A hybrid model for the transient stability of the rotor angle constrained optimal power flow

Beheshti, Babak; Shahgholian, Ghazanfar

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Volume 7, Issue 2 (3-2019)

ieijqp 2019, 7(2): 83-94

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A hybrid model for the transient stability of the rotor angle constrained optimal power flow

Babak Beheshti¹

, Ghazanfar Shahgholian ^*

1- Islamic Azad University

Abstract: (4429 Views)

Optimal power flow with transient stability is a nonlinear optimization problem with algebraic and differential equations. In this paper, using the imperialist competition algorithm as an evolutionary optimization algorithm and artificial neural network, a robust and effective two-stage design for solving the TSCOPF problem (transient stability constrained optimal power flow) has been proposed. In hybrid model, an artificial neural network was introduced to predict the transverse stability margin of the rotor angle and then to estimate the transient stability of the rotor angle bound to the optimal load distribution. To solve the problem of TSCOPF (transient stability constraint optimal power flow), imperialist competition algorithm optimization has been used. The function of the proposed method is based on the three-machine system, the WSCC (Western System Coordinating Council) and the IEEE cases under different loading conditions and error mode

Keywords: Optimal Power Flow, Colonial Competition, Artificial Neural Network

Full-Text [PDF 1942 kb] (1129 Downloads)

Type of Study: Research |
Received: 2018/07/16 | Accepted: 2019/01/22 | Published: 2019/02/25

References

1. [1] P. Kundur," Power system stability and control", New York, McGraw-Hill companies, 1994.

2. [2] H. Saadat, "Power system analysis", United States, PSA Pub., 2010.

3. [3] A. Pizano-Martínez, C.R. Fuerte-Esquivel, D. Ruiz-Vega, "Global transient stability constrained optimal power flow using an OMIB reference trajectory", IEEE Trans. On Power Systems, Vol. 25, No. 1, pp. 392-403, Feb. 2010.

4. [4] S.W. Xia, B. Zhou., K.W. Chan, Z.Z. Guo, "An improved GSO method for discontinuous non-convex transient stability constrained optimal power flow with complex system model", International Journal of Electrical Power & Energy Systems, Vol. 64, pp. 483-492, Jan. 2015.

5. [5] S. Xia, K.W. Chan, Z. Guo, "A novel margin sensitivity based method for transient stability constrained optimal power flow", Electric Power Systems Research, Vol. 108, pp. 93-102, March 2014.

6. [6] H. Ahmadi, H. Ghasemi, A. M. Haddadi, H. Lesani, " Two approaches to transient stability constrained optimal power flow" International Journal of Electrical Power & Energy Systems, Vol. 47, pp. 181-192, May 2013.

7. [7] S. Xia, K.W. Chan, Z. Guo, "A novel margin sensitivity based method for transient stability constrained optimal power flow", Electric Power Systems Research, Vol. 108, pp. 93-102, March 2014.

8. [8] A. Pizano-Martínez, C. R. Fuerte-Esquivel, E. Zamora-Cárdenas, D. Ruiz-Vega, "Selective transient stability- constrained optimal power flow using a SIME and trajectory sensitivity unified analysis", Electric Power Systems Research, Vol. 109, pp. 32-44, April 2014.

9. [9] H. D. Chiang, F. F. Wu, P. P. Varaiya , "A BCU method for direct analysis of power system transient stability", IEEE Transactions on power systems, Vol. 9, No. 3, pp. 1194-1208, August 1994 .

10. [10] M. Oluic, M. Ghandhari, B. Berggren, "Methodology for rotor angle transient stability assessment in parameter space", IEEE Tran. on Power Systems, Vol. 32, No. 2, pp. 1202-1211, March 2017.

11. [11] M. Oluić, M. Ghandhari, "On the parametrization of rotor angle transient stability region", North American Power Symposium (NAPS), 4-6 Oct. 2015.

12. [12] Y. Xu, Z. Y. Dong, Z. Xu ,K. P. Wong, " Power system transient stability constrained optimal power flow: A comprehensive review, Proceeding of the IEEE, Published in power and energy society general meeting, San Diego, CA, USA, July 2012.

13. [13] R.A. Lajimi, T. Amraee, "A two stage model for rotor angle transient stability constrained optimal power flow", International Journal of Electrical Power and Energy Systems, Vol. 76, pp. 82–89, March 2016.

14. [14] E. Atashpaz gargary,C. Lucas,"Imperialist competitive algorithm:an algorithm for optimization inspired by imperialistic competition",Proceeding of the IEEE/CEC, pp.4661-4667, Singapore, Sep. 2007.

15. [15] P. M. Anderson and A. A. Fouad," Power system control and stability", The Iowa State University Press, 1977.

16. [16] R. D. Zimmerman" MATPower 4.02b2" Power systems engineering research center, March 2010.

17. [17] R. Patel, T. S. Bhatti, D. P. Kothari, "MATLAB/simulink-based transient stability analysis of a multimachine power system", International Journal of Electrical Engineering Education, pp. 320-336, Oct. 2002.

18. [18] H. R. Cai, C. Y. Chung, K. P. Wong, "Application of differential evolution algorithm for transient stability constrained optimal power flow", IEEE Tran. on Power Systems, Vol. 23, No. 2, pp. 719-728, May 2008.

19. [19] "WSCC 9-Bus System," University of Illinois vol. Coordinated Science Laboratory, 2013.

20. [20] X. Yan, D. Zhao Yang, M. Ke, Z. Jun Hua, and W. Kit Po, "A hybrid method for transient stability-constrained optimal power flow computation", IEEE Trans. on Power Systems, Vol. 27, pp. 1769-1777, Nov. 2012.

21. [21] A. Zerigui, L. A. Dessaint, R. Hannat, R. T. F. Ah King, I. Kamwa," Statistical approach for transient stability constrained optimal power flow", IET Generation, Transmission and Distribution, Vol. 9, Issue 14, pp. 1856 – 1864, Nov. 2015.

22. [22] K. Ayan, U. Kilic, B. Barakli, "Chaotic artificial bee colony algorithm based solution of security and transient stability constrained optimal power flow" , International Journal of Electrical Power & Energy Systems, Vol. 64, pp. 136-147, Jan. 2015.

23. [23] H. Nguyen. Duc, L. Tran Hoai, D. Vo Ngoc, "A novel approach to solve transient stability constrained optimal power flow problems",Turkish Journal of Electrical Engineering& Computer Science, Vol 25, pp. 4696-4705, March 2017.

‎ 20.1001.1.23222344.1397.7.2.8.4

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Beheshti B, Shahgholian G. A hybrid model for the transient stability of the rotor angle constrained optimal power flow. ieijqp 2019; 7 (2) :83-94
URL: http://ieijqp.ir/article-1-544-en.html

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