Lab-Scale TCR-Based SVC System for Educational and DG Applications

Motivated by the development of power semiconductor technologies, flexible ac transmission systems (FACTS) devices and their penetration in the field of electrical power systems, an educational challenge in complementing theoretical knowledge with practical experience is recognized. In this paper, the design and implementation of a lab-scale hardware and software setup is presented. Three small-scale devices, including a static VAr compensator (SVC) unit, a transmission line model, and a substation, are developed. The SVC unit is validated by obtaining its operating characteristic. The lab setup is presented as a platform to carry out different experiments related to the SVC operation. Safety considerations in the design are discussed. Steady-state and dynamic analysis are presented showing the consistency between theory and practice. The potential use of small SVC units on low-voltage distributed generation schemes is discussed.

[1]  J. Munoz,et al.  Lab-scale three-phase TCR-based SVC system for educational purpose in dynamic and steady-state analysis , 2007, 2007 39th North American Power Symposium.

[2]  Rajiv K. Varma,et al.  Thyristor-Based Facts Controllers for Electrical Transmission Systems , 2002 .

[3]  Weijen Lee,et al.  Using a static VAr compensator to balance a distribution system , 1996, IAS '96. Conference Record of the 1996 IEEE Industry Applications Conference Thirty-First IAS Annual Meeting.

[4]  A. Emadi Grainger power electronics and motor drives laboratories at Illinois Institute of Technology , 2005, IEEE Power Engineering Society General Meeting, 2005.

[5]  P.Z. Haro,et al.  Experimental results on a lab scale single-phase TCSC , 2002, IEEE Power Engineering Society Summer Meeting,.

[6]  H. Akagi Prospects of new technologies for power electronics in the 21st century , 2002, IEEE/PES Transmission and Distribution Conference and Exhibition.

[7]  P.L. Chapman,et al.  Modern laboratory-based education for power electronics and electric machines , 2005, IEEE Transactions on Power Systems.

[8]  E. O'Neill-Carrillo,et al.  Undergraduate research and new laboratory practices in power engineering , 2002, 32nd Annual Frontiers in Education.

[9]  G. Majumdar Power Modules As Key Component Group For Power Electronics , 2007, 2007 Power Conversion Conference - Nagoya.

[10]  R. Palma-Behnke,et al.  System Security and Dynamic Performance in the Chilean Central Interconnected System , 2006, 2006 IEEE PES Power Systems Conference and Exposition.

[11]  P. K. Sen,et al.  Benefits of Power Electronic Interfaces for Distributed Energy Systems , 2010, IEEE Transactions on Energy Conversion.

[12]  K. Miu,et al.  Power transmission and distribution system laboratories at Drexel University , 2005, IEEE Power Engineering Society General Meeting, 2005.

[13]  I. Erlich,et al.  Advanced grid requirements for the integration of wind turbines into the German transmission system , 2006, 2006 IEEE Power Engineering Society General Meeting.

[14]  K. Methaprayoon,et al.  Reactive compensation techniques to improve the ride-through capability of wind turbine during disturbance , 2005, IEEE Transactions on Industry Applications.