A physical control/protection platform needs to be tested and its functionality verified prior to installation and commissioning. Closed-loop testing of a physical control/protection platform, in a real-time simulator environment is practically the only option to safely and thoroughly verify the design integrity and evaluate its functionality and performance. Moreover, a real-time simulator is also required to conduct statistical switching studies, as it substantially reduces the total run time of the study.
This thesis proposes and develops a generalized methodology for implementation of
the power system equations in the FPGA environment. The developed methodology enables real-time operation, for closed-loop testing of physical control/protection platforms
in hardware-in-the-loop (HIL) configuration, and even faster-than-real-time operation, for statistical switching studies. Based on the developed methodology, an FPGA-based simulator is developed and tested. The salient features of the proposed implementation are:
² It enables the use of a nanosecond range simulation time-step to simulate large systems in real-time, in contrast to the us range time-steps used in the existing simulators. Thus it is also able to provide a wide frequency bandwidth for the simulation results.
² It retains the calculation time, within each simulation time-step, nearly fixed irrespective of the size of the system.
² It eliminates the need for the corrective measures, adopted in the existing real-time
simulators, to reduce error due to the lack of synchronization between the simulation
time-grid and the output signals of the control/protection platform under test.
As an integral part of this work, this thesis proposes and develops the modified
two-layer network equivalent (M-TLNE). The salient feature of the M-TLNE is its computational efficiency, as compared to the existing network equivalents, which makes it
a prime choice for statistical switching studies and real-time simulation of electromagnetic transients. This thesis also proposes a generalized methodology, applicable to both single and multi-port network equivalents for both single- and multi-phase systems, for developing the proposed M-TLNE. The developed methodology ensures the stability and passivity of the M-TLNE.
Identifer | oai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/32001 |
Date | 17 January 2012 |
Creators | Bayoumi, Mahmoud |
Contributors | Iravani, Mohammad Reza |
Source Sets | University of Toronto |
Language | en_ca |
Detected Language | English |
Type | Thesis |
Page generated in 0.0018 seconds