Turbomachine internal pressure and blade response modelling

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dc.contributor.advisor Heyns, P.S. (Philippus Stephanus) en
dc.contributor.postgraduate Church, Chris Bryan en
dc.date.accessioned 2016-07-29T11:02:17Z
dc.date.available 2016-07-29T11:02:17Z
dc.date.created 2016-04-15 en
dc.date.issued 2015 en
dc.description Dissertation (MEng)--University of Pretoria, 2015. en
dc.description.abstract Blades are critical components of turbomachines, failure of a single blade may result in catastrophic failure of the entire machine. One study found that blade failure was the third largest cause of power generation unit unavailability. Their condition during operation is therefore of interest to monitor. Various intrusive and non-intrusive blade vibration measurement (BVM) techniques have been developed for this purpose. Intrusive techniques such as strain gauge approaches and the frequency modulated grid method require expensive and complex alteration of the actual blades and/or casing. Further, they are prone to failure due to operation in harsh working environments. Therefore the use of intrusive techniques has been predominantly limited to design verification, testing and research. Blade tip timing approaches are currently at the forefront of BVM. The practicality, accuracy and ease of implementation of these approaches have limited their commercial roll out. An alternative nonintrusive source of blade vibration information was found in the internal casing pressure signal (CPS). As the machine operates the blade movement excites the fluid in the casing, producing a measureable response. Unlike BTT approaches which deal with a scarcity of information, CPS based methods must identify blade vibration from a complex signal which contains multiple other sources of information. The issue of how to model the blades response and fluid interaction is the topic of this investigation. An available single stage turbomachine mock setup was modified for internal pressure and direct blade vibration measurements. Pressure measurements were taken in line with a redesigned hub and rotor blade assembly. Strain gauges (SG) were applied to blades in order to capture their response. The blades response was modelled as the combination of a forcing function and a multiple degree of freedom transfer function. Repurposed experimental modal analysis frequency response reconstruction techniques were used to model the blades transfer function. It was found that this technique was able to capture the blades underlying behaviour to a high degree. The forcing function was modelled in the time domain as a series of Gaussian shaped force distributions. It was found that the model was able to capture many important aspects of the forcing behaviour. Both the forcing function and blade transfer function were explored using constrained optimisation techniques. The blade-fluid interaction was modelled as a Fourier series. It was shown that the blade behaviour cannot be extracted from a pressure signal using standard frequency analysis techniques. The viability of an inverse problem solution methodology, for the purpose of blade behaviour extraction, was investigated. This was achieved by solving reduced components of the model with SG measurements and observations from pressure measurements. Further the need to isolate the pressure field about individual blades was motivated and a novel time domain windowing technique provided. en
dc.description.availability Unrestricted en
dc.description.degree MEng en
dc.description.department Mechanical and Aeronautical Engineering en
dc.description.librarian tm2016 en
dc.identifier.citation Church, CB 2015, Turbomachine internal pressure and blade response modelling, MEng Dissertation, University of Pretoria, Pretoria, viewed yymmdd <http://hdl.handle.net/2263/56131> en
dc.identifier.other A2016 en
dc.identifier.uri http://hdl.handle.net/2263/56131
dc.language.iso en en
dc.publisher University of Pretoria en_ZA
dc.rights © 2016 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria.
dc.subject UCTD en
dc.subject Turbomachinery
dc.subject Internal pressure modelling
dc.subject Blade response
dc.subject Aeroelasticity
dc.subject.other Engineering, built environment and information technology theses SDG-09
dc.subject.other SDG-09: Industry, innovation and infrastructure
dc.subject.other Engineering, built environment and information technology theses SDG-07
dc.subject.other SDG-07: Affordable and clean energy
dc.title Turbomachine internal pressure and blade response modelling en
dc.type Dissertation en


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