Most Popular Papers

This paper presents a multi-objective dispatch model of the power system with large-scale wind farms and cascade hydropower stations. Besides the objective of economic dispatch, considering the system operators’ requirement that the deviation of the daily actual thermal power generation from scheduled generation should be as small as possible, a new objective to minimize this deviation is very essential. Therefore, this paper formulates a multi-objective model that aims at minimizing both the total generation cost and daily deviation of thermal power generations, and achieves the maximum consumption of wind power by rationally arranging the operation of cascade hydropower stations. This model takes into account of the capacity constraint of transmission lines, operation constraints of cascade hydropower stations, constraint of boundary flows, and contract generation constraint on tie-lines. This model has a good accordance with the practical operation of the power system operation, and the security and reliability of the power system can be improved. The effectiveness of the proposed model has been verified on the IEEE-RTS 24 system
Copyright © 2013 Praise Worthy Prize - All rights reserved.

Multi-Objective Dispatch; Cascade Hydropower Stations; Wind Farm; Contract Generation; Boundary Flows

L.F. Wang, C. Singh C, Balancing risk and cost in fuzzy economic dispatch including wind power penetration based on particle swarm optimization, Electric Power Systems Research, vol. 78 n. 8, August 2008, pp.1361-1368.

S. Rebennack, B.C. Flach, M.V.F. Pereira, P.M. Pardalos, Stochastic Hydro-Thermal Scheduling Under CO2 Emissions Constraints, IEEE Transactions on power system, vol. 27 n. 1, February 2012, pp: 58-68.

Ganesan, S., Subramanian, S., A novel hybrid method for thermal unit commitment problems, (2010) International Review on Modelling and Simulations (IREMOS), 3 (4), pp. 694-704.

C. Han, A.Q. Huang, M.E. Baran, S. Bhattacharya, W. Litzenberger, L. Anderson, A.l. Johnson, A.A. Edris, STATCOM impact study on the integration of a large wind farm into a week loop power system, IEEE transaction on energy conversion, vol. 23 n. 1, march 2008, pp:226-233.

V. Hamidi, F.R. Li, L.Z. Yao, Value of Wind Power at Different Locations in the Grid, IEEE Transactions on Power Delivery, vol. 26 n. 2, April 2011, pp:526-537.

M.A. Khorsand, A. Zakariazadeh, S. Jadid, Stochastic wind-thermal generation scheduling considering emission reduction: a multiobjective mathematical programming approach, Power and Energy Engineering Conference (APPEEC), 2011 Asia-Pacific, March 1-4, 2011, Iran, Tehran.

X. Liu, W. Xu, Minimum emission dispatch constrained by stochastic wind power availability and cost, IEEE Transactions on Power Systems, vol. 25 n. 3, August 2010, pp.1705-1713.

Jalilzadeh, S., Kazemi, A., Farhang, P., Analysis and assessment of power system including wind farm by using SVC and STATCOM, (2012) International Review of Electrical Engineering (IREE), 7 (4), pp. 4971-4979.

Hoseynpoor, Y., Pirzadeh Ashraf, T., Sajedi, S., Karimi, T., Evaluation of power quality in a wind power generation system, (2011) International Review on Modelling and Simulations (IREMOS), 4 (3), pp. 1233-1238.

S.W. Mohod, M.V. Aware, A STATCOM-Control Scheme for Grid Connected Wind Energy System for Power Quality Improvement, IEEE System Journal, vol. 4 n. 3, September 2010, pp:346-352.

Mosayebian, M.E., Monsef, H., Reliability evaluation in power system integrated with wind power, (2010) International Review on Modelling and Simulations (IREMOS), 3 (3), pp. 368-372.

S. Brini, H.H. Abdallah, A. Ouali, Economic dispatch for power system included wind and solar thermal energy, Leonardo Journal of Sciences, n. 14, January-June 2009, pp.204-220.

X.H. Li, C.W. Jiang, Short-term operation model and risk management for wind power penetrated system in electricity market, IEEE Transactions on Power Systems, vol. 26 n. 2, May 2011, pp.932-939.

J. Hetzer, D.C. Yu, K. Bhattarai, An economic dispatch model incorporating wind power, IEEE Transactions on Energy Conversion, vol. 23 n. 2, June 2008, pp.603-611.

R.H. Liang, J.H. Liao, A fuzzy-optimization approach for generation scheduling with wind and solar energy systems, IEEE Transactions on Power Systems, vol. 22 n. 4, November 2007, pp.1665-1674.

C.L. Chen, Simulated annealing-based optimal wind-thermal coordination scheduling, IET Generation, Transmission and Distribution, vol. 1 n. 3, May 2007, pp.447-455.

X. Sun, C.Z. Fang, Interval mixed integer programming for daily unit commitment and dispatch incorporating wind power, Power System Technology (POWERCON), 2010 International Conference on, October 1-6, 2010, Zhenjiang, China.

F. Vieira, H.M. Ramos, Optimization of operational planning for wind/hydro hybrid water supply systems, Renewable Energy, vol. 34 n. 3, March 2009, pp.928-936.

J.A.P. Lopes, On the optimization of the daily operation of a wind-hydro power plant, IEEE Transactions on Power Systems, vol. 19 n. 3, August 2004, pp.1599-1606.

S. Papaefthimiou, E.G. Karamamou, S.A. Papathanassiou, M.P. Papadopoulos, Operating policies for wind-pumped storage hybrid power stations in island grids, IET Renewable Power Generation, vol. 3 n. 3, August 2008, pp.293-307.

Bishe, H.M., Kian, A.R., Esfahani, M.S., A primal-dual interior point method for solving environmental/economic power dispatch problem, (2011) International Review of Electrical Engineering (IREE), 6 (3), pp. 1463-1473.

X.F. Huang, C.M. Ji, Z.Y. Pei, Chaotic Particle Swarm Optimiazation Algorithm with Niche and Its Application in Cacade Hydropower Reservoirs Operation, Artificial Intelligence and Computational Intelligence, 2009. AICI '09. International Conference on, Novenber 568-572, 2009, Beijing, China.

T.H. Zhao, Z.B. Man , X.Y. Qi, The United Optimal Operation System of Cascade Hydropower Stations Based on Multi-Agent, Natural Computation, 2008. ICNC '08. Fourth International Conference on, October 571-575, 2008, Lanzhou, China.

C.E. Zoumas, A.Z. Bakirtzis, J.B. Theocharis, V. Petridis, A genetic algorithm solution approach to the hydro-thermal coordination problem, IEEE Transactions on Power Systems, vol 19 n. 3, August 2004, pp. 1356–1364.

C. Grigg, The IEEE Reliability Test System-1996. A report prepared by the Reliability Test System Task Force of the Application of Probability Methods Subcommittee, IEEE Transactions on Power Systems, vol. 14 n. 3, August 1999, pp.1010-1020.

N. Bin Abd Rahman, Capacity benefit margin (CBM) assessment incorporating tie-line reliability, Power Engineering and Optimization Conference (PEOCO), 2010 4th International, June 337-344, 2010, Arau, Malaysia.

Damiano, A., Gatto, G., Marongiu, I., Meo, S., Perfetto, A., Serpi, A., A direct-drive wind turbine control for a wind power plant with an internal DC distribution system, (2012) International Review of Electrical Engineering (IREE), 7 (4), pp. 4845-4856.