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Characterising material models for silicone-rubber using an inverse finite element model updating method

Thesis (MEng)--Stellenbosch University, 2018.

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Bibliographic Details
Main Author:	Du Toit, Viljoen
Other Authors:	Venter, Gerhard
Format:	Thesis
Language:	en_ZA
Published:	Stellenbosch : Stellenbosch University 2018
Subjects:	Finite element method Silicone rubber > Materials Numerical optimisation UCTD Generalized inverses
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access_status_str	Open Access
author	Du Toit, Viljoen
author2	Venter, Gerhard
author_browse	Du Toit, Viljoen Venter, Gerhard
author_facet	Venter, Gerhard Du Toit, Viljoen
author_sort	Du Toit, Viljoen
collection	Thesis
dc_rights_str_mv	Stellenbosch University
description	Thesis (MEng)--Stellenbosch University, 2018.
format	Thesis
id	oai:scholar.sun.ac.za:10019.1/103750
institution	Stellenbosch University (South Africa)
language	en_ZA
last_indexed	2026-06-10T12:47:08.513Z
license_str	Other — see source repository
provenance_str_mv	Harvested via OAI-PMH from SUNScholar — Stellenbosch University Repository
publishDate	2018
publishDateRange	2018
publishDateSort	2018
publisher	Stellenbosch : Stellenbosch University
publisherStr	Stellenbosch : Stellenbosch University
record_format	dspace
source_str	SUNScholar — Stellenbosch University Repository
spelling	oai:scholar.sun.ac.za:10019.1/103750 Characterising material models for silicone-rubber using an inverse finite element model updating method Du Toit, Viljoen Venter, Gerhard Stellenbosch University. Faculty of Engineering. Dept. of Mechanical and Mechatronic Engineering. Finite element method Silicone rubber -- Materials Numerical optimisation UCTD Generalized inverses Thesis (MEng)--Stellenbosch University, 2018. ENGLISH ABSTRACT: Silicone-rubber was investigated and its mechanical behaviour was characterised. Uni-axial tensile tests were conducted on two different sample geometries: rectangular flat strip and dumbbell shaped. Bi-axial bubble inflation tests were done on membranes and unconstrained uni-axial compression tests were conducted on cylindrical samples. Two identification methods were incorporated to determine three constitutive hyper-elastic material models from every experimental test: the direct and inverse. The direct method is the more traditional approach, where experimental data is used with a least squares fit to determine the constants that govern the material model. The inverse method is fundamentally different, it requires a finite element (FE) model and experimental results. The experimental results are used as boundary conditions in the FE model. Numerical optimisation is then used to obtain the material model constants that minimise the error between the FE model and the experimental results. The material models investigated in this thesis include the Mooney-Rivlin two- and three parameter models along with the Ogden three parameter model. Finally, an independent validation test was done, with a complex stress state. The validation test along with the extrapolation of each material model into all three stress states (uni-axial tension, -compression and bi-axial tension), served as the criteria to determine the best material model and identification method. It was found that the Mooney-Rivlin three parameter model obtained from uni-axial tensile tests (both sample geometries) using both the direct and inverse FE model updating method delivered the best results. However, additional user-input constraints were needed for the direct method (inverse method required no constraints) to obtain a material model that predicted feasible material behaviour. AFRIKAANSE OPSOMMING: Silikoon-rubber is ondersoek ten einde sy meganiese gedrag te karakteriseer. Eenassige trektoetse was uitgevoer op twee verskillende steekproef geometrieë: reghoekige plat strook en ’n hondebeen vorm. Verder was tweeassige borrel-inflasietoetse op membrane uitgevoer, asook onbeperkte eenassige druktoetse op silindriese monsters. Twee identifikasiemetodes is gebruik om drie hiperelastiese-materiaalmodelle vanaf elke eksperimentele toets te bepaal: die direkte en die inverse metodes. Die direkte metode is die meer tradisionele benadering waar eksperimentele data gebruik word met ’n minste vierkante passing om die konstantes wat die materiaalmodel beheer, te bepaal. Die inverse metode verskil fundamenteel hiervan deurdat dit ’n eindige element model tesame met die eksperimentele resultate vereis. Die eksperimentele resultate word as grensvoorwaardes vir die eindige element model gebruik. Numeriese optimering word dan gebruik om die materiaalmodel se konstantes te bepaal wat die fout tussen die eindige element model en die eksperimentele resultate minimeer. Die materiaalmodelle wat ondersoek is sluit in, die Mooney- Rivlin twee- en drie parametermodelle, sowel as die Ogden drie-parameter model. Tenslotte was ’n onafhanklike trektoets met ’n komplekse spanningstoestand uitgevoer om die modelle te valideer. Die valideringstoets saam met die ekstrapolasie van elke materiaalmodel in al drie spanningstoestande (eenassige spanning, -druk en tweeassige spanning) dien as die kriteria om die beste materiaalmodel en identifikasiemetode te bepaal. Daar was bevind dat die drie-parametermodel van Mooney-Rivlin, verkry vanaf eenasige trektoetse (vir beide steekproef geometrieë) met behulp van beide die direkte metode en die inverse eindige element model opdateringsmetode, die beste resultate gelewer het. Daar word egter addisionele beperkings benodig vir die gebruik van die direkte metode (teenoor die inverse metode wat geen beperkings vereis nie) ten einde ’n wesenlike model te verkry, wat logiese materiaalgedrag voorspel. 2018-02-28T19:18:56Z 2018-04-09T07:08:24Z 2018-02-28T19:18:56Z 2018-04-09T07:08:24Z 2018-03 Thesis http://hdl.handle.net/10019.1/103750 en_ZA Stellenbosch University 120 pages : illustrations application/pdf Stellenbosch : Stellenbosch University
spellingShingle	Finite element method Silicone rubber -- Materials Numerical optimisation UCTD Generalized inverses Du Toit, Viljoen Characterising material models for silicone-rubber using an inverse finite element model updating method
title	Characterising material models for silicone-rubber using an inverse finite element model updating method
title_full	Characterising material models for silicone-rubber using an inverse finite element model updating method
title_fullStr	Characterising material models for silicone-rubber using an inverse finite element model updating method
title_full_unstemmed	Characterising material models for silicone-rubber using an inverse finite element model updating method
title_short	Characterising material models for silicone-rubber using an inverse finite element model updating method
title_sort	characterising material models for silicone rubber using an inverse finite element model updating method
topic	Finite element method Silicone rubber -- Materials Numerical optimisation UCTD Generalized inverses
url	http://hdl.handle.net/10019.1/103750
work_keys_str_mv	AT dutoitviljoen characterisingmaterialmodelsforsiliconerubberusinganinversefiniteelementmodelupdatingmethod

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Characterising material models for silicone-rubber using an inverse finite element model updating method

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