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61	Compréhension et caractérisation multi-échelle de la rupture interfaciale d'assemblages collés (colle crash - tôle galvanisée) pour l'automobile / Understanding and multi-scale characterization of the interfacial failure of adhesively bonded assembly for automotive industry Legendre, Jean 04 October 2017 (has links) L’essai de type simple recouvrement est très largement utilisé dans l’industrie automobile pour évaluer la compatibilité entre une tôle d’acier et une colle. Dans ce cadre, deux critères de validation ont été définis par les constructeurs automobiles : un chargement à rupture minimum, et un facies de rupture cohésif. La rupture au niveau de l’interface colle/acier (rupture interfaciale), ne permet pas d’attester d’une bonne adhésion entre la colle et la tôle, elle n’est donc pas acceptée. Ainsi dans certains cas, l’assemblage n’est pas validé à cause de son faciès de rupture, même s’il démontre une résistance mécanique élevée. Une meilleure compréhension du phénomène de rupture interfaciale permettrait d’adapter le cahier des charges des constructeurs automobiles. Le premier objectif de la thèse a été de comprendre les mécanismes de rupture qui peuvent engendrer une rupture interfaciale. Des études expérimentales et numériques ont montré que la rigidité de la tôle a une forte influence sur la cinématique de déformation de l’éprouvette (rotation, plasticité de la tôle, effet de bords), et qu’elle influe beaucoup sur le faciès de rupture. La déformation plastique de la tôle semble être un paramètre-clef favorisant la rupture interfaciale. En effet, une étude à l’échelle microscopique sur la structure hétérogène du revêtement galvanique de la tôle a mis en évidence la présence de déformations localisées très importantes, qui semblent capable d’endommager l’interface collée. Le second objectif de la thèse a été de caractériser mécaniquement une interface tôle/adhésif. Deux méthodes complémentaires ont été proposées. La première consistait à caractériser l’interface dans des conditions « pures » de sollicitation, grâce à l’essai Arcan modifié. La seconde méthode a permis d’évaluer la capacité de l’interfaces à résister à un effet de bord, grâce à un essai de flexion trois points sur une éprouvette en coin. / The single lap-shear test is widely used by carmakers to characterize the adhesion of bonded joints. Two criteria govern the validation of the adhesion properties in the bonded joints: the shear strength and the failure mode which has to be cohesive. However, in some special cases, particularly when thin mild galvanized steel substrates were bonded with structural toughened adhesive, an interfacial pattern is obtained instead of cohesive failure. So the bonded assembly is not accepted even if its shear load at failure is high. A better understanding of the interfacial failure is required to adapt the carmakers specifications. The first objective of the PhD thesis was to analyze the critical phenomenon which favor the interfacial failure during single lap test. Substrate rigidity has significant effect on the failure pattern, because it influences the kinematic of deformation of the sample (rotation, steel plasticity, edge effect). Steel plasticity has been identified as a key factor for interfacial failure. The galvanized coating of the steel has a heterogeneous structure, which generate significant heterogeneous strain that could damage the interface. The second objective was to characterize the strength of the substrate-adhesive interface. Two methods have been proposed. The first one enable to measure the strength of an interface which homogeneous loading without edge effect (modified Arcan test). In the second method, the interface capability to resist to edge effects has been assessed. Thus, three different interfaces have been characterized using a three point bending test and thanks to an optical microscopy in situ analysis. Assemblage collé Rupture Interface Caractérisation multi-échelle Expérimentale et numérique Analyse in situ Acier galvanisé Zinc Colle crash Automobile Bonded assembly Failure Interface Multi-scale characterization Experimentale and numeric In situ analysis Galvanized steel Zinc Crash adhesive Automotive 620.112 6
62	Contribution à l'étude de la formation de la couche d'inhibition de l'acier galvanisé en continu Toussaint, Patrick 13 November 1997 (has links) <p align="justify">Un simulateur de laboratoire de galvanisation continue a été conçu et utilisé pour l'étude des effets des paramètres de contrôle du procédé sur la prise d'aluminium interfacial avec un intérêt particulier porté té à la simulation de l'hydrodynamique de l'écoulement du liquide à la surface de la tôle ainsi qu'aux durées d'immersion extrêmement courtes inférieures à une seconde. Les effets de la concentration en aluminium et des températures de travail ont aussi été étudiés. Il a pu être montré que la prise d'aluminium est extrêmement rapide dans les premiers instants de la réaction et que la couverture complète de l'acier par la couche d'inhibition était assurée après le premier dixième de seconde. La réaction se poursuit avec une vitesse de croissance de la couche compatible avec la diffusion à l'état solide du fer à travers le produit formé. Un modèle mathématique décrivant les phénomènes est proposé. La microscopie de force atomique a été utilisée pour l'étude de la morphologie de la couche d'inhibition et la microanalyse X à sélection d'énergie pour la mesure de son épaisseur.</p><p><p> / Doctorat en sciences appliquées / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Contrôle des matériaux Steel, Galvanized Surface chemistry Corrosion and anti-corrosives Aluminum coating Acier galvanisé Chimie des surfaces Corrosion Aluminiage chimie des surfaces et des interfaces corrosion des matériaux épaisseur métallurgie simulateur S.E.M. zinc aluminium
63	Estudo da substituição de aço convencional por aço de baixa liga e alta resistência (BLAR) em módulo estrutural Cruz, Magnus Geder Henz 26 June 2006 (has links) Foram estudados dois tipos de aços, aço convencional ZAR 230 (ZAR - Zincagem de alta resistência) e aço microligado ZSTE 380 (segundo norma SEW 093), sendo que foram avaliadas as suas propriedades mecânicas visando a substituição do aço convencional por aço microligado na estrutura tubular de uma carroceria para veículos de transporte coletivo de passageiros. O aço convencional vem sendo utilizado pela indústria de carrocerias há vários anos, já o aço microligado é utilizado basicamente em estruturas específicas que requeiram boas propriedades mecânicas e conseqüentemente redução de peso. A análise de viabilidade para a substituição de aço convencional por aço microligado em um módulo estrutural completo requereu uma série de ensaios: ensaios padronizados em laboratório foram executados para avaliação de suas principais propriedades mecânicas e químicas; ensaios de nós estruturais submetidos a uma carga forneceram informações para o uso em software de elementos finitos tanto para execução de cálculos estruturais, quanto para calibração de resultados. Os módulos estruturais foram preparados de acordo com as regulamentações ECE R66-00 (mercado europeu) e CONTRAN 811/96 (mercado brasileiro) e foram ensaiados exaustivamente até se obter o melhor resultado de deslocamento comparativamente aos dois materiais analisados. A validação da estrutura tubular foi obtida com a utilização do software Ansys Workbench 9.0 e a confecção de estrutura representativa de uma carroceria ensaiada conforme regulamentação CONTRAN 811/96. / Two kinds of steel were studied, conventional steel ZAR 230 (a standard for high strength galvanizing) and microalloyed steel ZSTE 380 (according to the regulation SEW 093). The study of its mechanical properties aimed to replace the steel for microalloyed steel in bodywork s tubular structure for collective transport vehicles of passengers. The conventional steel has been used for the bodywork industry for years, and the microalloyed steel is basically used in specific structures, those who require good mechanical properties and mass reduction. The analysis of the feasibility for the replacement of conventional steel for microalloyed steel in a complete structural model requires a series of tests. Lab tests were done to evaluate their main mechanical and chemical properties. The tests of the structural nodes and the structural behaviour when subjected to a load provided information to be used in the finite elements method software to do structural calculation and to calibrate the results. The structural modules were prepared according to the regulations ECE R66-00 (European market) and CONTRAN 811/96 (Brazilian market) and these modules were tested exhaustively to achieve the best displacement between the two materials that were analysed comparatively. The validation of the tubular structure was obtained using the software Ansys Workbench 9.0 and the production of the representative structure of a bodywork tested according the regulation CONTRAN 811/96. Estrutura dos metais e ligas Aços BLAR Aços microligados Aços galvanizados Melhoria de estrutura Seleção de materiais Estrutura de carroceria de ônibus HSLA (High Strength Low Alloy) steel Estruturas veiculares Microalloyed steel Galvanized steel Optimisation of structure Material selection Bus bodywork
64	Study of Bond Behavior at Rebar and Concrete Interface through Beam-end Specimens with Consideration of Corrosion Hauff, Derek Allen Johnson 01 May 2022 (has links) No description available. Civil Engineering
65	Understoppning av bergbultsbricka : En undersökning om möjlig uteslutning av arbetsmomentet / Underfilling of rock bolt plates Blomster, Elin, Litton Fredriksson, Sara January 2021 (has links) Vid byggnation av tunnlar och bergrum används bergförstärkning för att exempelvis säkra mot nedfallande lösa block och uppsprickning av berg. En vanlig förekommande förstärkning är bergbultar i kombination med sprutbetong. Vid installation av bultar borras hål i bergväggen som sedan fylls med cementbruk. Bultar som redan är försedd med bricka, halvkula, och mutter trycks sedan in i borrhålen av manuell kraft. Understoppningen görs i samband med att den sista biten av bulten trycks in i borrhålet. Då förses brickans undersida med cementbruk innan den skruvas åt med mutter mot den sprutbetongtäckta bergväggen. Denna rapport syftar till att ta reda på om momentet understoppning av bergbultsbricka vid montering av kamstålsbultar vid konventionell tunneldrivning är möjlig att utesluta. Idag råder det delade meningar mellan beställare, entreprenörer och specialister kring momentets betydelse för bergförstärkningen av tunnlar då vissa menar att det är nödvändigt och andra menar att det kan uteslutas. Däremot är det ofta angett i tekniska beskrivningar att momentet ska utföras då det står med i AMA Anläggning 20, vilket innebär att momentet inte kan uteslutas vid installation av kamstålsbultar. Med denna bakgrund ämnar föreliggande studie till att ta reda på grunderna till varför och när kravet på understoppning av bergbultsbrickor lades till, samt huruvida det fortfarande finns belägg för att ha kvar kravet. I denna studie har ingen tidigare forskning hittats om själva syftet med understoppning som kan visa på anledningar till varför man utför momentet samt varför det har lagts till som ett krav. Metoden har därför utförts genom att inhämta information och sökta svar från litteraturstudier inom ämnet samt via intervju- och enkätstudier. En teoretisk livslängdsberäkning för rostskyddssystemet har utförts för att få svar på om det uppfyller Trafikverkets krav på en teknisk livslängd på 120 år. Att utföra experimentella tester för att svara på studiens syfte diskuterades under studiens gång men var inte möjligt att genomföra med tillhandahållen tidsram och resurser. Resultatet visade att understoppningens huvudsakliga syfte är för att skydda bergbulten mot korrosion och mot genomstansning av brickan i sprutbetongen. Studien visade dock att det saknas bakgrund och konkreta bevis som säkerställer att understoppning motverkar detta. Litteraturstudien visade att varmförzinkade och epoxilackerade bultar har hög beständighet mot korrosion men att tunnelmiljön troligtvis har en betydande faktor för bultens livslängd. Litteraturstudien visade även att brickans betydelse för bärsystemet är odefinierad. Detta då vissa studier fastställer att brickan endast har en liten inverkan och andra visar att brickans styvhet har betydelse för genomstansning. Resultatet visade även att momentet innebär en ogynnsam arbetsmiljö för yrkesarbetare samt att en eventuell uteslutning skulle innebära förmodade vinster för inblandade parter. En annan fråga som belysts är huruvida den omfattning av bergsförstärkning som utförs idag verkligen är nödvändig. Om bergförstärkningen skulle kunna ske mer sparsamt skulle det möjliggöra en besparing av statliga medel och naturresurser. Denna studie har inte gett svar på om kravet på bärighet och beständighet uppfylls utan understoppning. Förslag på vidare studier för att besvara den frågan har därför redovisats. / When building tunnels, rock reinforcement is used. E.g., to secure against falling loose blocks and cracking of rock. A common reinforcement is rock bolts in combination with shotcrete. When installing bolts, holes are drilled into the rock wall, which are then filled with cement mortar. Bolts already provided with plate, hemisphere, and nut are then pushed into the boreholes by manual force. The underfilling of the plate is done in connection with the last part of the bolt being pushed into the borehole. Then the underside of the plate is provided with cement mortar before it is screwed on against the shotcrete-covered rock wall with a nut. The purpose of this report is to evaluate whether it is possible to exclude underfilling of rock bolt plates when installing rebar bolts during conventional tunnelling. Today, there are divided opinions between customers, contractors and specialists about the importance of underfilling for the rock reinforcement. I.e., there is a lack of consensus if underfilling of rock bolt plates is necessary or can be excluded. On the other hand, it is often stated in the technical descriptions that the task must be fulfilled then it is included in AMA Anläggning 20, which means that it cannot be excluded when installing rebar bolts. With this background, this study aims to find out the reasons why and when the requirement for underfilling of rock bolt plates was added, and whether there is still evidence to maintain the requirement. No previous research has investigated applicable reasons of why it is performed and why it has been added as a requirement. The method has therefore been performed by obtaining information from literature studies in the subject as well as via interview and survey studies. A theoretical lifetime calculation for the corrosion protection system has been performed to answer whether it achieves the requirement of a technical lifetime of 120 years issued by the Swedish Transport Administration. Performing experimental tests to answer the purpose of this study was discussed but was not possible to perform with the resources provided. The result showed that the main purpose of underfilling is to protect the rock bolt against corrosion and punching of the plate into the shotcrete. However, the study showed that there is a lack of background and actual evidence that proves that underfilling counteracts this. The literature study showed that hot galvanized and epoxy-painted bolts have high resistance against corrosion, but that the tunnel environment probably is a significant factor for the bolt's lifetime. The literature study also showed that the importance of the plate for the support system is undefined. Some studies demonstrate that the plate only has a small impact and others shows that the stiffness of the plate has a high impact for shear punching. The results also showed that the task causes an unfavourable working environment for professional workers and that a possible exclusion would mean presumed profits for involved parties. Another question that is highlighted is whether the extent of rock reinforcement that is carried out today is really necessary. If the rock reinforcement could be done more sparingly, it would make it possible to save state funds and natural resources. This study has not been able to answer whether the requirement for bearing capacity and durability is achieved without underfilling of rock bolt plates. Suggestions for further studies to answer this question have therefore been presented. underfilling rebar bolt rock bolt rock reinforcement rock bolt plate hot galvanized epoxy-painted corrosion protection system understoppning underpaltning paltning kamstålsbult bergbult bergförstärkning bergbultbricka varmförzinkad epoxilackerad rostskyddssystem Other Civil Engineering Annan samhällsbyggnadsteknik
66	Étude des mécanismes d'adhésion entre une surface d'oxyde et hydroxyde métallique (modèle et industrielle) et un polymère type époxy. Caractérisation de l'interface et de l'interphase / Study of adhesion mechanisms between surfaces oxides and hydroxides and epoxy polymer. Interfaces and interphase’s characterization Pélissier, Krystel 04 June 2014 (has links) La nouvelle génération de revêtement métallique à base de zinc, aluminium et magnésium (ZM) développée par ArcelorMittal permet une meilleure résistance à la corrosion pour une épaisseur plus faible que les aciers galvanisés standard du type GI. Toutefois, leur homologation pour l’utilisation dans des assemblages collés dans le secteur automobile pose problème car, contrairement au système adhésif crash/GI, des ruptures adhésives sont observées lors du test de traction-cisaillement d’un assemblage adhésif crash/ZM. Ce travail a visé à comprendre la ou les raison(s) de ces ruptures adhésives afin de proposer des solutions industrielles pour y remédier. Pour cela, une stratégie multi-technique et multi-échelle (XPS, IRRAS, Raman, AFM, …) a été mise au point afin de caractériser la surface métallique et ses oxydes, les interactions de ces derniers et les composants réactifs de l’adhésif à savoir la résine (DGEBA) et le durcisseur (DDA), et le système complet adhésif/ZM. Nous avons montré que la chimie de surface du ZM est bien plus complexe que celle du GI et est dominée par des phases riches en magnésium et très peu par des oxydes/hydroxydes de zinc contrairement au GI d’où une réactivité différente vis-à-vis de la DGEBA et la DDA. En particulier le piégeage de la DDA par interaction avec le magnésium perturbe la réticulation dans une interphase chimique ainsi que l’interaction du réseau polymérique avec la silice colloïdale et les charges à base de calcium dans une interphase mécanique affaiblissant la mécanique d’ancrage de l’adhésif. Divers solutions telles que l’application d’un traitement de surface sont proposées pour remédier à cet effet négatif du magnésium / New generation of metallic coatings based on zinc, aluminum and magnesium chemistry (ZM) developed by ArcelorMittal allows a higher corrosion resistance with a thinner layer than standard galvanized steel GI. However, its homologation for bonding structure application in automobile sector is a problem because of observation of adhesive failure after lap shear test with crash adhesive unlike GI coatings. This work’s aim is to understand the reason(s) behind the adhesive failure in order to resolve this problem by proposing industrial solutions. Thus, a multi-technical and multi-scale strategy (XPS, IRRAS, Raman, AFM,… ) was developed to characterize the metallic surface and its oxides, interactions between these oxides and the reactive components of the adhesive, namely the epoxide resin (DGEBA) and the hardener (DDA) and finally the whole system, i.e. ZM/adhesive. It was demonstrated that ZM surface chemistry is far more complex than GI surface chemistry and is dominated by rich magnesium phases and low in zinc oxides/hydroxides unlike GI leading to a different reactivity towards DGEBA and DDA. In particular, the DDA trapping by interaction with magnesium disrupts reticulation process in a chemical interphase and interaction of the polymeric network with colloidal silica and mineral fillers (calcium types) in a mechanical interphase which is weakening the adhesive mechanical anchoring. Several solutions like application of surface treatments can be proposed to solve the negative effect of magnesium Revêtement zinc-aluminium-magnésium Acier galvanisé Assemblage adhésif crash/acier revêtu DDA DGEBA Interface Interphase Mécanismes d’adhésion Zinc-aluminum-magnesium coating Galvanized steel Crash adhesive/coating steel assembly DDA DGEBA Interface Interphase Adhesion mechanisms 668.3
67	Dětská léčebna se speleoterapií Ostrov u Macochy / Sanatorium with Speleotherapy for Childern Ostrov u Macochy Tran, Hoang Long January 2015 (has links) The master thesis Sanatorium with Speleotherapy for Children - Ostrov u Macochy is an architectonical concept which consist of the establishment of a sanatorium with various functions for patients and the public. The compound offers a medical block, administrative and economic blocks, a school, a cafeteria for visitors, a guests house for adult clients and complement. The building site is located on an inclined terrain near Císařské jeskyně (Caesar cave) and it is surrounded by forest from three sides. There is a scenic view to the south from the construction site. The neighboring buildings consist only of family houses. The compound of sanatorium aimed to have the closest interaction with surroundings and the terrain, therefore the estate is divided into three different segments based on the three most important functions of the construction program.
68	Разработка конструктивного решения каркаса одноэтажного промышленного здания из ЛСТК, оборудованного подвесным краном грузоподъемностью до 2-3 тонн : магистерская диссертация / Development of a constructive solution for the frame of a single-storey industrial building made of LSTC equipped with an overhead crane with a lifting capacity of up to 2-3 tons Никагосов, Д. В., Nikagosov, D. V. January 2021 (has links) Работа посвящена разработке нового технического решения узла крепления подкрановых балок к ригелю покрытия рамы здания из ЛСТК (легких стальных тонкостенных конструкций), а также изучению его работы под нагрузкой. В результате исследования разработаны рабочие чертежи узла крепления и инженерный метод расчета данного узла, что позволяет расширить область применения каркасов из ЛСТК для строительства однопролетных зданий с подвесными кранами грузоподъемностью до 2-3 тс. В рамках настоящего исследования разработана расчетная пространственная модель здания в ПК ЛИРА-САПР 2016, произведен статический расчет по расчетным сочетаниям усилий. На основании результатов расчета методом конечных элементов определены максимальные действующие усилия, возникающие в несущих конструкциях. / Present work is devoted to the development of a new technical solution for the attachment joint of crane beams to the girder of the building frame covering made of LSTWS (Light steel thin-walled structures), as well as the study of its operation under load. As a result of the study, working drawings of the attachment joint and an engineering method for calculating this unit were developed, which makes it possible to expand the scope of application of frames from LSTWS for the construction of single-span buildings with overhead cranes with a lifting capacity of up to 2-3 t. Within the framework of this study, a computational spatial model of the building was developed in the FEA software LIRA-SAPR 2016. Static calculation was performed based on the design combinations of efforts. Based on the results of the calculation by the finite element method (FEM), the maximum acting forces arising in the supporting structures are determined. ЛСТК ОЦИНКОВАННЫЕ ПРОФИЛИ ПРОМЫШЛЕННОЕ ЗДАНИЕ УЗЕЛ ПОДВЕСНОЙ КРАН КРАН-БАЛКА ФЕРМА БАЛКА ПОКРЫТИЕ БОЛТОВОЕ СОЕДИНЕНИЕ MASTER'S THESIS LSTWS LIGHTWEIGHT STEEL STRUCTURES THIN-WALLED STRUCTURES GALVANIZED PROFILES INDUSTRIAL BUILDING JOINTS STEEL STRUCTURES OVERHEAD CRANE CRANE-BEAM REDUCED SECTION TRUSS BEAM COATING BOLTED CONNECTION FINITE ELEMENT METHOD

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