Internal cooling passages of turbine blades have long been at risk to blockage through the deposition of sand and dust during fleet service life. The ingestion of high volumes of volcanic ash (VA) therefore poses a real risk to engine operability. An additional difficulty is that the cooling system is frequently impossible to inspect in order to assess the level of deposition. This paper reports results from experiments carried out at typical high pressure (HP) turbine blade metal temperatures (1163 K to 1293 K) and coolant inlet temperatures (800 K to 900 K) in engine scale models of a turbine cooling passage with film-cooling offtakes. Volcanic ash samples from the 2010 Eyjafjallajökull eruption were used for the majority of the experiments conducted. A further ash sample from the Chaiten eruption allowed the effect of changing ash chemical composition to be investigated. The experimental rig allows the metered delivery of volcanic ash through the coolant system at the start of a test. The key metric indicating blockage is the flow parameter (FP), which can be determined over a range of pressure ratios (1.01–1.06) before and after each experiment, with visual inspection used to determine the deposition location. Results from the experiments have determined the threshold metal temperature at which blockage occurs for the ash samples available, and characterize the reduction of flow parameter with changing particle size distribution, blade metal temperature, ash sample composition, film-cooling hole configuration and pressure ratio across the holes. There is qualitative evidence that hole geometry can be manipulated to decrease the likelihood of blockage. A discrete phase computational fluid dynamics (CFD) model implemented in Fluent has allowed the trajectory of the ash particles within the coolant passages to be modeled, and these results are used to help explain the behavior observed.
Skip Nav Destination
Article navigation
March 2017
Research-Article
Reduction in Flow Parameter Resulting From Volcanic Ash Deposition in Engine Representative Cooling Passages
Sebastien Wylie,
Sebastien Wylie
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
e-mail: sebastien.wylie@eng.ox.ac.uk
University of Oxford,
Oxford OX2 0ES, UK
e-mail: sebastien.wylie@eng.ox.ac.uk
Search for other works by this author on:
Alexander Bucknell,
Alexander Bucknell
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
Search for other works by this author on:
Peter Forsyth,
Peter Forsyth
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
Search for other works by this author on:
Matthew McGilvray,
Matthew McGilvray
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
Search for other works by this author on:
David R. H. Gillespie
David R. H. Gillespie
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
Search for other works by this author on:
Sebastien Wylie
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
e-mail: sebastien.wylie@eng.ox.ac.uk
University of Oxford,
Oxford OX2 0ES, UK
e-mail: sebastien.wylie@eng.ox.ac.uk
Alexander Bucknell
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
Peter Forsyth
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
Matthew McGilvray
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
David R. H. Gillespie
Department of Engineering Science,
University of Oxford,
Oxford OX2 0ES, UK
University of Oxford,
Oxford OX2 0ES, UK
1Corresponding author.
Contributed by the International Gas Turbine Institute (IGTI) of ASME for publication in the JOURNAL OF TURBOMACHINERY. Manuscript received September 20, 2016; final manuscript received October 4, 2016; published online November 22, 2016. Editor: Kenneth Hall.
J. Turbomach. Mar 2017, 139(3): 031008 (13 pages)
Published Online: November 22, 2016
Article history
Received:
September 20, 2016
Revised:
October 4, 2016
Citation
Wylie, S., Bucknell, A., Forsyth, P., McGilvray, M., and Gillespie, D. R. H. (November 22, 2016). "Reduction in Flow Parameter Resulting From Volcanic Ash Deposition in Engine Representative Cooling Passages." ASME. J. Turbomach. March 2017; 139(3): 031008. https://doi.org/10.1115/1.4034939
Download citation file:
Get Email Alerts
Related Articles
A Converging Slot-Hole Film-Cooling Geometry—Part 2: Transonic Nozzle Guide Vane Heat Transfer and Loss
J. Turbomach (July,2002)
A Novel Technique for Assessing Turbine Cooling System Performance
J. Turbomach (July,2011)
Biot Number Analogy for Design of Experiments in Turbine Cooling
J. Turbomach (June,2015)
Effects of a Reacting Cross-Stream on Turbine Film Cooling
J. Eng. Gas Turbines Power (May,2010)
Related Proceedings Papers
Related Chapters
Completing the Picture
Air Engines: The History, Science, and Reality of the Perfect Engine
Control and Operational Performance
Closed-Cycle Gas Turbines: Operating Experience and Future Potential
Fans and Air Handling Systems
Thermal Management of Telecommunications Equipment