Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage

Advanced composites offer robust mechanical properties and are widely used for structural applications in the aerospace, marine, defense and transportation industries. However, the inhomogenous nature of composite materials leaves them susceptible to problematic failure; thus the development of a me...

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Other Authors: Dickens, Tarik J. (authoraut)
Format: Others
Language:English
English
Published: Florida State University
Subjects:
Online Access:http://purl.flvc.org/fsu/fd/FSU_migr_etd-7772
id ndltd-fsu.edu-oai-fsu.digital.flvc.org-fsu_253332
record_format oai_dc
collection NDLTD
language English
English
format Others
sources NDLTD
topic Industrial engineering
Production engineering
spellingShingle Industrial engineering
Production engineering
Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage
description Advanced composites offer robust mechanical properties and are widely used for structural applications in the aerospace, marine, defense and transportation industries. However, the inhomogenous nature of composite materials leaves them susceptible to problematic failure; thus the development of a means for detecting failure is imperative. Damage occurs when a load is applied and a distortion of the solid material results in deformation. This process also results in straining of the material. Strain, however, is a physical result of work being performed on a solid material making energy the commonality among all failure mechanisms. This study investigated the feasibility of using Triboluminescent zinc-sulphide manganese (ZnS:Mn) phosphors concentrated in vinyl ester resin for damage monitoring of polymer composites under flexural loading. These particulates react to straining or fracturing by emitting light of varied luminous intensity and detecting the crack initiation presently leading to catastrophic failure(s). Unreinforced vinyl ester resins and fiber-reinforced composite beams incorporated 5 - 50 % wt. concentrations of TL fillers, and were subjected to three-point bend tests. The intent of flexural testing was to observe the transient response of triboluminescence (TL) in both two- and three-phase composite systems throughout the failure cycle of notched beams, while changing the geometric constraints. Results indicate TL crystals emit light at various intensities corresponding to crystal concentration, the notch-length and imminent matrix fracture. The fracturing or deformation energy was estimated by the method of J-integral with varied notch-lengths, where a lower threshold for excitation was found to be approximately <2 J/m^2, far below its critical fracture energy (~ 3 & 7 J/m^2). Consequently, concentrated samples showed nearly 50 % reductions of mechanical moduli due to high loading levels, which subsequently affected the Triboluminescent response. As a result, an optimal 6 % vol. of TL particulates was chosen for further study and exhibited significant signal-to-noise response. Scanning electron microscopy (SEM) revealed particulate inclusions with shearing bands and semblance of particle to resin adhesion, as well as, cases of micro-cracking in reinforced samples. Despite significant parasitic affect to mechanical properties, the luminescent properties of TL occur at rupture for unreinforced composites. The cases of TL concentrated reinforced composites show detection of localized matrix phenomenon which are related to the material response and incurring internal strain-energy prior to any catastrophic failure. This indicates that TL in composite systems has the potential to detect micro-failures (micro-cracks) related to the weak matrix component. The triboluminescent signal was simulated as a rate-dependent model considering the load profile of the composite beam is known. === A Dissertation submitted to the Department of Industrial and Manufacturing Engineering in partial fulfillment of the requirements for the degree of Doctor of Philosophy. === Spring Semester, 2013. === April 4, 2013. === Composites, Damage Sensors, Intrinsic, Multifunctional Materials, Structural Health Monitoring, Triboluminescence === Includes bibliographical references. === Okenwa Okoli, Professor Directing Dissertation; Naresh Dalal, University Representative; Ted Liu, Committee Member; Richard Liang, Committee Member.
author2 Dickens, Tarik J. (authoraut)
author_facet Dickens, Tarik J. (authoraut)
title Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage
title_short Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage
title_full Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage
title_fullStr Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage
title_full_unstemmed Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage
title_sort assessment of triboluminescent materials for intrinsic health monitoring of composite damage
publisher Florida State University
url http://purl.flvc.org/fsu/fd/FSU_migr_etd-7772
_version_ 1719321909743583232
spelling ndltd-fsu.edu-oai-fsu.digital.flvc.org-fsu_2533322020-06-19T03:08:37Z Assessment of Triboluminescent Materials for Intrinsic Health Monitoring of Composite Damage Dickens, Tarik J. (authoraut) Okoli, Okenwa (professor directing dissertation) Dalal, Naresh (university representative) Liu, Ted (committee member) Liang, Richard (committee member) Department of Industrial and Manufacturing Engineering (degree granting department) Florida State University (degree granting institution) Text text Florida State University Florida State University English eng 1 online resource computer application/pdf Advanced composites offer robust mechanical properties and are widely used for structural applications in the aerospace, marine, defense and transportation industries. However, the inhomogenous nature of composite materials leaves them susceptible to problematic failure; thus the development of a means for detecting failure is imperative. Damage occurs when a load is applied and a distortion of the solid material results in deformation. This process also results in straining of the material. Strain, however, is a physical result of work being performed on a solid material making energy the commonality among all failure mechanisms. This study investigated the feasibility of using Triboluminescent zinc-sulphide manganese (ZnS:Mn) phosphors concentrated in vinyl ester resin for damage monitoring of polymer composites under flexural loading. These particulates react to straining or fracturing by emitting light of varied luminous intensity and detecting the crack initiation presently leading to catastrophic failure(s). Unreinforced vinyl ester resins and fiber-reinforced composite beams incorporated 5 - 50 % wt. concentrations of TL fillers, and were subjected to three-point bend tests. The intent of flexural testing was to observe the transient response of triboluminescence (TL) in both two- and three-phase composite systems throughout the failure cycle of notched beams, while changing the geometric constraints. Results indicate TL crystals emit light at various intensities corresponding to crystal concentration, the notch-length and imminent matrix fracture. The fracturing or deformation energy was estimated by the method of J-integral with varied notch-lengths, where a lower threshold for excitation was found to be approximately <2 J/m^2, far below its critical fracture energy (~ 3 & 7 J/m^2). Consequently, concentrated samples showed nearly 50 % reductions of mechanical moduli due to high loading levels, which subsequently affected the Triboluminescent response. As a result, an optimal 6 % vol. of TL particulates was chosen for further study and exhibited significant signal-to-noise response. Scanning electron microscopy (SEM) revealed particulate inclusions with shearing bands and semblance of particle to resin adhesion, as well as, cases of micro-cracking in reinforced samples. Despite significant parasitic affect to mechanical properties, the luminescent properties of TL occur at rupture for unreinforced composites. The cases of TL concentrated reinforced composites show detection of localized matrix phenomenon which are related to the material response and incurring internal strain-energy prior to any catastrophic failure. This indicates that TL in composite systems has the potential to detect micro-failures (micro-cracks) related to the weak matrix component. The triboluminescent signal was simulated as a rate-dependent model considering the load profile of the composite beam is known. A Dissertation submitted to the Department of Industrial and Manufacturing Engineering in partial fulfillment of the requirements for the degree of Doctor of Philosophy. Spring Semester, 2013. April 4, 2013. Composites, Damage Sensors, Intrinsic, Multifunctional Materials, Structural Health Monitoring, Triboluminescence Includes bibliographical references. Okenwa Okoli, Professor Directing Dissertation; Naresh Dalal, University Representative; Ted Liu, Committee Member; Richard Liang, Committee Member. Industrial engineering Production engineering FSU_migr_etd-7772 http://purl.flvc.org/fsu/fd/FSU_migr_etd-7772 This Item is protected by copyright and/or related rights. You are free to use this Item in any way that is permitted by the copyright and related rights legislation that applies to your use. For other uses you need to obtain permission from the rights-holder(s). The copyright in theses and dissertations completed at Florida State University is held by the students who author them. http://diginole.lib.fsu.edu/islandora/object/fsu%3A253332/datastream/TN/view/Assessment%20of%20Triboluminescent%20Materials%20for%20Intrinsic%20Health%20Monitoring%20of%20Composite%20Damage.jpg