Your search keyword '"Thermostatically controlled loads"' showing total 203 results

201. Design and Modelling of Thermostatically Controlled Loads as Frequency Controlled Reserve

Author

Jacob Østergaard, C. Marcus-Moller, Zhao Xu, and Mikael Togeby

Subjects

Engineering, business.industry, Automatic frequency control, Simulation modeling, Control engineering, Thermostat, Load modelling, law.invention, Electric power system, Power system simulation, law, Load regulation, Thermostatically controlled loads, Electricity, business, Demand as frequency controlled reserve

Abstract

Using demand as frequency controlled reserve (DFR) is beneficial to power systems in many aspects. To study the impacts of this technology on power system operation, control logics and simulation models of relevant loads should be carefully developed. Two advanced control logics for using demand as reserve have been presented in this paper. Electricity loads that are applicable for the technique in practical power systems are analysed. Moreover, a simulation model of thermostatically controlled loads, which can provide frequency activated reserve by controlling their set points according to system frequency, is developed. The developed simulation model is able to represent a variety of aggregated thermostatically controlled loads, such as heaters or refrigerators. Uncertainties including customer behaviours and ambient temperature variation are also modelled. Preliminary simulation results are presented and analysed, which demonstrates the great potentials of the DFR technology.

Published

2007

202. Design and Modelling of Thermostatically Controlled Loads as Frequency Controlled Reserve

Author

Xu, Zhao, Østergaard, Jacob, Togeby, Mikael, Marcus-Møller, C., Xu, Zhao, Østergaard, Jacob, Togeby, Mikael, and Marcus-Møller, C.

Abstract

Using demand as frequency controlled reserve (DFR) is beneficial to power systems in many aspects. To study the impacts of this technology on power system operation, control logics and simulation models of relevant loads should be carefully developed. Two advanced control logics for using demand as reserve have been presented in this paper. Electricity loads that are applicable for the technique in practical power systems are analysed. Moreover, a simulation model of thermostatically controlled loads, which can provide frequency activated reserve by controlling their set points according to system frequency, is developed. The developed simulation model is able to represent a variety of aggregated thermostatically controlled loads, such as heaters or refrigerators. Uncertainties including customer behaviours and ambient temperature variation are also modelled. Preliminary simulation results are presented and analysed, which demonstrates the great potentials of the DFR technology.

Published

2007

203. A Stackelberg game approach for price response coordination of thermostatically controlled loads

Author

Wang, Peng, Zou, Suli, Wang, Xiaojuan, and Ma, Zhongjing

Subjects

thermostatically controlled loads, energy management, 020209 energy, 0202 electrical engineering, electronic engineering, information engineering, 02 engineering and technology, Stackelberg game, set-point temperature, price response

Abstract

In this paper, we study the demand response of the thermostatically controlled loads (TCLs) to control their set-point temperatures by considering the tradeoff between the electricity payment and TCL user’s comfort preference. Based upon the dynamics of the TCLs, we set up the relationship between the set-point temperature and the energy demand. Then, we define a discomfort function with respect to the associated energy demand which represents the discomfort level of the set-point temperature. More specifically, the system is equipped with a coordinator named electric energy control center (EECC) which can buy energy resources from the electricity market and sell them to TCL users. Due to the interaction between EECC and TCL users, we formulate the specific energy trading process as a one-leader multiple-follower Stackelberg game. As the main contributions of this work, we show the existence and uniqueness of the equilibrium for the underlying Stackelberg games, and develop a DR algorithm based on the so-called Backward Induction to achieve the equilibrium. Several numerical simulations are presented to verify the developed results in this work., Applied Sciences, 8 (8), ISSN:2076-3417