Global ETD Search

71	Ultrasonic guided wave imaging via sparse reconstruction Levine, Ross M. 22 May 2014 (has links) Structural health monitoring (SHM) is concerned with the continuous, long-term assessment of structural integrity. One commonly investigated SHM technique uses guided ultrasonic waves, which travel through the structure and interact with damage. Measured signals are then analyzed in software for detection, estimation, and characterization of damage. One common configuration for such a system uses a spatially-distributed array of fixed piezoelectric transducers, which is inexpensive and can cover large areas. Typically, one or more sets of prerecorded baseline signals are measured when the structure is in a known state, with imaging methods operating on differences between follow-up measurements and these baselines. Presented here is a new class of SHM spatially-distributed array algorithms that rely on sparse reconstruction. For this problem, damage over a region of interest (ROI) is considered to be sparse. Two different techniques are demonstrated here. The first, which relies on sparse reconstruction, uses an a priori assumption of scattering behavior to generate a redundant dictionary where each column corresponds to a pixel in the ROI. The second method extends this concept by using multidimensional models for each pixel, with each pixel corresponding to a "block" in the dictionary matrix; this method does not require advance knowledge of scattering behavior. Analysis and experimental results presented demonstrate the validity of the sparsity assumption. Experiments show that images generated with sparse methods are superior to those created with delay-and-sum methods; the techniques here are shown to be tolerant of propagation model mismatch. The block-sparse method described here also allows the extraction of scattering patterns, which can be used for damage characterization. Sparse reconstruction Lamb waves Guided waves Structural health monitoring Smart structures Ultrasonic waves Non-destructive evaluation Non-destructive testing Sparse matrices Ultrasonic imaging Ultrasonics Nondestructive testing
72	Simulation numérique du contrôle non-destructif des guides d’ondes enfouis / Numerical modelling of non-destructive testing of buried waveguides Gallezot, Matthieu 22 November 2018 (has links) De nombreux éléments de structures de génie civil sont élancés et partiellement enfouis dans un milieu solide. Les ondes guidées sont souvent utilisées pour le contrôle non destructif (CND) de ces éléments. Ces derniers sont alors considérés comme des guides d’ondes ouverts, dans lesquels la plupart des ondes sont atténuées par des fuites dans le milieu environnant. D’autre part le problème est non borné, ce qui le rend difficile à appréhender sur le plan numérique. La combinaison d’une approche par éléments finis semi-analytique (SAFE) et de la méthode des couches parfaitement adaptées (PML) a été utilisée dans une thèse antérieure pour calculer numériquement trois types de modes (modes piégés, modes à fuite et modes de PML). Seuls les modes piégés et à fuite sont utilisés pour la représentation des courbes de dispersion. Les modes de PML sont non intrinsèques à la physique. L’objectif premier de cette thèse est d’obtenir, par superposition modale sur les modes calculés, les champs émis et diffracté dans les guides d’ondes ouverts. Nous montrons dans un premier temps que les trois types de modes appartiennent à la base modale. Une relation d’orthogonalité est obtenue dans la section du guide(incluant la PML) pour garantir l’unicité des solutions. La réponse forcée du guide peut alors être calculée rapidement par une somme sur les modes en tout point du guide. Des superpositions modales sont également utilisées pour construire des frontières transparentes au bord d’un petit domaine élément fini incluant un défaut, permettant ainsi de calculer le champ diffracté. Au cours de ces travaux, nous étudions les conditions d’approximation des solutions par des superpositions modales, limitées seulement aux modes à fuite, ce qui permet de réduire le coût des calculs. De plus, la généralité des méthodes proposées est démontrée par des calculs hautes fréquences (intéressantes pour le CND) et sur des guides tridimensionnels. Le deuxième objectif de cette thèse est de proposer une méthode d’imagerie pour la localisation de défauts. La méthode de l’imagerie topologique est appliquée aux guides d’ondes. Le cadre théorique général, de type optimisation sous contrainte, est rappelé. Le formalisme modal permet un calcul rapide de l’image. Nous l’appliquons pour simuler un guide d’onde endommagé, et nous montrons l’influence du type de champ émis (monomodal, dispersif,multimodal) ainsi que des configurations de mesure sur la qualité de l’image obtenue. / Various elements of civil engineering structures are elongated and partially embedded in a solid medium. Guided waves can be used for the nondestructive evaluation (NDE) of such elements. The latteris therefore considered as an open waveguide, in which most of waves are attenuated by leakage losses into the surrounding medium. Furthermore, the problem is difficult to solve numerically because of its unboundedness. In aprevious thesis, it has been shown that the semi-analytical finite-element method (SAFE) and perfectly matched layers(PML) can be coupled for the numerical computation of modes. It yields three types of modes: trapped modes,leaky modes and PML modes. Only trapped and leaky modes are useful for the post-processing of dispersion curves. PML modes are non-intrinsic to the physics. The major aim of this thesis is to obtain the propagated and diffracted fields, based on modal superpositions on the numerical modes. First, we show that the three types of modes belong to the modal basis. To guarantee the uniqueness of the solutions an orthogonality relationship is derived on the section including the PML. The forced response can then be obtained very efficiently with a modal expansion at any point of the waveguide. Modal expansions are also used to build transparent boundaries at the cross-sections of a small finite-element domain enclosing a defect, thereby yielding the diffracted field. Throughout this work, we study whether solutions can be obtained with modal expansions on leaky modes only, which enables to reduce the computational cost. Besides, solutions are obtained at high frequencies (which are of interest for NDE) and in tridimensional waveguides, which demonstrates the generality of the methods. The second objective of this thesis is to propose an imaging method to locate defects. The topological imaging method is applied to a waveguide configuration. The general theoretical framework is recalled, based on constrained optimization theory. The image can be quickly computed thanks to the modal formalism. The case of a damaged waveguide is then simulated to assess the influence on image quality of the emitted field characteristics (monomodal, dispersive or multimodal)and of the measurement configuration. Guide ouvert Élément fini Couche parfaitement adaptée Contrôle non-destructif Modes à fuite Réponse forcée Diffraction Imagerie Open waveguide Finite element Perfectly matched layer Non-destructive evaluation Leaky mode Forced response Diffraction Imaging
73	A non-destructive technical and stylistic comparative analysis of selected metal artefacts from the Ditsong national museum of cultural history Harcombe, Aletta Maria 15 November 2018 (has links) Text in English / The destructive nature of conventional analytical techniques, coupled with the finite nature of ancient/historical artefacts, has long restricted technical examinations of museum collections, mainly due to ethical constraints. However, over the past few decades, the application of Non-Destructive Evaluation (NDE) techniques has become increasingly popular within the fields of archaeology and cultural heritage diagnostics. The application of such techniques has facilitated the examination of objects that have long remained uninvestigated. However, this positive development also held a slight drawback, in that researchers tend to now focus on technical analyses alone, while excluding more traditional means of analyses, such as comparative stylistic analysis and surface investigation. By employing a combination of stylistic analysis, visual surface investigation (by means of SLR photography and digital microscopy) and nuclear imaging (by means of Microfocus X-Ray Computed Tomography), the thesis sets out to justify the application of mixed methodologies as part of a more holistic integrated authentication approach. Thus stated, the thesis presents a mixed-methodological approach towards the analysis of selected metal objects from the Ditsong National Museum of Cultural History in Pretoria, South Africa. The objects under investigation include a small collection of ancient Egyptian bronze statuettes, a Samurai helmet (kabuto) and mask (menpó), a European gauntlet, and an Arabian dagger (jambiya/khanjar). While all the objects are curated as part of the museum‘s archaeology and military history collections, the exact production dates, manufacturing techniques and areas of origin remain a mystery. By using a combination of techniques, the thesis aims to identify diagnostic features that can be used to shed light on their relative age, culturo-chronological framework and, by extension, their authenticity. / Old Testament and Ancient Near Eastern Studies / D. Litt. et Phil.(Ancient Near Eastern Studies) Ancient Egyptian bronzes Integrated authentication Jambiya Kabuto Khanjar Menpó Microfocus X-Ray Computed Tomography Mixed method approach Non-Destructive Evaluation 069.968 Museums -- South Africa Museum techniques -- Evaluation Artefacts Helmets Masks (Sculpture) Daggers, Prehistoric -- South Africa Bronze age -- South Africa
74	Multifunctional composite structures with damage sensing capabilities / Πολυλειτουργικές κατασκευές από σύνθετα υλικά με ικανότητα ανίχνευσης βλάβης Μπαλτόπουλος, Αθανάσιος 18 June 2014 (has links) The scope of this thesis is to reveal, identify and investigate promising routes for developing multifunctional composite structures with damage sensing capabilities towards the development of integrated non-destructive inspection (NDI) and structural health monitoring (SHM) capabilities. Two routes were identified and selected for further investigation; the enhancement of multifunctionality of composite systems through the use of nanotechnology and the development of novel damage sensing techniques based on the electrical properties of the composites. Both were selected in the view of better integration of NDI/SHM functionality. Initially, the use of nanotechnology to control the properties of polymer foam systems as part of multifunctional sandwich composite structures has been validated and proven feasible. Electrically conductive nano-composite foams were developed at a varying range of densities. The level of conductivity was controlled by the CNT concentration. The underlying mechanisms for the formation of the CNT network were analyzed closely and as a result a practical processing-structure-property map was proposed for describing the material capabilities. Towards the development of self-sensing functionality, the established electrical conductivity was studied as an index of strain and damage in nano-composite foams. A 1D electrical resistance sensing approach was followed during mechanical compression testing (Electrical Resistance Change Method – ERCM). The variations of the recordings revealed the strain and damage formation within the material. The distinct regions in the response curve were correlated to micro-structural strain and damage mechanisms, effectively demonstrating the capability to develop multifunctional structural materials with self-sensing capabilities. In the direction of novel sensing techniques, answering to the need for an electrical based approach that is transferable and scalable to 2D and even further to more complex 3D shell geometries, the concept of Electrical tomography and the ET inverse problem solution were proposed and studied as a tool for NDI and damage assessment of composite materials. The approach is based on the inherent electrical conductivity of the material and leads the step from conventional 1D electrical sensing to 2D imaging, offering a viable route for utilizing electrical sensing techniques in real applications. The technique delivers a conductivity change map which corresponds to the studied geometry and changes in conductivity are correlated with real damage. For each map, two features were extracted through automated algorithms; the Centre of Interest and the corresponding Region of Interest. It was found that the sensing principle was sensitive enough to extremely small variations of conductivity (less than 0.1% of the inspected area). The post-processing and feature extraction technique was effective in indicating to the location of the developed damage. Taking a step further, the knowledge of the composite material microstructure and expected failure modes have been translated and formulated into an additional mathematical constraint. The formulation is applied to constrain the solution of the ERT inverse problem greatly enhancing the solution and the damage localization in ERT. A concept for merging the two proposed routes for the development of multifunctional structures is then proposed and investigated. The establishment of a conductive 3D network of CNT is exploited using the previously formulated tomographic approaches. The development of a continuous artificial 3D CNT network within the matrix of a structural composite has been shown to provide electrical conductivity to previously non-conductive composites. This 3D network is used for the damage assessment of the composite as any structural damage introduced discontinuities in the 3D network which are located using tomographic approaches. ERT was applied providing 2D imaging for the NDI of composites based on electrical measurements taken from a CNT doped GFRP, effectively sensing variations in the electrical fields and identifying the location of the induced damage. Having shown that ERT can provide useful information on the health/damage state of composite materials, a step further was taken to identify the required steps to apply ERT to larger composite components with more complex geometry. The studied cylindrical component provided a case study to demonstrate the procedure for applying ERT to existing structural components while formulating the ERT inverse problem to cover cases that could not be covered with the up-to-date formulations. In parallel, an alternative approach for post-processing the electrical measurements taken using ET was proposed; the dipole technique. This observational technique was described, formulated and applied to the available experimental data. It was concluded that the dipole technique is effective in delivering a swarm of Damage Estimation Locations which formed convex Region of Interest, effectively locating the damage with small relative error and large inspection area suppression (reaching over 90%). Finally, a practical electrical-based approach was formulated for monitoring a real case of aeronautical component. The goal for monitoring the integrity of composite patch repair on an aluminium component was achieved by proposing a mapping technique to translate distributed 1D electrical measurements to a 2D damage probability map. The proposed approach was formulated theoretically and verified on experimental level under simulated service conditions. It was concluded that the technique can effectively identify the location of damage which was verified by thermographic imaging techniques. This final approach essentially bridges the area between 1D ERCM techniques on specimen level and the ERT approach proposed in this thesis. / Αντικείμενο της παρούσας διατριβής είναι η διερεύνηση, η αναλυτική μελέτη και η αποτίμηση της εφαρμογής νέων υλικών και μεθοδολογιών για την ανάπτυξη πολύ-λειτουργικών κατασκευών από Σύνθετα Υλικά (ΣΥ) με ικανότητα ανίχνευσης βλάβης. Πιο συγκεκριμένα, προτείνονται και μελετώνται δύο κατευθύνσεις: η ανάπτυξη νέων λειτουργιών και η ενίσχυση της πολυ-λειτουργικότητας των συνθέτων υλικών με χρήση νανοτεχνολογίας, και η ανάπτυξη νέων μεθοδολογιών για την ανίχνευση της βλάβης που να είναι βασισμένες στις ηλεκτρικές ιδιότητες του υλικού. Αμφότερες επιλέχθηκαν με στόχο την καλύτερη ενσωμάτωση της ικανότητας ανίχνευσης βλάβης με καινοτόμες μη καταστροφικές μεθόδους. Αρχικά, η χρήση νανοτεχνολογίας και συγκεκριμένα Νανο-Σωλήνων Άνθρακα (ΝΣΑ) για τον έλεγχο των ιδιοτήτων παραγόμενων πολυμερών αφρών ως συνιστώσα πολυλειτουργικών ΣΥ τύπου sandwich προτάθηκε, μελετήθηκε και αποδείχτηκε εφικτή. Αναπτύχθηκε η μεθοδολογία για την παραγωγή και κατασκευή ηλεκτρικά αγώγιμων νανοσύνθετων πολυμερών αφρών ως φορέων πολύ-λειτουργικότητας. Με χρήση τεχνικών διασποράς παρήχθησαν νανοσύνθετου αφροί ενισχυμένοι με Νανο-Σωλήνες Άνθρακα (ΝΣΑ) σε διάφορες περιεκτικότητες ΝΣΑ και πυκνότητες. Η ηλεκτρική αγωγιμότητα των αφρών μελετήθηκε ως προς τους δύο αυτές μεταβλητές και με χρήση στατιστικών μοντέλων περιγράφηκε η τελική ιδιότητα των υλικών. Τέλος, προτείνεται ένας χάρτης συσχέτιση μεταξύ παραμέτρων επεξεργασίας-δομής-ιδιότητας. Έχοντας αναπτύξει ηλεκτρικά αγώγιμους αφρούς, στη συνέχεια μελετήθηκε η εφαρμογή ηλεκτρικών μεθόδων παρακολούθησης για την ανίχνευση παραμόρφωσης και βλάβης σε αυτά τα συστήματα υλικών. Η ευρέως χρησιμοποιούμενη μέθοδος ηλεκτρικής ανίχνευσης Electrical Resistance Change Method (ERCM) διερευνήθηκε και αποδείχθηκε αποτελεσματική για τη αξιολόγηση της αναπτυσσόμενης βλάβης κατά τη διάρκεια πειραμάτων συμπίεσης των αφρών. Βάσει των αποτελεσμάτων προτείνεται μια χαρακτηριστική καμπύλη για το συσχετισμό της ηλεκτρικής μέτρησης και των διαφορετικών σταδίων της μηχανικής απόκρισης. Η καμπύλη αυτή καλύπτει ένα σημαντικό εύρος πυκνοτήτων σε αφρούς. Στην κατεύθυνση των νέων μεθοδολογιών ανίχνευσης βλάβης προτείνεται μια μεθοδολογία που βασίζεται στη διαφοροποίηση του αναπτυσσόμενου ηλεκτρικού πεδίου παρουσία βλάβης και αξιοποιώντας ηλεκτρικές μεθόδους 1-Διάστασης (ERCM) προτείνεται μία μεθοδολογία με εφαρμογή στις 2-Διαστάσεις για την αξιολόγηση βλάβης σε σύνθετα υλικά. Η μέθοδος ERCM έχει χρησιμοποιηθεί με επιτυχία σε μια σειρά από μελέτες μικρής κλίμακας, αλλά οι πραγματικές εφαρμογές της απαιτούν εργαλεία απεικόνισης σε 2-Διαστάσεις και 3-Διαστάσεις για το Μη Καταστροφικό Έλεγχο (ΜΚΕ) των κατασκευών. Το πρόβλημα που τοποθετείτε και επιλύεται είναι αυτό της ανίχνευσης και του εντοπισμού βλάβης σε σύνθετα υλικά με συνεχείς ίνες άνθρακα με χρήση κατανεμημένων μετρήσεων του ηλεκτρικού πεδίου και μεθοδολογιών αντίστροφων προβλημάτων. Περιγράφεται η ιδέα της ηλεκτρικής τομογραφίας με την περιγραφή του ευθέως και του αντιστρόφου προβλήματος. Παρουσιάζεται το σύστημα που αναπτύχθηκε για τους σκοπούς της παρούσας εργασίας και εκτελείται τόσο θεωρητική όσο και πειραματική μελέτη του προβλήματος. Διατυπώνεται η μεθοδολογία επίλυσης του αντίστροφου προβλήματος ηλεκτρικής τομογραφίας και εφαρμόζεται η προκειμένου να υπολογιστούν 2-Δ χάρτες ελέγχου των σύνθετων τμημάτων ως εργαλεία για το ΜΚΕ τους. Η τεχνική αποδεικνύεται ευαίσθητη σε πολύ μικρές βλάβες (<0.1% της παρακολουθούμενης επιφάνειας) και ικανοποιητικά ακριβής στον εντοπισμό της βλάβης καθώς οι εκτιμήσεις της μεθοδολογίας επεξεργασίας αποκλίνουν περίπου 10% από την πραγματική θέση. Η περιοχή ενδιαφέροντος που προσδιορίζεται συμπιέζει έως και 90% την περιοχή ελέγχου. Έχοντας αναδείξει την ευαισθησία και την αποτελεσματικότητα της μεθόδου της Ηλεκτρικής Τομογραφίας στη συνέχεια μελετάται η δυνατότητα συγχώνευσης των δύο προτεινόμενων κατευθύνσεων δηλαδή της χρήση φάσης στη νανο-κλίμακα και ηλεκτρικών τεχνικών παρακολούθηση βλάβης. Διερευνώνται έτσι συνδυαστικές προσεγγίσεις που επιτρέπουν την ανάπτυξη δομικών συστημάτων με ικανότητα ανίχνευσης βλάβης αξιοποιώντας το 3-διάστατο ανεπτυγμένο δίκτυο ΝΣΑ εντός των ΣΥ μέσω ηλεκτρικής τομογραφίας. Η μεθοδολογία επεξεργασίας και διασποράς ΝΣΑ που αναπτύχθηκε προηγούμενα χρησιμοποιείται για την κατασκευή αγώγιμων δομικών πλακών με ίνες γυαλιού. Ηλεκτρική τομογραφία για την ανίχνευση και τον εντοπισμό βλάβης εφαρμόζεται και αξιολογείται η αποτελεσματικότητα της προσέγγισης για ΜΚΕ. Τα αποτελέσματα είναι εξίσου ενθαρρυντικά και επιτυχή αναδεικνύοντας την πρακτικότητα του συστήματος που προτάθηκε. Κατανοώντας την ανάγκη για εφαρμογή της προτεινόμενης τεχνικής ΜΚΕ σε κατασκευές από σύνθετα υλικά μεγαλύτερης κλίμακας και διαφορετικής γεωμετρίας, στη συνέχεια γίνεται μελέτη προς την κατεύθυνση της ωρίμανσης της μεθοδολογίας της Ηλεκτρικής Τομογραφίας. Η μεθοδολογία αναπτύσσεται και εφαρμόζεται σε πειραματικό επίπεδο σε κυλινδρικές δομές. Τα βήματα για τη μετάβαση αυτή από επίπεδες δομές ΣΥ προσδιορίζονται και περιγράφονται ως παράμετροι σχεδιασμού για το σύστημα Ηλεκτρικής Τομογραφίας. Παρουσιάζονται επίσης περιπτώσεις μελέτης μέσω προσομοίωσης καθώς και πειραματικά αποτελέσματα από την εφαρμογή της μεθοδολογίας σε κυλινδρικές δομές από ΣΥ. Μια εναλλακτική προσέγγιση επεξεργασίας των δεδομένων ηλεκτρικής τομογραφίας για τον υπολογισμό σημειακών εκτιμήσεων της θέσης βλάβης προτείνεται και αξιολογείται ακολούθως. Η προτεινόμενη μεθοδολογία βασίζεται στην τεχνική του Ηλεκτρικού Δίπολου και εφαρμόζεται για την ανίχνευση βλάβης στις περιπτώσεις που αναπτύχθηκαν και διερευνήθηκαν προηγούμενα. Γίνεται αναλυτική σύγκριση των αποτελεσμάτων που προέκυψαν με τα υπάρχοντα δεδομένα και αποτιμάται η αποτελεσματικότητα της προτεινόμενης μεθόδου και τα όρια της. Τέλος, η εμπειρία που αποκτήθηκε, τα εργαλεία που αναπτύχτηκαν και η μεθοδολογία που αναπτύχθηκε εφαρμόζεται σε μια πραγματική περίπτωση αεροπορικής δομής. Η περίπτωση που μελετάται είναι αυτή της δομικής ακεραιότητας επιθεμάτων από σύνθετα υλικά που χρησιμοποιήθηκαν για την επισκευή βλάβης σε μεταλλικές κατασκευές από Αλουμίνιο, με χρήση της μεθόδου της ηλεκτρικής τομογραφίας. Η τεχνική που προτείνεται και αξιολογείται χρησιμοποιεί κατανεμημένες ηλεκτρικές μετρήσεις αντίστασης και υπολογίζει έναν διδιάστατο χάρτη του επιθέματος που αποτυπώνει τη χωρική κατανομή της πιθανότητα ύπαρξης βλάβης. Η τεχνική εφαρμόζεται πειραματικά στο κατακόρυφο ουραίο τμήμα ενός ελικοπτέρου και τα αποτελέσματα αξιολογούνται σε σύγκριση με συμβατικές μεθόδους ΜΚΕ. Multifunctional composite structures Nanocomposite foams Carbon nanotubes CFRP Damage sensing Non-destructive evaluation Electrical resistance change method Electrical tomography Dipole techniques Damage mapping 620.115 Νανο-σύνθετοι αφροί Νανοσωλήνες άνθρακα Ανίχνευση βλάβης Ηλεκτρική τομογραφία Τεχνική διπόλου Χαρτογράφηση βλάβης
75	Evaluation and Structural Behavior of Deteriorated Precast, Prestressed Concrete Box Beams Ryan T Whelchel (7874897) 22 November 2019 (has links) Adjacent precast, prestressed box beam bridges have a history of poor performance and have been observed to exhibit common types of deterioration including longitudinal cracking, concrete spalling, and deterioration of the concrete top flange. The nature of these types of deterioration leads to uncertainty of the extent and effect of deterioration on structural behavior. Due to limitations in previous research and understanding of the strength of deteriorated box beam bridges, conservative assumptions are being made for the assessment and load rating of these bridges. Furthermore, the design of new box beam bridges, which can offer an efficient and economical solution, is often discouraged due to poor past performance. Therefore, the objective of this research is to develop improved recommendations for the inspection, load rating, and design of adjacent box beam bridges. Through a series of bridge inspections, deteriorated box beams were identified and acquired for experimental testing. The extent of corrosion was determined through visual inspection, non-destructive evaluation, and destructive evaluation. Non-destructive tests (NDT) included the use of connectionless electrical pulse response analysis (CEPRA), ground penetrating radar (GPR), and half-cell potentials. The deteriorated capacity was determined through structural testing, and an analysis procedure was developed to estimate deteriorated behavior. A rehabilitation procedure was also developed to restore load transfer of adjacent beams in cases where shear key failures are suspected. Based on the understanding of deterioration developed through study of deteriorated adjacent box beam bridges, improved inspection and load rating procedure are provided along with design recommendations for the next generation of box beam bridges. Structural Engineering deteriorated prestressed concrete adjacent concrete box beams strand corrosion bridge inspection longitudinal cracking non-destructive testing ground penetrating radar half-cell potentials visual inspection concrete deterioration destructive evaluation structural testing live-load distribution adjacent box beam bridge rehabilitation concrete deck load rating structural capacity
76	Electron beam powder bed fusion manufacturing of a Ti-5Al-5Mo-5V-3Cr alloy: a microstructure and mechanical properties’ correlation study Hendl, Julius, Marquardt, Axel, Leyens, Christoph 26 February 2024 (has links) Electron beam powder bed fusion (EB-PBF) is a powder-bed fusion additive manufacturing process, which is suitable for fabricating high-performance parts for a wide range of industrial applications, such as medical and aerospace. Due to its deep curing capabilities, the metastable β-alloy Ti-5Al-5Mo-5V-3Cr (Ti-5553) is currently mostly used in the landing gear of airplanes. However, its great mechanical properties make it also attractive for small, complex, and load-bearing components. In this study, nine melting parameter sets, combining different scanning speeds and beam currents, were used in the EB-PBF ARCAM A2X system. Furthermore, the correlation between the microstructure and the mechanical properties was investigated and analyzed by applying µ-focus computer tomography and microscopic methods (optical, SEM/EDS). A significant influence of the different melting parameters on the microstructure as well as on the mechanical performance was found. In a subsequent step, three melting parameters were selected and the specimens were heat-treated (BASCA, STA) for further investigation. The experimental results of this work indicate that Ti-5553 parts can be manufactured successfully with high quality (ρ > 99.60%), and post-processing heat-treatments can be used to modify the microstructure in such a way that the parts are suitable for a large variety of possible applications. info:eu-repo/classification/ddc/670 ddc:670 info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/621.3 ddc:621.3
77	Some Experimental and Numerical Studies on Evaluation of Adhesive Bond Integrity of Composites Lap Shear Joints Vijaya Kumar, R L January 2014 (has links) (PDF) Adhesive bonding which has been in use for long as a traditional joining method has gained ground in the last couple of decades due to the introduction of advanced composite materials into the aerospace industry. Bonded structures have advantages such as high corrosion and fatigue resistance, ability to join dissimilar materials, reduced stress concentration, uniform stress distribution, good damping characteristics etc. They also have certain limitations like environmental degradation, existence of defects like pores, voids and disbonds, difficulty in maintenance and repair etc. A serious drawback in the use of adhesively bonded structures has been that there are no established comprehensive non-destructive testing (NDT) techniques for their evaluation. Further, a reliable evaluation of the effect of the existing defects on strength and durability of adhesive joints is yet to be achieved. This has been a challenge for the research and development community over several decades and hence, been the motivation behind this piece of research work. Under the scope of the work carried out in the thesis, some of the primary factors such as the existence of defects, degradation of the adhesive, stress and strain distribution in the bonded region etc., have been considered to study the bond integrity in composite to composite lap shear joints. The problem becomes complex if all the parameters affecting the adhesive joint are varied simultaneously. Taking this into consideration, one of the key parameters affecting the bond quality, viz., the adhesive layer degradation was chosen to study its effect on the bonded joint. The epoxy layer was added with different, definite amount of Poly vinyl alcohol (PVA) to arrive at sets of bonded joint specimens with varied adhesive layer properties. A thorough review of different non destructive testing methods applied to this particular problem showed that ultrasonic wave based techniques could be the right choice. To start with, preliminary experimental investigations were carried on unidirectional glass fiber reinforced plastic (GFRP-epoxy) lap joints. The adhesive joints were subjected to non destructive evaluation (NDE) using ultrasonic through transmission and pulse echo techniques as also low energy digital X-ray techniques. The results obtained showed a variation in reflected and transmitted ultrasonic pulse amplitude with bond quality. Digital X-Ray radiography technique showed a variation in the intensity of transmitted x-rays due to variation in the density of adhesive. Standard mechanical tests revealed that the addition of PVA decreased the bond strength. A plot of coefficient of reflection from the first interface and the bond strength showed a linear correlation between them. After obtaining a cursory feel and understanding of the parameters involved with the preliminary experiments on GFRP adhesive joints which yielded interesting and encouraging results, further work was carried on specimens made out of autoclave cured carbon fiber reinforced plastic (CFRP)-epoxy bonded joints. Normal incidence ultrasound showed a similar trend. Analyses of the Acoustic Emission (AE) signals generated indicate early AE activity for degraded joints compared to healthy joints. Literary evidences suggest that the ultrasonic shear waves are more sensitive to interfacial degradation. An attempt was made to use oblique incidence ultrasonic interrogation using shear waves. The amplitude of reflected shear waves from the interface increased with an increase in degradation. Further, a signal analysis approach in the frequency domain revealed a shift in the frequency minimum towards lower range in degraded samples. This phenomenon was verified using analytical models. An inversion algorithm was used to determine the interfacial transverse stiffness which decreased significantly due to increase in degradation. Conventional ultrasonic evaluation methods are rendered ineffective when a direct access to the test region is not possible; a different approach with guided wave techniques can be explored in this scenario. Investigations on CFRP-epoxy adhesive joints using Lamb waves showed a decrease in the amplitude of ‘So’ mode in degraded samples. Theoretical dispersion curves exhibited a similar trend. Frequency domain studies on the received modes using Gabor wavelet transform showed a negative shift in frequency with increased degradation. It was also observed that the maximum transmission loss for the most degraded sample with 40 percent PVA occurred in the range of 650 – 800 kHz. Non linear ultrasonic (NLU) evaluation revealed that the nonlinearity parameter (β) increased with increased degradation. Kissing bonds are most commonly occurring type of defects in adhesive joints and are very difficult to characterize. A recent non-contact imaging technique called digital image correlation (DIC) was tried to evaluate composite adhesive joints with varied percentage of inserted kissing bond defects. The results obtained indicate that DIC can detect the kissing bonds even at 50 percent of the failure load. In addition, to different experimental approaches to evaluate the bonded joint discussed above, the effect of degradation on the stresses in the bond line region was studied using analytical and numerical approach. A linear adhesive beam model based on Euler beam theory and a nonlinear adhesive beam model based on Timoshenko beam theory were used to determine the adhesive peel and shear stress in the joint. Digital image correlation technique was used to experimentally obtain the bond line strains and corresponding stresses were computed assuming a plane strain condition. It was found that the experimental stresses followed a similar trend to that predicted by the two analytical models. A maximum peel stress failure criterion was used to predict failure loads. A failure mechanism was proposed based on the observations made during the experimental work. It was further shown that the critical strain energy release rate for crack initiation in a healthy joint is much higher compared to a degraded joint. The analytical models become cumbersome if a larger number of factors have to be taken into account. Numerical methods like finite element analysis are found to be promising in overcoming these hurdles. Numerical investigation using 3D finite element analysis was carried out on CFRP-epoxy adhesive joints. The adherend – adhesive interface was modeled using connector elements whose stiffness properties as well as the bulk adhesive properties for joints with different amounts of PVA were determined using ultrasonic inspection method. The peel and shear stress variation along the adhesive bond line showed a similar trend as observed with the experimental stress distribution (DIC) but with a lesser magnitude. A parametric study using finite element based Monte-Carlo simulation was carried out to assess the effect of variation in various joint parameters like adhesive modulus, bondline thickness, adherend geometrical and material properties on peel and shear stress in the joint. It was found that the adhesive modulus and bond line thickness had a significant influence on the magnitude of stresses developed in the bond line. Thus, to summarize, an attempt has been made to study the bond line integrity of a composite epoxy adhesive lap joint using experimental, analytical and numerical approaches. Advanced NDE tools like oblique incidence ultrasound, non linear ultrasound, Lamb wave inspection and digital image correlation have been used to extract parameters which can be used to evaluate composite bonded joints. The results obtained and reported in the thesis have been encouraging and indicate that in specific cases where the bond line thickness and other relevant parameters if can be maintained or presumed reasonably non variant, it is possible to effectively evaluate the integrity of a composite bonded joint. Adhesive Bonding Composite Lap Joints Adhesive Joints Composite Adhesive Joints Composite Lap Shear Joints Composite Epoxy Adhesive Lap Joints Composite Bonded Joints Aerospace Composites Composite Lap Joints Composite Single Lap Joint Composite Adhesively Bonded Joints Composite Adhesive Lap Joints Composite Single-lap Joints Adhesively Bonded Joints Single Lap Shear Joints Adhesively Bonded Composite Lap Joints Adhesive Bond Integrity Aerospace Engineering
78	Etude de champs de température séparables avec une double décomposition en valeurs singulières : quelques applications à la caractérisation des propriétés thermophysiques des matérieux et au contrôle non destructif / Study of separable temperatur fields with a double singular value decomposition : some applications in characterization of thermophysical properties of materials and non destructive testing Ayvazyan, Vigen 14 December 2012 (has links) La thermographie infrarouge est une méthode largement employée pour la caractérisation des propriétés thermophysiques des matériaux. L’avènement des diodes laser pratiques, peu onéreuses et aux multiples caractéristiques, étendent les possibilités métrologiques des caméras infrarouges et mettent à disposition un ensemble de nouveaux outils puissants pour la caractérisation thermique et le contrôle non desturctif. Cependant, un lot de nouvelles difficultés doit être surmonté, comme le traitement d’une grande quantité de données bruitées et la faible sensibilité de ces données aux paramètres recherchés. Cela oblige de revisiter les méthodes de traitement du signal existantes, d’adopter de nouveaux outils mathématiques sophistiqués pour la compression de données et le traitement d’informations pertinentes. Les nouvelles stratégies consistent à utiliser des transformations orthogonales du signal comme outils de compression préalable de données, de réduction et maîtrise du bruit de mesure. L’analyse de sensibilité, basée sur l’étude locale des corrélations entre les dérivées partielles du signal expérimental, complète ces nouvelles approches. L'analogie avec la théorie dans l'espace de Fourier a permis d'apporter de nouveaux éléments de réponse pour mieux cerner la «physique» des approches modales.La réponse au point source impulsionnel a été revisitée de manière numérique et expérimentale. En utilisant la séparabilité des champs de température nous avons proposé une nouvelle méthode d'inversion basée sur une double décomposition en valeurs singulières du signal expérimental. Cette méthode par rapport aux précédentes, permet de tenir compte de la diffusion bi ou tridimensionnelle et offre ainsi une meilleure exploitation du contenu spatial des images infrarouges. Des exemples numériques et expérimentaux nous ont permis de valider dans une première approche cette nouvelle méthode d'estimation pour la caractérisation de diffusivités thermiques longitudinales. Des applications dans le domaine du contrôle non destructif des matériaux sont également proposées. Une ancienne problématique qui consiste à retrouver les champs de température initiaux à partir de données bruitées a été abordée sous un nouveau jour. La nécessité de connaitre les diffusivités thermiques du matériau orthotrope et la prise en compte des transferts souvent tridimensionnels sont complexes à gérer. L'application de la double décomposition en valeurs singulières a permis d'obtenir des résultats intéressants compte tenu de la simplicité de la méthode. En effet, les méthodes modales sont basées sur des approches statistiques de traitement d'une grande quantité de données, censément plus robustes quant au bruit de mesure, comme cela a pu être observé. / Infrared thermography is a widely used method for characterization of thermophysical properties of materials. The advent of the laser diodes, which are handy, inexpensive, with a broad spectrum of characteristics, extend metrological possibilities of infrared cameras and provide a combination of new powerful tools for thermal characterization and non destructive evaluation. However, this new dynamic has also brought numerous difficulties that must be overcome, such as high volume noisy data processing and low sensitivity to estimated parameters of such data. This requires revisiting the existing methods of signal processing, adopting new sophisticated mathematical tools for data compression and processing of relevant information.New strategies consist in using orthogonal transforms of the signal as a prior data compression tools, which allow noise reduction and control over it. Correlation analysis, based on the local cerrelation study between partial derivatives of the experimental signal, completes these new strategies. A theoretical analogy in Fourier space has been performed in order to better understand the «physical» meaning of modal approaches.The response to the instantaneous point source of heat, has been revisited both numerically and experimentally. By using separable temperature fields, a new inversion technique based on a double singular value decomposition of experimental signal has been introduced. In comparison with previous methods, it takes into account two or three-dimensional heat diffusion and therefore offers a better exploitation of the spatial content of infrared images. Numerical and experimental examples have allowed us to validate in the first approach our new estimation method of longitudinal thermal diffusivities. Non destructive testing applications based on the new technique have also been introduced.An old issue, which consists in determining the initial temperature field from noisy data, has been approached in a new light. The necessity to know the thermal diffusivities of an orthotropic medium and the need to take into account often three-dimensional heat transfer, are complicated issues. The implementation of the double singular value decomposition allowed us to achieve interesting results according to its ease of use. Indeed, modal approaches are statistical methods based on high volume data processing, supposedly robust as to the measurement noise. Thermographie infrarouge Contrôle non destructif CND Techniques inverses Caractérisation thermique Analyse en composantes principales PCA Diffusion thermique tridimensionnelle Méthode flash Flash face avant Diodes laser Point source impulsionnel Méthodes modales Analyse de corrélations Compression de données Transformations orthogonales du signal Champs de température séparables Séparabilité spatiale Transformées de Fourier Filtrage de données Matériaux hétérogènes Petites échelles Matériaux composites Infrared thermography Non destructive testing NDT Non destructive evaluation NDE Inverse techniques Thermal characterization Singular value decomposition SVD Double singular value decomposition 2SVD Principal component analysis PCA Singular value expansion SVE Estimation of thermophysical properties Estimation of initial temperature fields Three-dimensional heat diffusion Flash method Laser diodes Instantaneous point source of heat Correlation analysis Data compression Orthogonal transforms of the signal Separable temperature fields High volume data processing Fourier transforms Data filtering Heterogeneous materials Small scales Composite materials

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