Projects:2017s1-190 Modelling and Validation for Synchronous Generators
Contents
- 1 Team Members:
- 1.1 Supervisors:
- 1.2 Aim:
- 1.3 Motivation:
- 1.4 Software Model of The Generator in Matlab:
- 1.5 Measurement of Rotor Angle Using Encoding Wheel:
- 1.6 Lab-View and Data Acquisition (DAQ) Board:
- 1.7 EES Steady State Testing:
- 1.8 Synchronous Machine Saturation Model:
- 1.9 Steady State Capability Test:
- 1.10 Load Rejection:
- 1.11 Risk Analysis
- 1.12 Conclusion:
- 1.13 References:
Team Members:
- Ainal Syazwan Itamta
- Binhao Li
Supervisors:
- Dr. Andrew Allison
- David Vowels
Aim:
The aim of this project is to identify the dynamical parameters of the synchronous generators in NG06 Junior Lab. The model will be calibrated and verified via several specified tests on the machine. After that, the test procedures and designs specification will be documented.
Motivation:
The steady state characteristics of the synchronous generators are already well documented.However, the dynamical characteristics are required to be explored. Using these as guidelines, future students and academics can further analyze the synchronous machine in NG06 Junior Lab.
Software Model of The Generator in Matlab:
This section is done by Xinrui Li
Measurement of Rotor Angle Using Encoding Wheel:
This section is done by Binhao Li
Lab-View and Data Acquisition (DAQ) Board:
This section is done by Ainal Syazwan
EES Steady State Testing:
Synchronous Machine Saturation Model:
Steady State Capability Test:
Load Rejection:
Risk Analysis
Conclusion:
References:
[1]F. P. D. Mello et al, “Derivation of synchronous machine parameters from tests”, IEEE Power Tech. Inc., Schenectady, NY, Rep. 4, 1977.
[2]J. P. Bartlett, “The practical application of optimal control techniques to synchronous generator excitation”, The University of Adelaide, Adelaide, SA, 1972.
[3]. Kundur, Power system stability and control, New York, McGraw Hill, 1994.
[4]T. Wildi, Electrical machines, drives, and power systems, 5th edition, New Jersey, Pearson Education Inc, 2006.
[5]The Institute of Electrical and Electronics Engineers, IEEE Guide for Test Procedures for Synchronous Machines, New York, 2010.
[6]"Synchronous Generator as a Wind Power Generator", Alternative Energy Tutorials, 2016. [Online]. Available: http://www.alternative-energy-tutorials.com/wind-energy/synchronous-generator.html. [Accessed: 17- Apr- 2016].
[7]"Permanent magnet synchronous motor with sinusoidal fluxdistribution - MATLAB",Au.mathworks.com, 2016. [Online]. Available: http://au.mathworks.com/help/physmod/sps/ref/permanentmagnetsynchronousmotor.html. [Accessed: 17- Apr- 2016].
[8]"Risk Management Process - ISO 14971 - Risk Assessment - Risk Control", TSQuality.ch, 2016. [Online]. Available: http://tsquality.ch/risk-management-process/. [Accessed: 31- May- 2016].
[9]D. Vowles, P. Pourbeik and M. Gibbard, “Small-signal stability, control and dynamic performance of power systems”. University of Adelaide Press, 2015.
[10] D.J. Vowles, Suite of Matlab functions for steady-state analysis and parameter identification of synchronous machines, May 2016.
[11]W. Soong and A. Allison, "EES lecture Note Package", 2016.
[12]K. Daware, "Basic construction and working of a DC Generator.", Electricaleasy.com, 2016. [Online]. Available: http://www.electricaleasy.com/2012/12/basic-construction-and-working-of-dc.html. [Accessed: 17- Oct- 2016].
[13]"Synchronous Motor Excitation | Electrical4u", Electrical4u.com, 2016. [Online]. Available: http://www.electrical4u.com/synchronous-motor-excitation/. [Accessed: 19- Oct- 2016].
[14] A. Allison, Suite of Matlab functions for road rejection analysis, October 2016.