Optimal Scheduling of Critical Peak Pricing Considering Wind Commitment

Demand response has been widely implemented as one of the “virtual” control mechanisms to make peak load management more efficient and economic. One of the popular demand response programs is called critical peak pricing (CPP). Relatively simple pricing schemes and convenient implementation within current energy system metering infrastructure make it well accepted by many utilities and load-serving entities (LSEs). In this paper, we investigate the optimal scheduling of CPP events from the perspective of an LSE which has wind energy to sell into the day-ahead market. The goal is to minimize the total operational cost for the whole planning horizon, taking into account the energy purchasing cost, revenue from the CPP, and wind energy sales, as well as imbalance penalties due to wind energy over- and under-commitments. We propose a multi-stage stochastic mixed integer nonlinear programming model. In addition, we perform various analyses of both the special case of a single-stage problem and the general multi-stage problem analytically and experimentally. Our analysis leads to useful operational insights and policy implications on how to manage a renewable-integrated system more efficiently.

[1]  Jhi-Young Joo,et al.  Option Valuation Applied to Implementing Demand Response via Critical Peak Pricing , 2007, 2007 IEEE Power Engineering Society General Meeting.

[2]  Rajesh Tyagi,et al.  Potential problems with large scale differential pricing programs , 2010, IEEE PES T&D 2010.

[3]  L. Soder,et al.  Minimization of imbalance cost trading wind power on the short term power market , 2005, 2005 IEEE Russia Power Tech.

[4]  Karen Herter,et al.  Observed Temperature Effects on Hourly Residential Electric Load Reduction in Response to an Experimental Critical Peak Pricing Tariff , 2005 .

[5]  S. Borenstein The Long-Run Efficiency of Real-Time Electricity Pricing , 2005 .

[6]  Peng Xu,et al.  Automated Critical Peak Pricing Field Tests: Program Description and Results , 2006 .

[7]  R. Piwko,et al.  Wind energy delivery issues [transmission planning and competitive electricity market operation] , 2005, IEEE Power and Energy Magazine.

[8]  Xiaoxuan Zhang Optimal wind bidding strategy considering imbalance cost and allowed imbalance band , 2012, 2012 IEEE Energytech.

[9]  Dmitriy Katz,et al.  Incentive Design for Lowest Cost Aggregate Energy Demand Reduction , 2010, 2010 First IEEE International Conference on Smart Grid Communications.

[10]  Rajesh Tyagi,et al.  Scheduling demand response events with constraints on total number of events per year , 2010, 2010 IEEE Energy Conversion Congress and Exposition.

[11]  Xifan Wang,et al.  Optimal implementation strategies for critical peak pricing , 2009, 2009 6th International Conference on the European Energy Market.

[12]  Robert Bartle,et al.  The Elements of Real Analysis , 1977, The Mathematical Gazette.

[13]  Karen Herter Residential implementation of critical-peak pricing of electricity , 2007 .