Article: Small-signal stability assessment of a single-phase solid state transformer through PHIL experiment Journal: International Journal of Power Electronics (IJPELEC) 2015 Vol.7 No.3/4 pp.243 - 260 Abstract: Power electronic-based components (PECs) such as solid state transformers (SSTs), fault isolation devices (FIDs), power electronic-based converters, and motor drives provide highly useful features such as, load regulation, high power factor injection, and improved transient performance for power electronic-based distribution systems (PEDS). In contemporary power systems, which have high penetrations of renewable energy resources, as well as the inclusion of PECs. However, the drawback of including PECs in the system is that they can operate as negative impedances while connected to the constant power loads (CPLs) in the PEDS and CPLs are prone to small-signal instability due to their high power factor and constant-power nature in the system. Therefore, small-signal stability of the PEDS plays a prominent role in the systems analysis. In this paper, a new small-signal stability analysis method, based on d-q impedance measurement and generalised Nyquist criterion (GNC), is developed, and the stability of an SST is comprehensively investigated under various loading conditions and through power hardware-in-the-loop (PHIL) experimentation. Inderscience Publishers - linking academia, business and industry through research

Title: Small-signal stability assessment of a single-phase solid state transformer through PHIL experiment

Authors: M. Amin Salmani; Chris S. Edrington

Addresses: Department of Electrical Engineering, Center for Advanced Power Systems, Florida State University, 2039 N Meridian Rd Apt 207, Tallahassee, FL 32310 USA ' Department of Electrical Engineering, Center for Advanced Power Systems, Florida State University, 2000 Levy Ave., Tallahassee, FL, 32310, USA

Abstract: Power electronic-based components (PECs) such as solid state transformers (SSTs), fault isolation devices (FIDs), power electronic-based converters, and motor drives provide highly useful features such as, load regulation, high power factor injection, and improved transient performance for power electronic-based distribution systems (PEDS). In contemporary power systems, which have high penetrations of renewable energy resources, as well as the inclusion of PECs. However, the drawback of including PECs in the system is that they can operate as negative impedances while connected to the constant power loads (CPLs) in the PEDS and CPLs are prone to small-signal instability due to their high power factor and constant-power nature in the system. Therefore, small-signal stability of the PEDS plays a prominent role in the systems analysis. In this paper, a new small-signal stability analysis method, based on d-q impedance measurement and generalised Nyquist criterion (GNC), is developed, and the stability of an SST is comprehensively investigated under various loading conditions and through power hardware-in-the-loop (PHIL) experimentation.

Keywords: constant power loads; generalised Nyquist criterion; impedance measurement; Nyquist stability theorem; power electronics; distribution systems; power HIL; PHIL; hardware-in-the-loop; real-time stability assessment; small-signal stability; unit circle stability criterion; solid state transformers; SSTs.

DOI: 10.1504/IJPELEC.2015.075441

International Journal of Power Electronics, 2015 Vol.7 No.3/4, pp.243 - 260

Accepted: 20 Jan 2016
Published online: 22 Mar 2016 *

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Title: Small-signal stability assessment of a single-phase solid state transformer through PHIL experiment

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