications networks. The data defines various operations of the system.

Abstract: Methods and arrangements for load-shifting time deferrable devices. An electrical load scheduling mechanism is provided, and this is placed in communication with an appliance. Electrical grid load conditions are assessed, and delivery of electrical power to the appliance is scheduled via the electrical load scheduling mechanism.

Abstract: A method for managing an energy consuming load in a group of energy consuming loads and a method for managing the group of energy consuming loads. The method includes generating sets of load state data from the loads, making enablement state decisions for one or more loads using the sets of load state data, and implementing the enablement state decisions. Each of the enablement state decisions reflects an enablement state of a load, wherein the enablement state is either a load enabled state where the load is capable of operating even when the load is not actually operating or a load disabled state where the load is not capable of operating. A computer readable medium may include computer readable instructions for directing a processor to perform the methods and make the enablement state decision. Further, an apparatus comprised of a processor may be programmed to perform the methods.

Abstract: A power intervening and management panel has a low voltage power supply electrically coupled to a low voltage circuit, a power module array having a plurality of power contactor modules where each has a power contactor with a power load input and a power load output switchable between a closed and an open position and a low voltage switch operably connected thereto for switching between the closed and the open position, a low voltage signal relay module for transmitting a low voltage output signal to one of a direct digital controller and a digital timer, and an enclosure containing the low voltage power supply, the power module array and the low voltage signal relay module.

Abstract: A motor control center comprises a plurality of bays in which switchgear components, circuit protective components, automation components and power electronic components are disposed for driving motors and other loads. Network optical conductors are routed through one or more wireways adjacent to the bays. Distribution nodes are coupled to the conductors and are interconnected with respective network terminals within the bays. Components within individual bays for which EtherNet and/or Internet connectivity is desired are coupled to the network terminals. The conductors may comprise plastic optical fibers and may be designed to operate in the relatively high voltage environment of the motor control center bays.

Abstract: A system includes a cooling system having a cooling fluid for cooling an engine and a radiator fan motor; a dynamic braking system configured to supply electrical energy to the fan motor during a braking event; and a controller that is operable to direct the electrical energy from the dynamic braking system to the fan motor to cool the coolant to a predetermined minimum threshold temperature. A method includes switching a vehicle thermal management system from a first mode of operation in which the coolant is maintained at a steady operating temperature to a second mode of operation in which the coolant is cooled to a minimum threshold temperature.

Abstract: An approach is provided that prints print jobs based on energy demand data. The print job manager, which is a software application running on an information handling system receives a print request, the print request including a print job. The print job manager retrieves energy demand data. The energy demand data corresponds to a power grid that is a power source for a printer accessible from the information handling system. If the energy demand data indicates a a non-elevated energy demand, then the print job is printed on the printer. On the other hand, if the energy demand data indicates an elevated energy demand, then the print request is stored in a storage and the process waits until the energy demand is not elevated, at which time the print job is printed on the printer.

Abstract: A system and method of managing energy use in a home, and more particularly to energy management of household consumer appliances, are provided. Existing appliances can be modified with add-on features or modules, and likewise new energy saving features and functions can be incorporated into new appliances. Communication among a home energy manager, an appliance, and a utility meter measures energy usage and/or a local generator controls operation of various appliances such as a refrigerator, washer, dryer, oven/range, microwave oven, dishwasher, HVAC system hot water heater, and the like.

Abstract: An energy management system manages energy consumption of managed device(s) disposed to receive energy via a meter connected to an energy supply, the energy supply. A system controller has a computer processor that instructs the managed device(s) to employ an operational mode based on the priority, the energy need, the demand state, and whether the energy consumption rate of the managed device(s) exceeds energy available from at least one of the external energy source and internal energy source.

Abstract: System, method, and computer-executable instructions for use in operating one or more energy consuming devices. A load shedding schedule and a load shedding override schedule that is associated with an energy consuming device are determined The energy consuming device is enabled during any portion of the load shedding schedule that coincides with the load shedding override schedule. The energy consuming device is disabled during any portion of the load shedding schedule that does not coincide with the load shedding override schedule.

Abstract: The invention consists of an electrical circuit having an internal CPU with clock, and means for switching external loads. By means of the CPU, clock, and possibly internal lookup tables, times during which certain circuits are to be switched off or on are determined. For example the CPU may be programmed to determine the time of the Sabbath onset each week, this time in fact shifting with the seasons as it is linked to the time of sunset. By use of the switching means (which may be implemented in the form of relays for instance) appliances such as lights, heaters and the like may be switched on or off for the duration of various events such as Sabbath, holidays, and the like, in accordance with yearly or multi-year calendars.

Abstract: An electric appliance and a control method thereof are disclosed. The electric appliance includes a communication device connected with a smart grid net to recognize electric power information including power-rate information for each time period, a sensing device configured to sense a predetermined operation mode and an operation state according to the operation mode, and a control device configured to implement power-saving operation based on the received electric power information and the state information sensed by the sensing device.

Abstract: According to an aspect of the disclosure, an apparatus includes a processor operable to manage energy use at a site wherein the processor is configured to detect a user interaction with the apparatus and create a personalized schedule automatically in response to the user interaction. The apparatus can also include a first profile accessible to the processor, wherein the first profile includes a first personalized schedule, and a second profile accessible to the processor, wherein the second profile is different from the first profile and includes a second personalized schedule. In addition, the processor can be configured to determine when to use the first profile or the second profile, initiate an outgoing message using the first or second personalized schedule, and update the first or second profile in response to a user interaction with an interface of the apparatus during use of the first or second personalized schedule.