Abstract: An appliance is placed in a bootload mode and other operations of the appliance are powered down. Data is gathered through an appliance control module which activates the bootloader mode, and then receives the data and overwrites the remainder of the appliance controller memory. In this manner, software for an appliance is updated without having to enter the home.

Abstract: A system for reducing the peak power consumption by a refrigeration system is provided. The system comprises a first electromechanical cold control calibrated to a first temperature setpoint, a second electromechanical cold control calibrated to a second temperature setpoint, said first and second cold controls each having a setpoint selector member operatively linked such that adjustment of one results in a corresponding adjustment of the other, a DSM module responsive to demand state signals from an associated utility indicative of at least a peak demand and an off peak demand state, and a DSM switching device responsive to the DSM module and operative to selectively render one or the other of the cold controls effectively operative to control the cooling system depending upon the demand state signal.

Abstract: A system for reducing the peak power consumption in an electromechanically controlled refrigerator is provided. The system comprises a cold control device including a housing and a counter spring having at least one spring tension position corresponding to a temperature set point, a bourdon tube having a first end comprising an elastomeric diaphragm operatively associated with the counter spring, and a second end, opposite the first end, located in the compartment, wherein the counter spring is capable of providing a force against the diaphragm, and a DSM switching device operatively controlled by an associated DSM module. The DSM module is configured to receive a signal indicative of at least one of a peak or non-peak demand period of an associated utility.

Abstract: Methods and a system are disclosed for one or more appliances including a controller for managing power consumption within a household. The controller is configured to receive and process a signal indicative of one or more energy parameters of an associated energy utility, including at least a peak demand period or an off-peak demand period. A generated serial number is obtained from an original serial number of the appliance or controller, which is configured for a signal to communicate to the appliance within a population and command the appliance to operate in an energy savings mode and a normal mode at various time periods. The generated serial number (GSN) is used to segregate a total population into segments to provide granularity in assigning DR activations and deactivations based upon the GSN.

Abstract: An energy management system for an appliance comprising an interface to receive a schedule having an off-peak time segment and an on-peak time segment; a control to determine an operation to be performed by the appliance; a mode selecting device to select between an energy management mode and an immediate start mode; and a controller connected to the interface, the control, and the mode selecting device. The controller is arranged such that upon selection of the energy management mode, the controller initiates the operation when a majority of the energy consumption of the operation is within the off-peak time segment; and upon selection of the immediate start mode, the controller initiates the operation immediately.

Abstract: A home energy management system for providing energy usage and cost projections to a user related to management of a home network is provided. The system comprises a central controller coupled to at least one energy consuming device, the central controller being configured to receive energy consumption data from the at least one energy consuming device, and a user interface comprising a display coupled to the central controller to receive user input data and provide the user with information. The central controller is further configured to use the energy consumption data and user input data to provide the user with one or more of future energy consumption projections, energy saving suggestions, and cost saving suggestion.

Abstract: An appliance for drying or warming associated laundry items includes a housing having a wall forming a stationary cavity dimensioned to receive the associated laundry items. At least one article support member is preferably contained within the cavity. A heater increases a temperature of associated air within the cavity and a fan circulates the heated air within the cavity. A vent is dimensioned to allow air to exit the housing cavity, and a controller regulates circulation of the associated heated air within the cavity.

Abstract: A smart load switch or smart plug incorporates a built-in circuit that can monitor a physical variable condition and compare that sensed condition to data stored in a memory. A controller receives input data from the measuring device, compares the data to the reference data in memory, and selectively controls the on/off condition of a switch and thus the device that is plugged into the switch.

Abstract: An energy saving defrost control system for reducing power consumption of an electromechanically controlled refrigerator is provided. The system includes a defrost timer adapted to control a compressor according to an established run time, a defrost heater control operatively connected to the defrost timer and configured to activate a defrost heater in response to a timeout by the defrost timer, a DSM module responsive to demand state signals from an associated utility indicative of at least a peak demand and off peak demand state, and a time delay latching relay having a timer and configured to switch to one of a low position and a high position based on the demand state signal.

Abstract: A hydrocarbon-fueled hot water heater for supplying hot water includes a cold water inlet, a hot water outlet, a selectively activatable burner for applying heat to a volume of water between the inlet and the outlet, a sensor for sensing activation of the at least one burner, and a communication interface for communicating data corresponding to the activation of the at least one burner to a processor configured to multiply the amount of time the burner is activated by a known value corresponding to a flow rate of the burner to estimate an amount of fuel consumed by the hydrocarbon-fueled hot water heater. Other devices and methods of submetering hydrocarbon fueled water heaters are also included.

Abstract: A refrigerated appliance such as a refrigerator receives a demand response signal indicating a peak demand period and operates the refrigerator in an energy savings mode by disabling an anti-sweat heater. Sensors monitor ambient temperature and humidity, and the dry bulb temperature of a preselected region where incipient moisture would likely form. Data from the sensors is sent to a controller which calculates ambient dew point and compares the dry bulb temperature of the preselected region with the calculated dew point to enable the anti-sweat heater during the peak demand period and prevent incipient formation of moisture.

Abstract: An appliance such as a refrigerator receives a demand response signal indicating a peak demand period and operates the refrigerator in an energy savings mode by disabling an anti-sweat heater. A sensor on an external surface of the refrigerator enables the anti-sweat heater during the peak demand period if moisture is detected by the sensor. A preselected location can be defined where incipient moisture would form such as reducing the amount of insulation in this location. By forming a depression in the location and using an impedance-type sensor, moisture can be easily detected. The sensor signal is sent to the controller which then activates the anti-sweat heater to remove the moisture.

Abstract: A system for reducing the peak power consumption in an electromechanically controlled refrigerator is provided. The system comprises a cold control device including a housing and a counter spring having at least one spring tension position corresponding to a temperature set point, a bourdon tube having a first end comprising an elastomeric diaphragm operatively associated with the counter spring, and a second end, opposite the first end, located in the compartment, wherein the counter spring is capable of providing a force against the diaphragm, and a DSM switching device operatively controlled by an associated DSM module. The DSM module is configured to receive a signal indicative of at least one of a peak or non-peak demand period of an associated utility.

Abstract: An apparatus and methods are disclosed for controlling load shedding and payback spikes of a population by segregating the population into subsets based on predicted energy consumption usage and peak load profiles. Subset populations respond independently from another based on a communication message sent to the population. Each subset population of homes with one or more energy consuming devices responds based on a generated value generated from a randomizing distribution routine.

Abstract: A refrigerator comprises a fresh food compartment and a freezer compartment and one or more power consuming features/functions including a refrigeration system for cooling the fresh food compartment and the freezer compartment. A controller is operatively connected to the one or more power consuming features/functions. The controller is configured to receive and process a signal indicative of current state of an associated energy supplying utility. The controller adjusts the temperature of the refrigerator and/or freezer from a normal setting to a higher point during an energy saving mode and then back to a normal temperature. The transition between low and high is controlled to reduce energy consumption.

Abstract: A household energy management system is provided comprising a controller for managing power consumption of multiple devices within a household wherein the controller monitors energy usage data from a utility. The system further provides a utility meter for measuring an amount of energy usage by the household and a user interface through which a user can enter a parameter of the energy usage. The system yet further provides a local generator for generating energy for one or more of the energy consuming devices wherein the controller initiates the generator and changes at least some of the energy usage from the utility to the local generator when the energy usage level is within a predetermined percentage range of the parameter.

Abstract: A system and method for controlling operation of a hybrid heating system that includes a heat pump and a gas heater is disclosed. Peak demand or pricing information is received from gas and electric utilities, and outdoor ambient temperature data is also fed to a smart hybrid thermostat. A controller processes this data and calculates overall efficiency of operating the heat pump versus the gas heater by accessing stored performance data relating to the heat pump in memory.

Abstract: Apparatus and method for managing energy of a home or other structure are disclosed. The thermal characteristics of a home are determined based on variables such as inside temperatures, outside temperatures, setpoint temperatures, and duty cycles over time. Response time constants of the home are calculated and used to generate at least one transfer function or table to predict and control energy efficiency versus comfort within the home. A user is presented with variations of cost and power consumptions to choose from and be factored into the transfer function.

Abstract: Methods and a system are disclosed for one or more appliances including a controller for managing power consumption within a household. The controller is configured to receive and process a signal indicative of one or more energy parameters of an associated energy utility, including at least a peak demand period or an off-peak demand period. A generated serial number is obtained from an original serial number of the appliance or controller, which is configured for a signal to communicate to the appliance within a population and command the appliance to operate in an energy savings mode and a normal mode at various time periods. The generated serial number (GSN) is used to segregate a total population into segments to provide granularity in assigning DR activations and deactivations based upon the GSN.

Abstract: An appliance for conditioning air of an associated room and an associated method for controlling an air conditioner are disclosed, the controller selectively adjusting operation of the air conditioning appliance based on historical operating data. The controller adjusts a set-point of the appliance for a preselected period of time in response to the historical operating data of the appliance when the appliance operates in an energy savings mode. In one arrangement, the controller is configured to receive and process data regarding whether the appliance has been operating over a predetermined time period before a utility demand state signal is received. The controller is configured to receive and process data relating to similar time periods of operation, and more particularly may include receiving data from the last two consecutive days where similar time periods of those days are analyzed. The controller may be configured to receive and process data relating to the rate of change in the temperature.