Please use this identifier to cite or link to this item: http://hdl.handle.net/10603/16740
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dc.coverage.spatialMechanical Engineeringen_US
dc.date.accessioned2014-03-04T10:47:32Z-
dc.date.available2014-03-04T10:47:32Z-
dc.date.issued2014-03-04-
dc.identifier.urihttp://hdl.handle.net/10603/16740-
dc.description.abstractComposite materials are among the strongest, lightest and stiffest corrosion-resistant materials widely used in aerospace, marine, civil and automotive industries. Damage in composite materials can be localized to one of the constituents or affect the structure as a whole. There are several methods of characterizing internal damage within composite materials. One of the most widely used nondestructive methods is Acoustic Emission (AE), which is defined as the release of transient elastic waves in solids as a result of rapid localized redistributions of stresses which accompany the operation of damage mechanisms . AE can evaluate damage by detecting the emitting strain energy when elastic waves are generated by the generation and growth of a crack, plastic deformation, fiber breakage, matrix cleavage, or delamination. The structural complexity of composites and the presence of friction-related emissions, produced during mutual rubbing of evolving damage surfaces and fretting of broken fibers with matrix, which may conceal emissions from actual damage. The overall goal of this thesis is to characterize the damages in composite laminate and joint, predicting residual strength using AE. This aim can be reached using either of the experimental approaches described below or a combination of them. The first approach involves the measurement of a number of parameters from the AE wave, divided into signals using appropriate time settings disposed on the AE system (multi parameter approach). The second approach is based on the extraction of frequency content from AE wave with appropriate algorithms, the simplest of these being Fast Fourier Transform (FFT). Laminates with different stacking sequences such as (00, 900, angleply (+450/-450) and cross ply (00/900) are used to trigger different failure mechanisms. From AE data of specimens subjected to tensile load, three different frequency content are identified which are related to matrix cracking (90-100kHz), delamination (130-200kHz)en_US
dc.format.extentxxxiii,210p.en_US
dc.languageEnglishen_US
dc.relation178en_US
dc.rightsuniversityen_US
dc.titleCharacterization of failure modes in GFRP laminates and analysis of composite joints by acoustic emission monitoringen_US
dc.creator.researcherAsokan Ren_US
dc.subject.keywordAcoustic Emissionen_US
dc.subject.keywordComposite materialsen_US
dc.subject.keywordFast Fourier Transformen_US
dc.subject.keywordGFRP laminatesen_US
dc.subject.keywordMechanical Engineeringen_US
dc.description.noteAppendix p.177-189, References p.190-207en_US
dc.contributor.guideJoseph stanley Aen_US
dc.contributor.guideDhanaraj Ren_US
dc.publisher.placeChennaien_US
dc.publisher.universityAnna Universityen_US
dc.publisher.institutionFaculty of Mechanical Engineeringen_US
dc.date.registeredn.d.en_US
dc.date.completed01/09/2013en_US
dc.date.awarded30/09/2013en_US
dc.format.dimensions21cmen_US
dc.format.accompanyingmaterialNoneen_US
dc.source.universityUniversityen_US
dc.type.degreePh.D.en_US
Appears in Departments:Faculty of Mechanical Engineering

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01_title.pdfAttached File25.91 kBAdobe PDFView/Open
02_certificates.pdf559.84 kBAdobe PDFView/Open
03_abstracts.pdf10.77 kBAdobe PDFView/Open
04_acknowledgement.pdf6.84 kBAdobe PDFView/Open
05_contents.pdf62.84 kBAdobe PDFView/Open
06_chapter 1.pdf346.99 kBAdobe PDFView/Open
07_chapter 2.pdf258.08 kBAdobe PDFView/Open
08_chapter 3.pdf1.96 MBAdobe PDFView/Open
09_chapter 4.pdf10.59 MBAdobe PDFView/Open
10_chapter 5.pdf22.14 kBAdobe PDFView/Open
11_appendix.pdf1.16 MBAdobe PDFView/Open
12_references.pdf67.07 kBAdobe PDFView/Open
13_publications.pdf9.87 kBAdobe PDFView/Open
14_vitae.pdf7.36 kBAdobe PDFView/Open


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