The analysis and optimization of an axial compressor

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hamman_analysis_2015.pdf(6.32 MB)
Date
2015-12
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Stellenbosch : Stellenbosch University
Abstract
ENGLISH ABSTRACT: Axial compressors are widely used in a variety of contexts. When compared to centrifugal compressors, axial compressors offer higher pressure ratios and efficiencies. Due to the complex relationship between blade shape and compressor performance, as well as the sensitivity of axial compressors to massflow rates, the design of an axial compressor is a challenging problem. These design difficulties can be circumvented using numerical design optimization. In this work, meta-model based design optimization (MBDO), a variant of numerical design optimization, is used to develop replacement blades for a low speed axial compressor. Two numerical models were developed: a low fidelity, computationally inexpensive single stage model and a high fidelity, computationally expensive three stage model. For reasons of computational cost, the single stage model was used to evaluate the objective function in the optimization process. An optimized blade design was developed, which delivered a 9:83% increase in pressure coefficient over the original design, when evaluated with the single stage model. This increase was not sustained when evaluating the optimized design with the three stage model. After investigation, the cause was found to be a high incidence angle near the hub and shroud, just outside the range in which incidence angle was constrained in the design problem. To compensate for this, the blade angles were manually adjusted, in order to lower the incidence angle. The adjusted blades delivered an increase of 8:54% over the original design, when evaluated with the three stage model.
AFRIKAANSE OPSOMMING: Aksiale kompressors word benut in 'n wye verskeidenheid omgewings. In vergelyking met sentrifugale kompressors bied aksiale kompressors hoër werksverrigting en doeltreffendheid. Die komplekse verhouding tussen lemvorm en kompressorwerkverrigting sowel as die sensitiwiteit van aksiale kompressors vir massavloeitempo maak die ontwerp van 'n aksiale kompressor 'n uitdagende taak. Hierdie ontwerpsuitdagings kan omseil word deur van numeriese ontwerpsoptimering gebruik te maak. In hierdie werk word metamodel gebaseerde ontwerpsoptimering (MBDO), 'n variasie van numeriese ontwerpsoptimering, gebruik om nuwe lemme vir 'n lae-spoed aksiale kompressor te ontwerp. Twee numeriese modelle was ontwerp: 'n lae- akkuraatheid, lae-berekeningskoste enkel stadium model, en 'n hoë-akkuraatheid, hoë- berekeningskoste drie-stadium model. As 'n gevolg van berekeningskostes is die enkel stadium model gebruik om die doel funksie in die optimeringsproses te evalueer. 'n Optimale lemontwerp is ontwikkel wat 'n verhoging van 9.83% in die druk-koëffisiënt toon teenoor die oorspronklike ontwerp indien dit met die enkel stadium model ge-evalueer word. Hierdie verbetering is nie sigbaar met die evaluasie van die drie-stadium model nie. Die oorsaak hiervoor was 'n hoë invalshoek naby die middelpunt en deelspanmantel wat net buite die omvang van die invalshoek se beperkinge in die ontwerpsprobleem was. As kompensasie hiervoor, is die lemhoeke aangepas om die invalshoek te verminder. Die aangepaste lemme toon 'n verhoging van 8.54% teenoor die oorspronklike ontwerp as dit met die drie-stadium model ge-evalueer word.
Description
Thesis (MSc)--Stellenbosch University, 2015.
Keywords
Axial compressor -- Analysis, Axial compressor -- Optimization, Meta-model based design optimization (MBDO), UCTD
Citation
URI
http://hdl.handle.net/10019.1/97936
Collections
Masters Degrees (Mechanical and Mechatronic Engineering)