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This is a reference source for strength of material formulas for the analysis and design of structural members and mechanical elements. Allows efficient static, stability and dynamic analyses of beams, bars, plates and shells with very general mechanical or thermal loading. The range of solutions includes arbitrary geometries and loadings.
Strains and stresses --- Structural analysis (Engineering) --- Structural analysis (Engineering --- Contraintes (Mécanique) --- Tables. --- Computer programs. --- Tables --- 539.4 --- -Structural analysis (Engineering) --- -Structural analysis (Engineering --- -#KVIV:BB --- stabiliteit --- structuuranalyse --- spanning --- belasting --- druk --- matrices --- spanningsanalyse --- kerfwerking --- uitwerking --- verbindingen --- balken --- zuilen --- staven --- skelet --- Architectural engineering --- Engineering, Architectural --- Structural mechanics --- Structures, Theory of --- Structural engineering --- Stresses and strains --- Architecture --- Elastic solids --- Flexure --- Mechanics --- Statics --- Deformations (Mechanics) --- Elasticity --- Engineering design --- Graphic statics --- Strength of materials --- Stress waves --- Structural design --- Strength. Resistance to stress --- Computer programs --- 539.4 Strength. Resistance to stress --- Contraintes (Mécanique) --- #KVIV:BB
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Phenomena occurring during a contact of two bodies are encountered in everyday life. In reality almost every type of motion is related to frictional contact between a moving body and a ground. Moreover, modeling of simple and more complex processes as nailing, cutting, vacuum pressing, movement of machines and their elements, rolling or, finally, a numerical simulation of car crash tests, requires taking contact into account. Therefore, its analysis has been a subject of many research efforts for a long time now. However, it is author’s opinion that there are relatively few efforts related to contact between structural elements, like beams, plates or shells. The purpose of this work is to fill this gap. It concerns the beam-to-beam contact as a specific case of the 3D solids contact. A numerical formulation of frictional contact for beams with two shapes of cross-section is derived. Further, a couple of effective methods for modeling of smooth curves representing beam axes are presented. A part of the book is also devoted to analyze some aspects of thermo-electro-mechanical coupling in contact of thermal and electric conductors. Analyses in every chapter are illustrated with numerical examples showing the performance of derived contact finite elements.
Balken. --- Contact mechanics. --- Finite element method. --- Finite-Elemente-Methode. --- Kontaktmechanik. --- Contact mechanics --- Finite element method --- Materials Science --- Applied Mathematics --- Civil Engineering --- Civil & Environmental Engineering --- Engineering & Applied Sciences --- Chemical & Materials Engineering --- FEA (Numerical analysis) --- FEM (Numerical analysis) --- Finite element analysis --- Contact problems (Mechanics) --- Mechanics, Contact --- Engineering. --- Applied mathematics. --- Engineering mathematics. --- Continuum mechanics. --- Continuum Mechanics and Mechanics of Materials. --- Appl.Mathematics/Computational Methods of Engineering. --- Numerical analysis --- Isogeometric analysis --- Mechanics, Applied --- Mechanics. --- Mechanics, Applied. --- Solid Mechanics. --- Mathematical and Computational Engineering. --- Engineering --- Engineering analysis --- Mathematical analysis --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Physics --- Dynamics --- Quantum theory --- Mathematics --- Solids. --- Mathematical and Computational Engineering Applications. --- Data processing. --- Solid state physics --- Transparent solids
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Pourquoi est-ce que les (bons) tabourets ont trois pieds ? Pourquoi est-ce que la canne de Charlot se plie lorsqu'il s'appuie dessus mais reste rigide quand il s'y pend ? Pourquoi conserve-t-on mieux son équilibre dans un bus en écartant les pieds ?Des questions assez simples dont la réponse permet cependant de comprendre des procédés de construction en apparence très complexes, tels que les ponts suspendus ou la tour Eiffel.Discussions à bâtons rompus de l'élève et du professeur, croquis illustratifs, encadrés historiques et techniques dédiés aux chefs-d'oeuvre en matière de conception, exemples humoristiques...Le lecteur est invité à voyager de façon très didactique « au pays des structures ».
Structure --- Ingénierie --- Pont --- Structure légère --- Architecture religieuse --- Coupole --- Beams [Composite ] --- Building [Composite ] --- Composed construction --- Composite girders --- Construction composite --- Construction mixte --- Gemengde balken --- Gemengde bouwkunde --- Girders [Composite ] --- Mixte construction --- Poutres mixtes --- Théorie des constructions --- Ouvrages pour la jeunesse --- Constructions, Théorie des --- Ponts --- Théorie des constructions --- Infrastructures de transport --- Conception technique --- Conception et construction --- Architecture --- Structural analysis (Engineering) --- Structural design --- Buildings --- Constructions --- Juvenile literature --- Calcul --- Design and construction --- Infrastructures de transport. --- Conception technique. --- Constructions, Théorie des. --- Conception et construction. --- Civil engineering. Building industry --- architectonics --- Constructions, Théorie des --- 69.01 --- 69.07 --- 373.67 --- Bouwconstructie --- Draagconstructies --- Architectuuronderwijs --- Koepelconstructies
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