Figure 9- System model with D

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Transcript Figure 9- System model with D

IV. SIMULATION RESULT
Wind power
System description
Figure 9- System model with D-STATCOM
IV. SIMULATION RESULT
At POC: V
Wind power
Without STATCOM
Figure 11- Simulation result of V
With STATCOM
IV. SIMULATION RESULT
SCIG
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Without STATCOM
With STATCOM
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V. CONCLUSIONS
• Power systems require taking into account the reactive
power of the wind farm in order to contribute to the
network stability, thus operating the wind farm as active
compensator devices. The impact of SCIG wind farm
connecting into a distribution network is completely
studied in this paper.
• when STATCOM is installed at wind farm, with STATCOM
technology to have the capability to increase stability and
improve system dynamic response following disturbances.
Application of STATCOMs for wind farm is to increase
power quality, regulate reactive power at the grid POC
and reduce voltage flicker.
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V. CONCLUSIONS
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Future works
Application of STATCOMs for wind farm use DFIG
turbines and for large-scale wind farm connect into the
grid to increase power quality, wind power systems
stability, reduce reactive power, reduce voltage flicker
and suitably manage the available capacity on the
sources of reactive power.
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REFERENCES
[1] Matlab Simulink toolbox of the \SimPowerSystems\Distributed Resources Library\Wind Generation\, the Help file of the model
of wind farm (IG), wind farm DFIG (Detailed type, Average type).
[2] “Wind Power in Power system”, The book edited by Thomas Ackermann, Royal Institute of Technology Stockholm, Sweden, in
2005.
[3] “Impacts of Wind Farms on Power System Stability”, chapter 7, edited by Ahmed G. Abo-Khalil, http://dx.doi.org/10.5772/55090
[4] Yvonne Coughlan, Paul Smith, Alan Mullane, Mark O’Malley, Membe IEEE, ” Wind Turbine Modelling for Power System
Stability Analysis—A System Operator Perspective”, IEEE Transaction on Power Systems, Vol. 22, NO. 3, August 2007.
[5] Mazen Abdel-Salam, Adel Ahmed, Mahmoud Mahrous, ” Transient analysis of grid-connected wind-driven PMSG, DFIG and
SCIG at fixed and variable speeds”, Electric Engineering Department, Assiut University, Assiut, Egypt, Innovative Systems Design
and Engineering, ISSN 2222-1727 (Paper) ISSN 2222-2871 (Online), Vol 2, No 3. www.iiste.org
[6] Francisco D__az Gonz_alez, Marcela Mart__nez-Rojas, Andreas Sumper, Oriol Gomis-Bellmunt, Llu__s Trilla, “Strategies for
Reactive Power Control in Wind Farms with STATCOM”.
[7] Fei Ye, Xueliang Huang, Chaoming Wang, Gan Zhou, Ping Luo, “The Impact and Simulation on Large Wind Farm Connected to
Power System”, DRPT2008 6-9 April 2008 Nanjing China.
[8] Mohammad Ali Tofigh, Nasrudin Abd Rahim , R. Vigna Kumaran, IEEE Member
“Voltage Regulation of Grid Connected
Wind Farm Using STATCOM”, Department of Electrical Engineering University of Malaya
Kuala Lumpur, Malaysia.
[9] Li Wang, Senior Member, IEEE, and Chia-Tien Hsiung, “Dynamic Stability Improvement of an Integrated Grid-Connected
Offshore Wind Farm and Marine-Current Farm Using a STATCOM”, IEEE Transactions on Power Systems,Vol. 26, NO. 2, MAY
2011.
[10] Sverre Skalleberg Gjerde and Tore M. Undeland, “ STATCOM and Energy Storage in Grid Integration of Wind Farms” fellow,
IEEE.
[11] Chong Han, Alex Q. Huang, Mesut Baran, Subhashish Bhattacharya, Wayne Litzenberger, Loren Anderson, Anders Johnson,
Abdel-Aty Edris, “STATCOM Impact Study on the Integration of a Large Wind Farm into a Weak Loop Power System”, SPEC, NC
State Univ., Raleigh, USA.
[12] Ching-Yin Lee, Li-Chieh Chen, Shao-Hong Tsai, Wen-Tsan Liu, Yuan-Kang Wu, “The Impact of SCIG Wind Farm Connecting
into a Distribution System”, Department of Electrical Engineering, National Taipei University of Technology, Taipei, Taiwan
Wind power
THANKS FOR YOUR ATTENTION!