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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
71

Adhesive modelling in multi-material structures : Evaluating the strength and fatigue life of adhesive joints / Modellering av lim i multimaterialstrukturer : Utvärdering av styrka och livslängd i limfogar

Narayanaswamy, Nitin January 2020 (has links)
Advancements in material science and manufacturing techniques are enabling the use of lightweight metal alloys and polymer composites in several combinations and shapes for producing more efficient and lightweight structures for automotive applications without compromising strength, stiffness and/or durability. When evaluating the strength of the structure, the joints are of importance. For multi-material structures adhesives are often the best type of joints. However, traditional finite element methods using stress criteria cannot accurately predict the failure of these adhesive joints under static loading. In this thesis work a strength and fatigue model, formulated using energy release rate theory, is implemented in a post processing tool. Given a finite element model of an adhesive joint and a list of boundary elements and nodes this tool calculates the energy release rates in mode I and mode II, and if the fracture toughness of the adhesive is known, a prescribed mixed-mode failure index is calculated. To evaluate its predictions joint strength results are correlated to experiments. Specimens with combined shear and normal load forms the underlying experimental setup with change in strain rate and adhesive thickness as varying parameters. Methods for implementing the model for a car body structure with multiple adhesive joints is investigated, the tool proves to be scalable, however, the required finite element setup at the adhesive boundaries may not be present in a car body model and thus further work needs to carried out to accommodate irregularities like non-matching mesh in the car body finite element model. This model may be used for assessing the strength and durability of a car body structure comprising different materials joined together using adhesives.
72

Oberflächenvorbehandlung von Fügeteilen zur Optimierung adhäsiver Verbindungen im Konstruktiven Glasbau

Kothe, Christiane 15 October 2013 (has links)
Die moderne Architektur ist durch gläserne Fassaden und ausgefallene Konstruktionen aus Glas geprägt. Dabei wird Glas nicht nur als raumabschließendes Element verwendet, sondern auch konstruktiv eingesetzt und zunehmend an der Lastabtragung beteiligt. Die Integration von Glaselementen in die Baukonstruktion erfolgt über linien- oder punktförmige Lagerungen. Dabei können mechanisch ausgeführte Halterungen lokale Beanspruchungen und damit Glasversagen verursachen. Eine Alternative bilden Klebverbindungen, welche ein materialgerechtes Konstruieren im Glasbau ermöglichen. Kommerziell wird hierfür eine Vielzahl von Klebstoffen angeboten. Neben der Auswahl eines geeigneten Klebstoffsystems können dauerhafte adhäsive Verbindungen aber meist nur mit Hilfe von Oberflächenvorbehandlungen der Fügeteile gewährleistet werden. Aufgrund der langen Standzeiten von Bauwerken sind große Beständigkeiten von geklebten Verbindungen notwendig, welche nur durch den Aufbau von möglichst hohen Haftungskräften zwischen Fügeteiloberflächen und Klebstoffpolymer erreichbar sind. Spezielle Vorbehandlungsverfahren sorgen für eine bessere Benetzbarkeit der Oberflächen und schaffen zudem energetisch aktive Zentren, die mit den Klebstoffen in Wechselwirkung treten können. Viele der insbesondere für metallische Materialien industriell etablierten Oberflächenvorbehandlungen sind allerdings wenig zukunftsträchtig, da diese Verfahren häufig den Einsatz ätzender, hochgiftiger und umweltgefährdender Substanzen notwendig machen. Hierin liegt der Ansatzpunkt der vorliegenden Arbeit. In verschiedenen Industriebereichen, wie dem Automobilbau, der Elektrotechnik und der Dentalmedizin werden bereits neu entwickelte Oberflächenvorbehandlungsverfahren auf Basis von Plasma- und Abscheidungstechnologien eingesetzt. Daraus ergibt sich die Fragestellung nach der Anwendbarkeit solcher Verfahren auf Fügeteilmaterialien des Konstruktiven Glasbaus und nach dem Nutzen dieser Oberflächenvorbehandlungen in Bezug auf die Optimierung von strukturellen Klebungen. Für die Ermittlung optimaler Eigenschaften von Oberflächen für den klebtechnischen Prozess werden ausgewählte Fügeteile aus Edelstahl, Aluminium und Messing sowie Einscheibensicherheitglas aus Kalk-Natronsilikatglas physikalischen und chemischen Oberflächenanalysen vor und nach der Anwendung von vier verschiedenen Oberflächenvorbehandlungsverfahren unterzogen. Zudem werden die Haftungseigenschaften nach der Vorbehandlung an geklebten Prüfkörpern vor und nach Alterung untersucht. Aus den daraus erhaltenen Ergebnissen wird der Einfluss der Oberflächenbeschaffenheit auf die Festigkeit der Klebverbindungen bestimmt. Die durchgeführten Untersuchungen ergeben sehr unterschiedliche, stark substrat- und klebstoffabhängige Wirkungsweisen der einzelnen Oberflächenvorbehandlungen. Als geeignetes Verfahren in Bezug auf die Verbesserungen des Adhäsionsvermögens und der Alterungsbeständigkeit, die Integrierbarkeit in maschinelle Herstellungsprozesse und die Vermeidung optischer Veränderung der Oberflächen stellt sich die Flammensilikatisierung heraus. Die mit dieser Oberflächenvorbehandlung aufgebrachte, dichte Silikatschicht und deren chemische Aktivität sowie deren vollständige Benetzbarkeit bieten beste Voraussetzungen für die Verklebung verschiedener Fügeteilmaterialien mit unterschiedlichsten Klebstoffen. / The modern architecture is affected by glass facades and novel glass structures. Therein glass is not only used as space enclosing element, rather it finds more and more constructive application and it is increasingly involved in load transfer. State of the art for the integration of glass elements in buildings are mechanically designed point and linear fixings. But they may cause local stresses followed by glass breakage. An alternative to these fixations are adhesive joints which more respect the specific requirements of the fragile material glass. A wide variety of adhesives is already available for this purpose. For strong adhesive joints not only the selection of a suitable adhesive is essential. The surface quality, which can be enhanced by surface treatments, is just as important for a very good adhesion. Due to the long life expectancy of buildings, a permanently aging resistance of the adhesive joints is necessary. For that, a formation of the highest possible adhesion forces between adhesive polymer and adherend surface is essential. Special surface treatment processes ensure a better wettability of the surfaces and also create energetically active sites that can interact with the adhesive molecules. However, many of the industrially established surface pretreatments, especially those for metallic materials, are not sustainable, since these methods often use corrosive, highly toxic and environmentally hazardous substances. This is the basis of the present dissertation. In various industries, such as automotive, electrical engineering and dentistry, newly developed surface treatment methods based on plasma and deposition technologies are already used. This raises the question of the applicability of such methods on materials for glass constructions and of their benefit to the optimization of structural adhesive joints. The effect of four different surface treatment methods used on the surfaces of stainless steel, aluminum, brass and toughened safety glass made from soda-lime glass is investigated in experimental studies. Physical and chemical surface analyses are performed before and after the applications. In addition, the adhesion properties of bonded specimens with pretreated surfaces are examined before and after aging. The influence of the surface conditions on the strength of the adhesive joints is determined from the obtained results. The results show very different effects of the individual surface treatment methods with high dependences on substrate and adhesive. With regard to an increase of adhesion strength, a good aging resistance, an uncomplicated integration into automated production processes and an avoidance of changing the optical surface properties, the investigated combustion chemical vapour deposition is the most suitable method. With this pretreatment, a dense silicate layer is deposite on the surface. Its high chemical activity and its complete wettability offer the best conditions for bonding a variety of materials with different adhesives.
73

Etude de fiabilité et définition de modèles théoriques de vieillissement en très haute température pour des systèmes électronique et microélectronique

Jullien, Jean-Baptiste 25 October 2012 (has links)
Ce travail s'intègre dans les domaines de l'analyse et de la prédiction de la fiabilité des assemblages Multi-Chip Module. Il présente l'étude de fiabilité de microcâblages filaires (wire bonding) en très haute température à partir d'essais de vieillissement et d'analyses expérimentales. Les résultats permettent d'identifier les mécanismes de dégradation et d'évaluer les températures limites d'utilisation de ces interconnexions. Il développe une étude du comportement thermomécanique des joints collés à partir d'essais de caractérisation mécanique, d'essais de vieillissement accéléré et de simulations numériques par éléments finis. Ces méthodes permettent d'évaluer la criticité des assemblages dès la phase de conception. / This work is performed in analysis and prediction areas of Multi-Chip Module package reliability. It presents a reliability study on wire bonding in high temperature environment from aging tests and experimental analyzes. Results permit to identify degradation mechanisms and evaluate temperature limits of these interconnections. It develops a study of the thermomechanical behavior of adhesive joints from mechanical characterization tests, accelerated aging tests and finite element simulations. These methods are used to assess the criticality of packages from the design phase.
74

Development Of Efficient Modeling Methodologies Of Adhesively Bonded Joints For Crash Simulations

Sureshrao, Malvade Indrajit 07 1900 (has links)
In this thesis, a new modeling methodology applicable to adhesively bonded joints for crash simulations is presented. Using this approach, adhesive joints can be modeled without using minute solid elements thus reducing the size of the model. Moreover, coarse mesh can be used for substrates in the overlap region of a joint. Both of these improvements together yield significant reduction in simulation run times in crash analysis when compared to solid element representation of adhesive. The modeling can also capture effects of strain rate for a given ambient temperature. In order to develop the efficient modeling procedure mentioned above, experimental, analytical and numerical studies have been carried out. Mechanical behaviors of adhesively bonded joints are studied with the help of double lap shear (DLS) coupon tests conducted at different extension rates and temperatures. The joint specimens are made from dual-phase (DP) steel coupons bonded with epoxy resin. Tests are also carried out to ascertain the behaviors of these component materials at different extension rates and temperatures. A new semi-analytical solution procedure is developed considering material nonlinearity to predict mechanical behaviors of adhesively bonded DLS joints. The joint behaviors using the semi-analytical approach are predicted separately using the Von Mises and exponent Drucker-Prager yield criteria. The predicted force versus extension curves using semi-analytical solution are compared with test results. It is also hypothesized here that, the semi-analytical solution procedure can be used as a base to develop efficient modeling procedures of adhesively bonded joints in FEA. In finite element analysis, both adhesive and substrates are modeled as elastic-plastic materials. It is shown that the shell-solid model of the DLS joint, in which substrates are modeled using shell elements and adhesive is modeled using solid elements, can accurately predict the mechanical behavior of the joint. Both exponent Drucker-Prager and Von Mises material models in ABAQUS are used to calculate force versus extension curves. Numerical and experimental forces versus extension curves are compared. A new methodology for efficient modeling of adhesively bonded joints in LS-DYNA using equivalent material properties in the joint overlap region is proposed. Various models using this methodology are assessed by comparing their results with shell-solid model and test results. Finally, it is also shown that strain rate effects can be included in the efficient modeling approach.

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