The oil and gas industry has a growing demand for electrically driven trains operated at variable speeds. Variable frequency electrical drives enable increased operational flexibility and energy efficiency. One drawback of power electronics driven systems is the generation of non-fundamental air-gap torque ripple components due to electrical harmonics. The air-gap torque ripple can interact with the mechanical system at natural torsional frequencies of the drive train. Uncontrolled excited torsional vibration can silently lead to coupling failure due to fatigue. The coincidence of electrical drive harmonics and natural torsional frequencies of the mechanical system is sometimes unavoidable, due to the large variable speed range of the compressor as for process requirements. For those types of applications, a damping system utilizing available power electronics has been developed that can be applied to new units but also as a retrofit solution in existing variable speed trains. Electronic torsional vibration elimination (eTVe) is based on an angular vibration measurement in the mechanical system and an interface to the existing inverter control of the electrical drive. An important milestone of the eTVe development was achieved in 2010, in site testing this new solution to Liquid Natural Gas (LNG) production trains and demonstrating that it can completely eliminate torsional vibrations. With eTVe a residual torsional vibration level was achieved that was lower than the vibration level measured while the LNG train was only gas turbine driven. This torsional performance was achieved with a standard load commutated inverter drive (LCI). LCIs are one of the most widespread electrical drive technology for gas compression trains because of excellent reliability records, and it is the only one referenced solution for electric power larger than 45 MW.
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ASME 2011 Turbo Expo: Turbine Technical Conference and Exposition
June 6–10, 2011
Vancouver, British Columbia, Canada
Conference Sponsors:
- International Gas Turbine Institute
ISBN:
978-0-7918-5466-2
PROCEEDINGS PAPER
Electronic Torsional Vibration Elimination for Synchronous Motor Driven Turbomachinery
Christof Sihler,
Christof Sihler
GE Global Research, Munich, Germany
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Simon Schramm,
Simon Schramm
GE Global Research, Munich, Germany
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Valerio Rossi,
Valerio Rossi
GE Oil & Gas, Florence, Italy
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Valerio Depau
Valerio Depau
GE Oil & Gas, Florence, Italy
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Christof Sihler
GE Global Research, Munich, Germany
Simon Schramm
GE Global Research, Munich, Germany
Valerio Rossi
GE Oil & Gas, Florence, Italy
Andrea Lenzi
GE Oil & Gas, Florence, Italy
Valerio Depau
GE Oil & Gas, Florence, Italy
Paper No:
GT2011-46005, pp. 399-408; 10 pages
Published Online:
May 3, 2012
Citation
Sihler, C, Schramm, S, Rossi, V, Lenzi, A, & Depau, V. "Electronic Torsional Vibration Elimination for Synchronous Motor Driven Turbomachinery." Proceedings of the ASME 2011 Turbo Expo: Turbine Technical Conference and Exposition. Volume 6: Structures and Dynamics, Parts A and B. Vancouver, British Columbia, Canada. June 6–10, 2011. pp. 399-408. ASME. https://doi.org/10.1115/GT2011-46005
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