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361	Etude expérimentale et modélisation de l'endommagement du contact aube-disque de soufflante soumis à des chargements de fretting fatigue Meriaux, Jean 02 July 2010 (has links) L’optimisation du dimensionnement des structures passe par une meilleure connaissance de leur mode d’endommagement. Cette étude se focalise donc sur la caractérisation de l’endommagement du contact aube/disque des moteurs aéronautique. Cet assemblage mécanique est soumis a une combinaison d’un effort normal (force centrifuge) et tangentiel (dynamique de l’aube). La portée du disque en Ti-6Al-4V subi donc un chargement complexe de type fretting fatigue. Ce type de sollicitation entraine, entre autre dégradation, de la fissuration dont la modélisation expérimentale et numérique est rendue difficile par les limitations des moyens et des connaissances actuelles. Le premier objectif de ce travail de thèse est de développer un moyen d’essai et une instrumentation associée afin d’étudier de façon qualitative et quantitative la fissuration d’un contact Ti-6Al-4V/Ti-6Al-4V. Le second but est d’utiliser les données issues de ce moyen expérimental afin de proposer un modèle de prédiction des durées de vie de cet assemblage. Un montage inédit de fretting fatigue double vérin mono-contact a été mis en place avec une instrumentation nouvelle pour ce type d’essai : suivi de fissuration par suivi de potentiel et par émission acoustique. Une attention particulière a été apportée aux calibrations et aux méthodologies expérimentales. Ce banc d’essai permet notamment de simuler des efforts de fretting applique en phase ou alors de telle manière a simuler un vrai cycle de vol. Cet outil a permis de décrire quantitativement les premières courbes de Wohler en fretting à amorçage (Effort de fretting vs Nombre de cycles à amorçage) pour deux configurations de contact (cylindre/plan et plan/plan). Les impacts des différents paramètres de fretting sur l’amorcage ont pu être quantifies. Les paramètres influant sont : la configuration du contact, les niveaux des efforts appliques et leur mode de combinaison (cycles en phase ou cycles de type vol). De plus des courbes de cinétique de propagation des fissures ont pu être extraites des différents essais, montrant un fort impact du fretting sur les vitesses de propagation des fissures. Une analyse qualitative via l’émission acoustique a montré un mécanisme d’amorçage et de propagation en 3 étapes suivant la perte d’influence du contact. Un modèle de prédiction de l’amorçage et de simulation de la propagation des fissures a été mis en place. Bien que limite dans la prise en compte des effets gradients (approches non locales), ce modèle se montre très performant surtout dans sa capacité à utiliser les données expérimentales dans l’identification des lois d’amorçage ou de propagation. Ce travail a donc permis d’importantes avancées dans la compréhension des mécanismes de fissuration et dans leur modélisation ouvrant ainsi la porte vers une prédiction fiable de l’endommagement des contacts aube/disque. / Optimization of structures design requires a better understanding of their damage process. This study focuses on the characterisation of the blade/disk contact damaging process on aircraft engines. That mechanical structure is subjected to a normal load (centrifugal forces) combined with a tangential force (blade dynamic). Thus the Ti-6Al-4V disk seat sees a complex fretting fatigue loading. This type of solicitation can generate a series of degradations like cracking. Experimental and numerical simulation of this damaging is very difficult considering the present state of arts. The first aim of this work is to develop a new experimental set-up with the appropriate instrumentation in order to conduct a qualitative and a quantitative analysis of the cracking in a Ti-6Al-4V/Ti6-Al-4V contact. The second goal is to build a life prediction numerical model that would be able to use the data obtain with the new experimental tests. The new dual-actuator fretting-fatigue set-up is now operational. It allows to run single contact test under different loading combinations: fretting and fatigue loads can be applied in phase or in a way to simulate the real ‘in flight’ conditions. New instrumentations have been added in order to follow the crack initiation and propagation: potential-drop technique and acoustic emission. Thanks to this new test procedure, the first fretting Wöhler curve to crack nucleation have been described (fretting load vs number of cycles to crack nucleation) for two contact geometries (cylinder on flat and flat on flat). The separate influences of fatigue and fretting parameters have been determined. The mains parameters are: the contact characteristics, the stress level and the force combination modes (‘in phase’ cycles or ‘in-flight’ cycles). Moreover, the very first crack propagation kinetics have been drowned. Also, a major influence of the fretting on the crack propagation has been exposed. The qualitative analysis conducted with the acoustic emission has revealed a three steps crack propagation process. The crack propagation process evolves with the decrease of the contact influence. A model has been developed in order to predict crack initiation and propagation lives. Even if the model suffers from a major limitation due to the difficult considerations of the stress gradient effects, it has shown very good results through its ability to directly include experimental data. This work has led to major breakthroughs in the understanding of the cracking mechanisms and their simulation. This forms solid foundations for future predictions of the blade/disk interface durability. Fretting fatigue Glissement partiel Amorçage des fissures Propagation des fissures Suivi de fissuration Cartes de fretting fatigue Cinétiques de propagation Emission acoustique Modélisation Eléments finis Ti-6A1-4V Fretting fatigue Partial slip conditions Crack nucleation Crack propagation Crack propagation following Fretting fatigue map Crack propagation kinetic Acoustic emission Modelling Finite elements Ti-6A1-4V
362	Compréhension de la fragilité des composites PVC/bois par l'étude des relations microstructure/propriétés mécaniques et des mécanismes d'endommagement / Comprehension of PVC/wood flour composites brittleness analysis of the relations between microstructure, mechanical properties ans failure mechanisms Balamoutoff, Alexia 13 March 2012 (has links) Ce travail de thèse a pour objectif de comprendre la fragilité des composites à matrice polymère (PVC) contenant des particules de bois. Dans un premier temps, il s’agit d’examiner le rôle de chacun des constituants : matrice et charge, sur les propriétés mécaniques du composite. Cette étude a montré que l’influence des paramètres relatifs à la microstructure de la matrice PVC est minoritaire face à celle des paramètres de la farine de bois. Pour mettre en évidence le rôle des particules de bois, une méthode d’analyse de leur dispersion et leur orientation par une technique 3D non destructive, a été employée : la tomographie aux rayons X. Un traitement spécifique des données a permis de quantifier la taille, l’orientation et la connectivité des particules. Ainsi, on a montré que l’existence d’agglomérats et/ou d’un réseau percolant fragilise fortement le composite ce qui explique la chute de la résistance au choc lorsque le taux de farine de bois augmente. Pour optimiser le compromis fragilité/ductilité, différentes solutions ont été envisagées. Dans un deuxième temps, nos travaux s'intéressent à l'évolution de l'endommagement de matériaux composites possédant différents taux de farine de bois. Cette évolution est mesurée à l'aide de deux techniques : l'émission acoustique et la tomographie aux rayons X in-situ. La décohésion à l’interface entre la matrice PVC et les particules de bois est le mécanisme initiant l’endommagement. La transition ductile/fragile des composites s’explique par la coalescence de ces cavités. L’ajout de modifiant choc ne réduit pas suffisamment ce mécanisme. Les agents de couplage sont donc la voie à explorer afin d’améliorer l’interface matrice/particules et remédier au défaut d’adhésion qui pénalise ces composites. / The aim of the present study is to understand the origin of the brittleness of PVC/wood flour composites (WPC). The influence of the matrix and of the filler is investigated: fiber parameters are key factors that significantly affect the mechanical properties of WPC. Fiber dispersion, orientation and particles connectivity can be accurately assessed by using the non-destructive X-ray tomography technique. The qualitative and quantitative analysis of tomography experimental results allows a 3D visualisation of the composite. The brittleness of the composites is caused by agglomerates and/or the presence of a percolated network: it explains why impact resistance decreases when the wood flour content increase. To optimise the rigidity/ductility compromise, several solutions are considered. The other part of this work consists of combining acoustic emission and X-ray tomography to study the evolution of damaging in composite materials with different wood flour content. An original coupling of these two techniques is implemented. The main failure mechanism involved in such composites is the decohesion between the matrix and the wood particles. The ductile/brittle transition occurs when the cavities coalescence becomes the dominant process over the PVC matrix failure. Adding impact modifiers is not sufficient to improve the ductility of the composite. Coupling agents are the route to be explored so as to improve the interfacial adhesion between the matrix and the particles. Composite à matrice polymère PVC - Polychlorure de vinyl Farine de bois Résistance mécanique Fragilité Endommagement ductile Dispersion charge Orientation Percolation Tomographie par rayon X Emission acoustique Polymer matrix composite PVC - Polyvinyl chloride Wood flour Mechanical strength Brittleness Ductile damage Orientation Percolation X-ray tomography Acoustic emission 620.192 118 072
363	Fracture Characteristics Of Self Consolidating Concrete Naddaf, Hamid Eskandari 07 1900 (has links) Self-consolidating concrete (SCC) has wide use for placement in congested reinforced concrete structures in recent years. SCC represents one of the most outstanding advances in concrete technology during the last two decades. In the current work a great deal of cognizance pertaining to mechanical properties of SCC and comparison of fracture characteristics of notched and unnotched beams of plain concrete as well as using acoustic emission to understand the localization of crack patterns at different stages has been done. An artificial neural network (ANN) is proposed to predict the 28day compressive strength of a normal and high strength of SCC and HPC with high volume fly ash. The ANN is trained by the data available in literature on normal volume fly ash because data on SCC with high volume fly ash is not available in sufficient quantity. Fracture characteristics of notched and unnotched beams of plain self consolidating concrete using acoustic emission to understand the localization of crack patterns at different stages has been done. Considering this as a platform, further analysis has been done using moment tensor analysis as a new notion to evaluate fracture characteristics in terms of crack orientation, direction of crack propagation at nano and micro levels. Analysis of B-value (b-value based on energy) is also carried out, and this has introduced to a new idea of carrying out the analysis on the basis of energy which gives a clear picture of results when compared with the analysis carried out using amplitudes. Further a new concept is introduced to analyze crack smaller than micro (could be hepto cracks) in solid materials. Each crack formation corresponds to an AE event and is processed and analyzed for crack orientation, crack volume at hepto and micro levels using moment tensor analysis based on energy. Cracks which are tinier than microcracks (could be hepto), are formed in large numbers at very early stages of loading prior to peak load. The volume of hepto and micro cracks is difficult to measure physically, but could be characterized using AE data in moment tensor analysis based on energy. It is conjectured that the ratio of the volume of hepto to that of micro could reach a critical value which could be an indicator of onset of microcracks after the formation of hepto cracks. Concrete - Fracture Mechanics Self-Consolidating Concrete (SCC) Plain Concrete Beams - Fracture Plain Concrete Beams - Acoustic Emission Self-Consolidating Concrete - Properties Artificial Neural Network (ANN) Fly Ash Un-notched Beams Notched Beams Hepto Cracks Microcracks Structural Engineering
364	Χρήση μεθόδων συνοριακών στοιχείων και τοπικών ολοκληρωτικών εξισώσεων χωρίς διακριτοποίηση για την αριθμητική επίλυση προβλημάτων κυματικής διάδοσης σε εφαρμογές μη-καταστροφικού ελέγχου Βαβουράκης, Βασίλειος 18 August 2008 (has links) Ο στόχος της παρούσας διδακτορικής διατριβής είναι διττός: η ανάπτυξη και η εφαρμογή αριθμητικών τεχνικών για την επίλυση προβλημάτων που εμπίπτουν στην περιοχή του Μη-Καταστροφικού Ελέγχου. Συγκεκριμένα αναπτύχθηκαν η Μέθοδος των Συνοριακών Στοιχείων (ΜΣΣ) και η Μέθοδος των Τοπικών Ολοκληρωτικών Εξισώσεων χωρίς Διακριτοποίηση για την αριθμητική ανάλυση στατικών και μεταβατικών προβλημάτων στο πεδίο της ελαστικότητας και της αλληλεπίδρασης ελαστικού με ακουστικό μέσο στις δύο διαστάσεις. Σημαντικό μέρος της διδακτορικής διατριβής αποτέλεσε η ανάπτυξη προγράμματος ηλεκτρονικού υπολογιστή, το οποίο επιλύει τα προβλήματα στα οποία πραγματεύεται το παρόν σύγγραμμα. Η διδακτορική διατριβή αποτελείται από τρεις ενότητες. Στην πρώτη ενότητα γίνεται πλήρης περιγραφή της απαραίτητης θεωρίας για την κάλυψη και κατανόηση των αριθμητικών ΜΣΣ αλλά και των Τοπικών Μεθόδων χωρίς Διακριτοποίηση (ΤΜχΔ). Στη δεύτερη ενότητα εφαρμόζονται οι προαναφερθείσες αριθμητικές μέθοδοι για την επίλυση στατικών και δυναμικών (στο πεδίο συχνοτήτων) διδιάστατων προβλημάτων, ώστε να πιστοποιηθεί η ακρίβεια και η αξιοπιστία των εν λόγω μεθοδολογιών. Τέλος, στην τρίτη ενότητα οι αριθμητικές ΜΣΣ και ΤΜχΔ εφαρμόζονται για την επίλυση προβλημάτων κυματικής διάδοσης που εμπίπτουν στο πεδίο του Μη-Καταστροφικού Ελέγχου. Πιο συγκεκριμένα μελετήθηκε η κυματική διάδοση σε ελεύθερες επίπεδες πλάκες και σε κυλινδρικές δεξαμενές αποθήκευσης υγρών καυσίμων. / The aim of this doctoral thesis is twofold: the development and implementation of numerical techniques for solving wave propagation problems in Non-Destructive Testing applications. Particularly, the Boundary Element Method (BEM) and the Local Boyndary Integral Equation Method are developed, so as to numerically solve static and transient problems on the field of elasticity and fluid-structure interaction in two dimensions. A major part of the present research is the construction of a computer program for solving such kind of problems. This textbook consists of three sections. In the first section, a thorough description on the theory of the BEM and the Local Meshless Methods (LMM) is done. The second section is dedicated for the numerical implementation of the BEM and LMM for solving steady state and time-harmonic two dimensional elastic and acoustic problems, in order to verify the accuracy and the ability of the proposed methodologies to solve the above-mentioned problems. Finally in the third section, the wave propagation problems of traction-free plates and cylindrical fuel storage tanks is studied, from the perspective of Non-Destructive Testing. The numerical methods of BEM and LMM are implemented, as well as spectral methods are utilized, for drawing useful conclusions on the wave propagation phenomena. Ακουστική εκπομπή 620.112 7 Boundary elements method Local Petrov-Galerking method Local boundary integral equation method Meshless methods Non destructive testing Dispersion curves Time-frequency representation Acoustic emission
365	Distributions Of Fiber Characteristics As A Tool To Evaluate Mechanical Pulps Reyier Österling, Sofia January 2015 (has links) Mechanical pulps are used in paper products such as magazine or news grade printing papers or paperboard. Mechanical pulping gives a high yield; nearly everything in the tree except the bark is used in the paper. This means that mechanical pulping consumes much less wood than chemical pulping, especially to produce a unit area of printing surface. A drawback of mechanical pulp production is the high amounts of electrical energy needed to separate and refine the fibers to a given fiber quality. Mechanical pulps are often produced from slow growing spruce trees of forests in the northern hemisphere resulting in long, slender fibers that are well suited for mechanical pulp products. These fibers have large varieties in geometry, mainly wall thickness and width, depending on seasonal variations and growth conditions. Earlywood fibers typically have thin walls and latewood fibers thick. The background to this study was that a more detailed fiber characterization involving evaluations of distributions of fiber characteristics, may give improved possibilities to optimize the mechanical pulping process and thereby reduce the total electric energy needed to reach a given quality of the pulp and final product. This would result in improved competitiveness as well as less environmental impact. This study evaluated the relation between fiber characteristics in three types of mechanical pulps made from Norway spruce (Picea abies), thermomechanical pulp(TMP), stone groundwood pulp (SGW) and chemithermomechanical pulp (CTMP). In addition, the influence of fibers from these pulp types on sheet characteristics, mainly tensile index, was studied. A comparatively rapid method was presented on how to evaluate the propensity of each fiber to form sheets of high tensile index, by the use of raw data from a commercially available fiber analyzer (FiberLabTM). The developed method gives novel opportunities of evaluating the effect on the fibers of each stage in the mechanical pulping process and has a potential to be applied also on‐line to steer the refining and pulping process by the characteristics of the final pulp and the quality of the final paper. The long fiber fraction is important for the properties of the whole pulp. It was found that fiber wall thickness and external fibrillation were the fibercharacteristics that contributed the most to tensile index of the long fiber fractions in five mechanical pulps (three TMPs, one SGW, one CTMP). The tensile index of handsheets of the long fiber fractions could be predicted by linear regressions using a combination of fiber wall thickness and degree of external fibrillation. The predicted tensile index was denoted BIN, short for Bonding ability INfluence. This resulted in the same linear correlation between BIN and tensile index for 52 samples of the five mechanical pulps studied, each fractionated into five streams(plus feed) in full size hydrocyclones. The Bauer McNett P16/R30 (passed 16 meshwire, retained on a 30 mesh wire) and P30/R50 fractions of each stream were used for the evaluation. The fibers of the SGW had thicker walls and a higher degree of external fibrillation than the TMPs and CTMP, which resulted in a correlation between BIN and tensile index on a different level for the P30/R50 fraction of SGW than the other pulp samples. A BIN model based on averages weighted by each fiber´s wall volume instead of arithmetic averages, took the fiber wall thickness of the SGW into account, and gave one uniform correlation between BIN and tensile index for all pulp samples (12 samples for constructing the model, 46 for validatingit). If the BIN model is used for predicting averages of the tensile index of a sheet, a model based on wall volume weighted data is recommended. To be able to produce BIN distributions where the influence of the length or wall volume of each fiber is taken into account, the BIN model is currently based on arithmetic averages of fiber wall thickness and fibrillation. Fiber width used as a single factor reduced the accuracy of the BIN model. Wall volume weighted averages of fiber width also resulted in a completely changed ranking of the five hydrocyclone streams compared to arithmetic, for two of thefive pulps. This was not seen when fiber width was combined with fiber wallthickness into the factor “collapse resistance index”. In order to avoid too high influence of fiber wall thickness and until the influence of fiber width on BIN and the measurement of fiber width is further evaluated, it is recommended to use length weighted or arithmetic distributions of BIN and other fiber characteristics. A comparably fast method to evaluate the distribution of fiber wall thickness and degree of external fibrillation with high resolution showed that the fiber wallthickness of the latewood fibers was reduced by increasing the refining energy in adouble disc refiner operated at four levels of specific energy input in a commercial TMP production line. This was expected but could not be seen by the use of average values, it was concluded that fiber characteristics in many cases should be evaluated as distributions and not only as averages. BIN distributions of various types of mechanical pulps from Norway spruce showed results that were expected based on knowledge of the particular pulps and processes. Measurements of mixtures of a news‐ and a SC (super calendered) gradeTMP, showed a gradual increase in high‐BIN fibers with higher amounts of SCgrade TMP. The BIN distributions also revealed differences between the pulps that were not seen from average fiber values, for example that the shape of the BINdistributions was similar for two pulps that originated from conical disc refiners, a news grade TMP and the board grade CTMP, although the distributions were on different BIN levels. The SC grade TMP and the SC grade SGW had similar levels of tensile index, but the SGW contained some fibers of very low BIN values which may influence the characteristics of the final paper, for example strength, surface and structure. This shows that the BIN model has the potential of being applied on either the whole or parts of a papermaking process based on mechanical or chemimechanical pulping; the evaluation of distributions of fiber characteristics can contribute to increased knowledge about the process and opportunities to optimize it. Fiber fibre fiber characteristics fiber dimension fiber properties mechanical pulp FiberLab raw data distribution fiber wall thickness BIN bonding ability influence bonding indicator bonding ability fiber width fibrillation collapse resistance laboratory sheet fiber analyzer optical analyzer TMP CTMP SGW sheet model prediction fiber characterization hydrocyclone fractionation kernel density estimation KDE diffusion mixing acoustic emission F0.90 Norway spruce Picea abies
366	Contribution au traitement du signal pour le contrôle de santé in situ de structures composites : application au suivi de température et à l’analyse des signaux d’émission acoustique / Signal processing for in situ Structural Health Monitoring of composite structures : application to the estimation of the temperature dynamics and to the study of acoustic emission Hamdi, Seif Eddine 12 October 2012 (has links) Le contrôle de santé structural ou Structural Health Monitoring (SHM) des matériaux constitue une démarche fondamentale pour la maîtrise de la durabilité et de la fiabilité des structures en service. Au-delà des enjeux industriels et humains qui ne cessent de s’accroître en termes de sécurité et de fiabilité, le contrôle de santé doit faire face à des exigences de plus en plus élaborées. Les nouvelles stratégies de contrôle de santé doivent non seulement détecter et identifier l’endommagement mais aussi quantifier les différents phénomènes qui en sont responsables. Pour atteindre cet objectif, il est nécessaire d’accéder à une meilleure connaissance des processus d’endommagement. Par ailleurs, ceux-ci surviennent fréquemment sous l’effet de sollicitations mécaniques et environnementales. Ainsi, il est indispensable, d’une part, d’élaborer des méthodes de traitement des signaux permettant d’estimer les effets des conditions environnementales et opérationnelles, dans un contexte de l’analyse des événements précurseurs des mécanismes d’endommagement, et, d’autre part, de définir les descripteurs d’endommagement les plus adaptés à cette analyse. Cette étude propose donc des méthodes de traitement du signal permettant d’atteindre cet objectif, dans un premier temps, pour l’estimation des effets externes sur les ondes multidiffusées dans un contexte de contrôle de santé actif et, dans un second temps, pour l’extraction d’un indicateur d’endommagement à partir de l’analyse des signaux d’émission acoustique dans un contexte de contrôle de santé passif. Dans la première partie de ce travail, quatre méthodes de traitement du signal sont proposées. Celles-ci permettent de prendre en compte les variations des conditions environnementales dans la structure, qui dans le cadre de cette thèse, se sont limitées au cas particulier du changement de la température. En effet, les variations de température ont pour effet de modifier les propriétés mécaniques du matériau et par conséquent la vitesse de propagation des ondes ultrasonores. Ce phénomène entraîne alors une dilatation temporelle des signaux acoustiques qu’il convient d’estimer afin de suivre les variations de température. Quatre estimateurs de coefficients de dilatation sont alors étudiés : Il s’agit de l’intercorrélation à fenêtre glissante, utilisée comme méthode de référence, la méthode du stretching, l’estimateur à variance minimale et la transformée exponentielle. Les deux premières méthodes ont été déjà validées dans la littérature alors que les deux dernières ont été développées spécifiquement dans le cadre de cette étude. Par la suite, une évaluation statistique de la qualité des estimations est menée grâce à des simulations de Monte-Carlo utilisant des signaux de synthèse. Ces signaux sont basés sur un modèle de signal multidiffusé prenant en compte l’influence de la température. Une estimation sommaire de la complexité algorithmique des méthodes de traitement du signal complète également cette phase d’évaluation. Enfin, la validation expérimentale des méthodes d’estimation est réalisée sur deux types de matériaux : Tout d’abord, dans une plaque d’aluminium, milieu homogène dont les caractéristiques sont connues, puis, dans un second temps dans un milieu fortement hétérogène prenant la forme d’une plaque composite en verre/epoxy. Dans ces expériences, les plaques sont soumises à différentes températures dans un environnement thermique contrôlé. Les estimations de température sont alors confrontées à un modèle analytique décrivant le comportement du matériau. La seconde partie de ce travail concerne la caractérisation in situ des mécanismes d’endommagement par émission acoustique dans des matériaux hétérogènes. Les sources d’émission acoustique génèrent des signaux non stationnaires... / Structural health monitoring (SHM) of materials is a fundamental measure to master thedurability and the reliability of structures in service. Beyond the industrial and human issuesever increasing in terms of safety and reliability, health monitoring must cope with demandsincreasingly sophisticated. New health monitoring strategies must not only detect and identifydamage but also quantify the various phenomena involved in it. To achieve this objective, itis necessary to reach a better understanding of the damage process. Moreover, they frequentlyoccur as a result of mechanical and environmental stresses. Thus, it is essential, first, to developsignal processing methods for estimating the effects of environmental and operational conditions,in the context of the analysis of precursor events of damage mechanisms, and on theother hand, to define the damage descriptors that are the most suitable to this analysis. Thisstudy proposes signal processing methods to achieve this goal. At first, to the estimation ofexternal effects on the scattered waves in an active health control context, in a second step, tothe extraction of a damage indicator from the signals analysis of acoustic emission in a passivehealth monitoring context.In the first part of this work, four signal processing methods are proposed. These allow takinginto account the variation of environmental conditions in the structure, which in this thesis,were limited to the particular case of temperature change. Indeed, temperature changes have theeffect of altering the mechanical properties of the material and therefore the propagation velocityof ultrasonic waves. This phenomenon then causes a dilation of the acoustic signals that shouldbe estimated in order to monitor changes in temperature. Four estimators of dilation coefficientsare then studied: the intercorrelation sliding window, used as reference method, the stretchingmethod, the minimum variance estimator and the exponential transform. The first two methodshave already been validated in the literature while the latter two were developed specificallyin the context of this study. Thereafter, a statistical evaluation of the quality of estimates isconducted through Monte Carlo simulations using synthetic signals. These signals are basedon a scattered signal model taking into account the influence of temperature. A raw estimateof the computational complexity of signal processing methods also completes this evaluationphase. Finally, the experimental validation of estimation methods is performed on two types ofmaterial: First, in an aluminum plate, homogeneous medium whose characteristics are known,then, in a second step in a highly heterogeneous environment in the form of a compositeglass/epoxy plate. In these experiments, the plates are subjected to different temperatures in acontrolled thermal environment. The temperature estimates are then faced with an analyticalmodel describing the material behavior.The second part of this work concerns in situ characterization of damage mechanisms byacoustic emission in heterogeneous materials. Acoustic emission sources generate non-stationarysignals. The Hilbert-Huang transform is thus proposed for the discrimination of signals representativeof four typical sources of acoustic emission in composites: matrix cracking, debondingfiber/matrix, fiber breakage and delamination. A new time-frequency descriptor is then definedfrom the Hilbert-Huang transform and is introduced into an online classification algorithm. Amethod of unsupervised classification, based on the k-means method, is then used to discriminatethe sources of acoustic emission and the data segmentation quality is evaluated. Thesignals are recorded from blank samples, using piezoelectric sensors stuck to the surface of thematerial and sensitive samples (sensors integrated within the material)... Contrôle de santé structurale Intercorrélation à fenêtre glissante Stretching Transformée de Hilbert-Huang Fréquence instantanée Reconnaissance de formes Classification Endommagement Émission acoustique Ondes multidiffusées Structural health monitoring Exponential transform Hilbert-Huang transform Instantaneous frequency Pattern recognition Classification Damage Environmental and operational conditions Acoustic emission Scattered waves Maximum likelihood Stretching Intercorrelation sliding window
367	Entwurf, Aufbau und Charakterisierung eines mikromechanischen Gleichspannungswandlers Arnold, Benjamin 09 December 2020 (has links) Die mikromechanische Gleichspannungswandlung basierend auf verschiebungsabhängigen Kapazitäten stellt eine Alternative zu etablierten rein elektronischen Wandlern für den Spezialfall der kapazitiven oder piezoelektrischen Verbraucher dar. Durch ihre kleine Bauform und den Verzicht auf Induktivitäten bietet sie den Vorteil der On-Chip-MEMS- und CMOS-Integration und ermöglicht die Bereitstellung hoher elektrischer Gleichspannungen aus den verfügbaren Grundspannungen der Elektronik (z. B. 3, 5 bzw. 12 V). Von hohen Polarisationsspannungen profitieren nicht nur kapazitive Sensoren und Aktoren, sondern auch piezoelektrische Messverfahren. Diese Arbeit stellt eine umfangreiche Übersicht und Bewertung der möglichen Bauformen mikromechanischer Gleichspannungswandler sowie die konkrete Umsetzung, Charakterisierung und Modellbildung eines resonant arbeitenden Wandlers vor. Es wird auf Besonderheiten und Probleme im Entwurf eingegangen und ausgehend von den Ergebnissen ein Konzeptentwurf für einen optimierten resonanten Gleichspannungswandler erarbeitet.:1 Einleitung 2 Theoretische Grundlagen 3 Ausführungsvarianten von MEMS-DC/DC-Wandlern 4 Designstudie und Umsetzung des resonanten Funktionsprinzips 5 Zusammenfassung und Ausblick / Micromechanical DC/DC conversion based on variable capacitances is an alternative to established electronic voltage converters, which does not require bulky inductors and is suitable for capacitive and piezoelectric loads. The converters are capable of boosting up the polarization voltage from CMOS and electronic levels (3, 5, 12 V), which is beneficial not only for capacitive sensors and actuators but also for piezoelectric sensing. Advantages of this method are the on-chip- and CMOS-integrability. This thesis introduces a comprehensive overview and evaluation of possible designs as well as the practical application, characterization and modeling of a resonant micromechanical DC/DC converter. Innovative claims include a test board for the characterization of resonant DC/DC converters and a SPICE behavioral model of the device, considering parasitic effects. Characteristics and problems of the design are discussed and the results are used to demonstrate an optimized conceptual design of a resonant DC/DC converter.:1 Einleitung 2 Theoretische Grundlagen 3 Ausführungsvarianten von MEMS-DC/DC-Wandlern 4 Designstudie und Umsetzung des resonanten Funktionsprinzips 5 Zusammenfassung und Ausblick info:eu-repo/classification/ddc/600 ddc:600 info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/621.3 ddc:621.3
368	Carbon nanotubes as nanofillers or fibers for multifunctional epoxy-based composites / Nanotubes de carbone sous forme de nanoparticules ou fibres pour les composites multifonctionnels fibre de carbone/matrice époxy Lutz, Vincent 26 March 2014 (has links) L’utilisation de composites à matrice thermodurcissable et fibres continues est en constante progression dans le secteur aéronautique, ferroviaire, et automobile. Afin d’améliorer les composites obtenus, notamment leur résistance à l’impact et leur conductivité électrique, des nanocharges organiques ou inorganiques peuvent être ajoutées. Les nanotubes de carbone (CNT) font partie des candidats les plus prometteurs pour le renforcement de composites à multi-échelle. Cependant, il s’avère difficile de contrôler la dispersion, la répartition et l’orientation des CNT, après les avoir mélangés aux prépolymères. Une nouvelle stratégie d’insertion des CNT dans un composite consiste à combiner des fibres de CNT avec des fibres de carbone. L’orientation et l’organisation structurelle des CNT au sein de la fibre permettent d’obtenir d’excellentes propriétés mécaniques et électriques. Dans notre étude, les propriétés de fibres contenant exclusivement des CNT, obtenues par direct spinning, ont été comparées à celles de fibres de carbone (non-ensimées, ensimées, et CNT en surface). Différentes interfaces entre les fibres de CNT, fibres de carbone et deux types de matrices époxy (de TG très différentes) ont été générées et testées par des essais de fragmentation de fibre dans la matrice. La contrainte de cisaillement interfaciale fibre/matrice a été évaluée afin de déterminer l’influence des diverses fibres et ensimages sur les performances mécaniques de composites à matrice organique et à fibres continues. En outre, la nature de l’adhésion et la qualité de l’interphase entre la matrice et la fibre ont été caractérisées par plusieurs techniques d’analyses et d’observations à multi-échelles. / Nowadays, polymer-matrix composites reinforced with carbon fibers are increasingly used in the whole transport sector (aerospace, automotive and railway industries). However, the obtained parts still suffer from low impact resistance and low damage tolerance. To improve these properties, the matrix precursors have to be combined with organic or inorganic compounds to lead to multi-phased matrices. Among them, carbon nanotubes (CNT) are especially promising for targeting multi-scale reinforcement. Since high quality of the parts are required, continuous-fibers-reinforced composites can be produced by resin transfer molding (RTM) which also offers a reduced cost if compared with high temperature- and high pressure-based processes. However, RTM requires a very low viscosity of the polymer precursors and CNT-filled precursors are far too viscous to be injected on dry performs. In addition, this strategy does not allow for a control of the CNT location and orientation in the final part. In this study, innovative ways have been developed to insert CNT in the preform with local positioning and defined orientation. Deliveries of CNT in the matrix, from a neat carbon multi-nanotubes fiber produced by direct spinning, or from a CNT grown on carbon fiber were investigated in two types of epoxy matrices (with very different TG). Different polymer matrix/fiber interfaces have been generated using neat carbon multi-nanotubes fiber, CNT grown on carbon fiber and conventional carbon fiber, with or without sizing. A fine mechanical characterization of various fibers and particularly the measurement of single fiber interfacial properties have been performed in order to determine mechanical performance of continuous fiber reinforced composites. In addition, the nature of adhesion and quality of matrix/fiber interface have been fully evaluated by different multi-scale analyses and suitable microstructural observations. Composite à matrice polymère Polymère thermodurcissable Nanocomposite Nanotube de carbone Fibre de carbone Moulage par transfert de résine Test de fragmentation Contrainte de cisaillement interfacial Interface Interphase Emission acoustique Spectroscopie Raman Polymer matrix composite Thermosetting polymer Nanocomposite Carbon nanotube Carbon fiber RTM - Resin transfer molding Fragmentation test Interfacial shear strength Interface Interphase Acoustic emission Raman Spectroscopy 620.192 118 072
369	Mikromechanischer Körperschall-Sensor zur Strukturüberwachung Auerswald, Christian 23 June 2016 (has links) Strukturüberwachung und Condition Monitoring spielen in vielen Gebieten der Technik eine große Rolle. Zur Überwachung von Leichtbaustrukturen aus faserverstärkten Kunststoffen bietet sich hierfür besonders die Körperschall-Analyse an. Am Markt etabliert sind hierfür piezoelektrische Signalaufnehmer. Diese Arbeit stellt eine kostengünstige Alternative in Form von mikromechanischen Körperschall-Sensoren vor. Eine Besonderheit stellt hierbei das Prinzip des mechanischen Bandpasses dar. Es wird die Elektronik- und Gehäuseentwicklung sowie die experimentelle Untersuchung dargelegt. / Structural health monitoring is of vital importance in many technical fields. For monitoring of lightweight structures made from fiber reinforced plastics especially acoustic emission testing is used. Commercially available transducers utilize the piezoelectric effect. This thesis introduces a cost efficient alternative in form of micromechanical sensors, in particular sensors using the principle of a mechanical bandpass. The design of electronics and the packaging as well as experimental investigations are provided. info:eu-repo/classification/ddc/534 ddc:534 info:eu-repo/classification/ddc/537 ddc:537 info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/629 ddc:629
370	USE OF SINGLE TOW CERAMIC MATRIX MINICOMPOSITES TO DETERMINE FUNDAMENTAL ROOM AND ELEVATED TEMPERATURE PROPERTIES Almansour, Amjad Saleh Ali 28 September 2017 (has links) No description available. Chemical Engineering Chemistry Engineering Materials Science Mechanical Engineering Mechanics Aerospace Materials Acoustics Aerospace Engineering Experiments Theoretical Mathematics Theoretical Physics Metallurgy Mathematics High Temperature Physics Electrical Engineering

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