MPC-Based Appliance Scheduling for Residential Building Energy Management Controller

This paper proposes an appliance scheduling scheme for residential building energy management controllers, by taking advantage of the time-varying retail pricing enabled by the two-way communication infrastructure of the smart grid. Finite-horizon scheduling optimization problems are formulated to exploit operational flexibilities of thermal and non-thermal appliances using a model predictive control (MPC) method which incorporates both forecasts and newly updated information. For thermal appliance scheduling, the thermal mass of the building, which serves as thermal storage, is integrated into the optimization problem by modeling the thermodynamics of rooms in a building as constraints. Within the comfort range modeled by the predicted mean vote (PMV) index, thermal appliances are scheduled smartly together with thermal mass storage to hedge against high prices and make use of low-price time periods. For non-thermal appliance scheduling, in which delay and/or power consumption flexibilities are available, operation dependence of inter-appliance and intra-appliance is modeled to further exploit the price variation. Simulation results show that customers have notable energy cost savings on their electricity bills with time-varying pricing. The impact of customers' preferences of appliances usage on energy cost savings is also evaluated.

[1]  Jason Brown,et al.  LESSONS FROM AN ADVANCED BUILDING SIMULATION COURSE , 2008 .

[2]  J. Contreras,et al.  ARIMA Models to Predict Next-Day Electricity Prices , 2002, IEEE Power Engineering Review.

[3]  Z. Tan,et al.  Day-ahead electricity price forecasting using wavelet transform combined with ARIMA and GARCH models , 2010 .

[4]  Rongxin Yin Study on Auto-DR and Pre-Cooling of Commercial Buildings with Thermal Mass in California , 2010 .

[5]  Vincent W. S. Wong,et al.  Autonomous Demand-Side Management Based on Game-Theoretic Energy Consumption Scheduling for the Future Smart Grid , 2010, IEEE Transactions on Smart Grid.

[6]  Manfred Morari,et al.  Reducing peak electricity demand in building climate control using real-time pricing and model predictive control , 2010, 49th IEEE Conference on Decision and Control (CDC).

[7]  Yan Zhou,et al.  Assessment of Impacts of PHEV Charging Patterns on Wind-Thermal Scheduling by Stochastic Unit Commitment , 2012, IEEE Transactions on Smart Grid.

[8]  Chen Chen,et al.  An innovative RTP-based residential power scheduling scheme for smart grids , 2011, 2011 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP).

[9]  R. Hendron Building America Research Benchmark Definition , 2008 .

[10]  Yi Zong,et al.  Application of Model Predictive Control for Active Load Management in a Distributed Power System With High Wind Penetration , 2012, IEEE Transactions on Smart Grid.

[11]  J. Contreras,et al.  ARIMA models to predict next-day electricity prices , 2002 .

[12]  Ning Lu,et al.  Appliance Commitment for Household Load Scheduling , 2011, IEEE Transactions on Smart Grid.

[13]  Guoyuan Wu,et al.  Development and Evaluation of Intelligent Energy Management Strategies for Plug-in Hybrid Electric Vehicles , 2012 .

[14]  S. Grijalva,et al.  Realizing smart grid benefits requires energy optimization algorithms at residential level , 2011, ISGT 2011.

[15]  Hamed Mohsenian Rad,et al.  Optimal Residential Load Control With Price Prediction in Real-Time Electricity Pricing Environments , 2010, IEEE Transactions on Smart Grid.

[16]  Marco Levorato,et al.  Residential Demand Response Using Reinforcement Learning , 2010, 2010 First IEEE International Conference on Smart Grid Communications.

[17]  Daniel James Livengood,et al.  The Energy Box : comparing locally automated control strategies of residential electricity consumption under uncertainty , 2011 .

[18]  Lawrence V. Snyder,et al.  Control Mechanisms for Residential Electricity Demand in SmartGrids , 2010, 2010 First IEEE International Conference on Smart Grid Communications.