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Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS)

Year 2014, Volume: 4 Issue: 2, 355 - 362, 01.06.2014

Abstract

In this paper, the impact of increasing in wind energy penetration level on voltage stability is studied by utilizing quasi-static time domain simulation (QSTDS). Connecting a squirrel cage induction generator (SCIG)-based wind farm has an undesirable effect on the voltage stability in power system, especially when this connection is accompanied with increase in the level of wind generation. Due to the asynchronous operation of induction machine, the increment of wind power generation will be possible only by absorption of more reactive power. Increasing in the power reactive consumption of induction generator leads to reduction of voltage in the bus of common connection between wind farm and the grid. Under these conditions, if the reactive power absorption of wind farm is not managed efficiently it would result in voltage instability of the grid. In this paper, it is shown that using static Var compensator (SVC) and static synchronous compensator (STATCOM) has improved the voltage stability of the system and leads to desirable performance of the wind farms.

References

  • Z. Chen, Y. Hu and F. Blaabjerg. “Stability Improvement of Induction Generator-Based Wind Turbine System” , IET Renewable Power Generation, Vol. 1, pp. 81-93, 1, March 2007.
  • I. S. Naser, A. Garba, O. Anay-Lara and K. L. Lo,“Voltage Stability of Transmission Network with Different Penetration Levels of Wind Generation”, 45th International Universities Power Engineering Conference (UPEC), Cardiff, Wales , pp. 1-5, 2010.
  • P. N. Boonchiam, A. Sode-Yome, N. Mithalananthan, K. Aodsup,“Voltage Stability in Power Network when Connected Wind Farm Generators”, International Conference
  • Systems(PEDS), Taipei, pp. 655 - 660, 2-5 Nov. 2009 Electronics and
  • Drive [4] F. Milano, “Assessing Adequate Voltage Stability Analysis Tools for Networks with High Wind Power Penetration”, Third International Conference on Electric Utility Deregulation and Restructuring and Power Technologies (DRPT), Nanjuing, China, pp. 2492 - 2497, 6-9 April 2008.
  • W. Freitas, J. C. M. Vieira, L. C. P. da Silva, C. M. Affonso and A. Morelato, “Long-term Voltage Stability of Distribution Systems with Induction Generators”, Proceedings of the IEEE Power Engineering Society General Meeting, San Francisco, pp. 2910 - 2913, 12-16 June 2005.
  • V. K. Ajjarapu, C. Christy, “The Continuation Power Flow: A Tool for Steady State Voltage Stability Analysis”, IEEE Transactions on Power Systems, Vol. 7, pp. 416 - 423, 1, Feb. 1992.
  • S. Iwamoto, Y. Tmura, “A Load Flow Calculation Method for Ill-Conditioned Power System”, IEEE Transactions on Power Apparatus and Systems, Vols. PAS-100, Issue 4, pp. 1736 - 1743, April 1981.
  • M. Z. Laton, I. Musirin, T. K. Abdul-Rahman, “Voltage Stability Assessment via Continuation Power Flow Method”, INT. JOURNAL OF ELECTRICAL AND ELECTRONIC SYSTEMS RESEARCH (IEESR), Vol. 1, pp. 71-78, 2008
  • A. Sode_Yome, N. Mithulananthan, K. Y. Lee, “A Maximum Loading Margin Method for Static Voltage Stability in Power System”, IEEE Transactions on Power Systems, Vol. 21, pp. 799 - 808, May 2006.
  • D. Ming, L.Binbin and H. Pingping, “Impact of Dubly- Fed Induction Wind Turbine Generator Operation Mode on System Voltage Stability”, 2nd IEEE International Synposium on Power Electronic for Distributed Generation Systems (PEDG), Hefei, Chaina, 16-18 June 2010.
  • P. Kundur, Power System Stability and Control, McGraw-Hill, 1994.
  • B. Gao, G. K. Morison and P. kundur, “Toward the Development of a Systematic approach for Voltage Stability Assessment of Large-Scale Power System”, IEEE Transactions on Power Systems, Vol. 11, pp. 1314-1324, August 1996.
  • L. Holdsworth, N. Jenkins, and G. Strbac, “Electrical stability of large, offshore wind farms”, Seventh International
  • Transmission, pp. 156-161, 28-30 Nov. 2001. on AC-DC
  • Power [14] V. Akhmatov, H. Knudsen, M. Bruntt and A.H. Nielsen, J. K. Pedersen, N. K. Poulsen, “A dynamic stability limit of grid-connected induction generator”, Proceedings of IASTED International Conference Power and Energy Systems, Marbella, Spain, pp. 235-244, September 2000 [15] L. Xu, L. Yao, C. Sasse “Comparison of using SVC and STATCOM for Wind Farm Integration”, International Conference on Power System Technology, Chongqing, pp. 1-7, 22-26 Oct. 2006.
Year 2014, Volume: 4 Issue: 2, 355 - 362, 01.06.2014

Abstract

References

  • Z. Chen, Y. Hu and F. Blaabjerg. “Stability Improvement of Induction Generator-Based Wind Turbine System” , IET Renewable Power Generation, Vol. 1, pp. 81-93, 1, March 2007.
  • I. S. Naser, A. Garba, O. Anay-Lara and K. L. Lo,“Voltage Stability of Transmission Network with Different Penetration Levels of Wind Generation”, 45th International Universities Power Engineering Conference (UPEC), Cardiff, Wales , pp. 1-5, 2010.
  • P. N. Boonchiam, A. Sode-Yome, N. Mithalananthan, K. Aodsup,“Voltage Stability in Power Network when Connected Wind Farm Generators”, International Conference
  • Systems(PEDS), Taipei, pp. 655 - 660, 2-5 Nov. 2009 Electronics and
  • Drive [4] F. Milano, “Assessing Adequate Voltage Stability Analysis Tools for Networks with High Wind Power Penetration”, Third International Conference on Electric Utility Deregulation and Restructuring and Power Technologies (DRPT), Nanjuing, China, pp. 2492 - 2497, 6-9 April 2008.
  • W. Freitas, J. C. M. Vieira, L. C. P. da Silva, C. M. Affonso and A. Morelato, “Long-term Voltage Stability of Distribution Systems with Induction Generators”, Proceedings of the IEEE Power Engineering Society General Meeting, San Francisco, pp. 2910 - 2913, 12-16 June 2005.
  • V. K. Ajjarapu, C. Christy, “The Continuation Power Flow: A Tool for Steady State Voltage Stability Analysis”, IEEE Transactions on Power Systems, Vol. 7, pp. 416 - 423, 1, Feb. 1992.
  • S. Iwamoto, Y. Tmura, “A Load Flow Calculation Method for Ill-Conditioned Power System”, IEEE Transactions on Power Apparatus and Systems, Vols. PAS-100, Issue 4, pp. 1736 - 1743, April 1981.
  • M. Z. Laton, I. Musirin, T. K. Abdul-Rahman, “Voltage Stability Assessment via Continuation Power Flow Method”, INT. JOURNAL OF ELECTRICAL AND ELECTRONIC SYSTEMS RESEARCH (IEESR), Vol. 1, pp. 71-78, 2008
  • A. Sode_Yome, N. Mithulananthan, K. Y. Lee, “A Maximum Loading Margin Method for Static Voltage Stability in Power System”, IEEE Transactions on Power Systems, Vol. 21, pp. 799 - 808, May 2006.
  • D. Ming, L.Binbin and H. Pingping, “Impact of Dubly- Fed Induction Wind Turbine Generator Operation Mode on System Voltage Stability”, 2nd IEEE International Synposium on Power Electronic for Distributed Generation Systems (PEDG), Hefei, Chaina, 16-18 June 2010.
  • P. Kundur, Power System Stability and Control, McGraw-Hill, 1994.
  • B. Gao, G. K. Morison and P. kundur, “Toward the Development of a Systematic approach for Voltage Stability Assessment of Large-Scale Power System”, IEEE Transactions on Power Systems, Vol. 11, pp. 1314-1324, August 1996.
  • L. Holdsworth, N. Jenkins, and G. Strbac, “Electrical stability of large, offshore wind farms”, Seventh International
  • Transmission, pp. 156-161, 28-30 Nov. 2001. on AC-DC
  • Power [14] V. Akhmatov, H. Knudsen, M. Bruntt and A.H. Nielsen, J. K. Pedersen, N. K. Poulsen, “A dynamic stability limit of grid-connected induction generator”, Proceedings of IASTED International Conference Power and Energy Systems, Marbella, Spain, pp. 235-244, September 2000 [15] L. Xu, L. Yao, C. Sasse “Comparison of using SVC and STATCOM for Wind Farm Integration”, International Conference on Power System Technology, Chongqing, pp. 1-7, 22-26 Oct. 2006.
There are 16 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Ashkan Edrisian This is me

Arman Goudarzi This is me

Mahmoud Ebadian This is me

Publication Date June 1, 2014
Published in Issue Year 2014 Volume: 4 Issue: 2

Cite

APA Edrisian, A., Goudarzi, A., & Ebadian, M. (2014). Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS). International Journal Of Renewable Energy Research, 4(2), 355-362.
AMA Edrisian A, Goudarzi A, Ebadian M. Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS). International Journal Of Renewable Energy Research. June 2014;4(2):355-362.
Chicago Edrisian, Ashkan, Arman Goudarzi, and Mahmoud Ebadian. “Investigating the Effect of High Level of Wind Penetration on Voltage Stability by Quasi-Static Time-Domain Simulation (QSTDS)”. International Journal Of Renewable Energy Research 4, no. 2 (June 2014): 355-62.
EndNote Edrisian A, Goudarzi A, Ebadian M (June 1, 2014) Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS). International Journal Of Renewable Energy Research 4 2 355–362.
IEEE A. Edrisian, A. Goudarzi, and M. Ebadian, “Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS)”, International Journal Of Renewable Energy Research, vol. 4, no. 2, pp. 355–362, 2014.
ISNAD Edrisian, Ashkan et al. “Investigating the Effect of High Level of Wind Penetration on Voltage Stability by Quasi-Static Time-Domain Simulation (QSTDS)”. International Journal Of Renewable Energy Research 4/2 (June 2014), 355-362.
JAMA Edrisian A, Goudarzi A, Ebadian M. Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS). International Journal Of Renewable Energy Research. 2014;4:355–362.
MLA Edrisian, Ashkan et al. “Investigating the Effect of High Level of Wind Penetration on Voltage Stability by Quasi-Static Time-Domain Simulation (QSTDS)”. International Journal Of Renewable Energy Research, vol. 4, no. 2, 2014, pp. 355-62.
Vancouver Edrisian A, Goudarzi A, Ebadian M. Investigating the effect of high level of wind penetration on voltage stability by quasi-static time-domain simulation (QSTDS). International Journal Of Renewable Energy Research. 2014;4(2):355-62.