The present application provides an optimized regulating and controlling method and system for an integrated electricity and heat system with heat pumps, relating to the technical field of energy operation. According to the present application, regulating and controlling can be performed by regarding units as different agents and taking maximization of the self-interest of each agent as the objective, so that the load demands of heat and power consumers can be met, and each unit agent can be satisfied with its payoff to the greatest extent. The method includes: S1. establishing a composition and structure framework of the integrated electricity and heat system with heat pumps, and establishing an output model of each unit; S2. establishing a payoff function model of each unit in the integrated electricity and heat system with heat pumps; S3. establishing a non-cooperative game model of the integrated electricity and heat system with heat pumps; and S4. solving the game model by using a particle swarm optimization algorithm to obtain a heat and power scheduling optimization scheme of each unit. The technical solution provided by the present application is applicable to a process of regulating an integrated electricity and heat system with heat pumps.

An inductive stove appliance that includes a stove housing; a minimum of three cooking zones, with at least two of the cooking zones comprising induction coils; an electric oven; a set of cooktop and oven controls configured for operation of the inductive stove appliance, including operation of the minimum of three cooking zones and the electric oven; a power cord with a plug configured to couple with a standard 120V, 15A-30A, electrical power receptacle of a power distribution system; and a battery system disposed within the stove housing of the inductive stove appliance with one or more batteries integrated into the stove housing configured to: store power obtained from the power cord with the plug coupled with the electrical power receptacle of the power distribution system, power the minimum of three cooking zones of the inductive stove appliance, and power the electric oven of the inductive stove appliance.

An inductive stove appliance that includes a stove housing; a minimum of three cooking zones, with at least two of the cooking zones comprising induction coils; an electric oven; a set of cooktop and oven controls configured for operation of the inductive stove appliance, including operation of the minimum of three cooking zones and the electric oven; a power cord with a plug configured to couple with a standard 120V, 15A-30A, electrical power receptacle of a power distribution system; and a battery system disposed within the stove housing of the inductive stove appliance with one or more batteries integrated into the stove housing configured to: store power obtained from the power cord with the plug coupled with the electrical power receptacle of the power distribution system, power the minimum of three cooking zones of the inductive stove appliance, and power the electric oven of the inductive stove appliance.

A power dispatch system and a power dispatch method are provided. When a time span of the historical electricity usage data is greater than or equal to a preset value, an upper bound is determine according to the historical electricity usage data, the expected power demand and a dispatchable power. When the time span is less than the preset value, the upper and lower bounds are determined according to the historical electricity usage data. When an actual power demand is greater than the upper bound, the power system receives an amount of power equal to the upper bound, and the energy storage unit discharges to supplement the power required by the power system. When the actual power demand is less than the lower bound, the power system receives an amount of power equal to the lower bound, and the energy storage unit receives the surplus power for charging.

A thermal energy storage (TES) system converts variable renewable electricity (VRE) to continuous heat at over 900 C. Intermittent electrical energy heats a solid medium. Heat from the solid medium is delivered continuously on demand. Heat delivery via flowing gas establishes a thermocline which maintains high outlet temperature throughout discharge. The delivered heat which may be used for processes including power generation and cogeneration. The TES system is configured to include control system components that reduce thermal losses associated with component inefficiency.

Methods and systems describe multicasting the messages over a broadcast medium (e.g., a TV network). In particular, the methods and systems recite the use of Advanced Television Systems Committee (ATSC) 3.0, a new broadcast television transmission standard in the United States. Using ATSC 3.0, the methods and systems can disseminate messages to all the electrical equipment.

In accordance with at least one aspect of the present disclosure, there is provided a method for controlling power in an aircraft. The method includes, monitoring an electric energy storage module electrically connected to an electrical bus for an exceedance of a first current limit and monitoring a generator module connected to the electrical bus for an exceedance of a second current limit. If the current limit of either of the electric energy storage module or the generator module is exceeded by a predetermined exceedance amount, the method includes reducing a power consumption for an electric machine by a predetermined bias until the exceedance of the electrical energy storage and the exceedance of the generator module are both less than or equal to zero.