This book is intended as an introductory text on Solid Mechanics suitable for engineers, scientists and applied mathematicians. Solid mechanics is treated as a subset of mathematical engineering and courses on this topic which include theoretical, numerical and experimental aspects (as this text does) can be amongst the most interesting and accessible that an undergraduate science student can take. I have concentrated entirely on linear elasticity being, to the beginner, the most amenable and accessible aspect of solid mechanics. It is a subject with a long history, though its development in…mehr
This book is intended as an introductory text on Solid Mechanics suitable for engineers, scientists and applied mathematicians. Solid mechanics is treated as a subset of mathematical engineering and courses on this topic which include theoretical, numerical and experimental aspects (as this text does) can be amongst the most interesting and accessible that an undergraduate science student can take. I have concentrated entirely on linear elasticity being, to the beginner, the most amenable and accessible aspect of solid mechanics. It is a subject with a long history, though its development in relatively recent times can be traced back to Hooke (circa 1670). Partly because of its long history solid mechanics has an 'old fashioned' feel to it which is reflected in numerous texts written on the subject. This is particularly so in the classic text by Love (A Treatise on the Mathematical Theory of Elasticity 4th ed., Cambridge, Univ. Press, 1927). Although there is a wealth of information in that text it is not in a form which is easily accessible to the average lecturer let alone the average engineering student. This classic style avoiding the use of vectors or tensors has been mirrored in many other more 'modern' texts.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
1 Vectors.- 1.1 Introduction to vector algebra.- 1.2 The scalar product.- 1.3 The vector product.- 1.4 Applications of vectors to forces.- 1.5 Triple products.- 1.6 The index notation for vectors.- 1.7 Vector differential calculus.- 1.8 Vector integral calculus.- 2 Cartesian Tensors.- 2.1 Introduction.- 2.2 Rotation of Cartesian coordinates.- 2.3 Cartesian tensors.- 2.4 Properties of tensors.- 2.5 The rotation tensor.- 2.6 Isotropic tensors.- 2.7 Second order symmetric tensors.- 3 The Analysis of Stress.- 3.1 Introduction.- 3.2 The stress tensor.- 3.3 Principal axes.- 3.4 Maximum normal and shear stresses.- 3.5 Plane stress.- 3.6 Photoelastic measurement of principal stresses.- 4 The Analysis of Strain.- 4.1 The strain tensor.- 4.2 Physical interpretation of the strain tensor.- 4.3 Principal axes, principal strains.- 4.4 Principal strains and the strain rosette.- 4.5 The compatibility equations for strain.- 5 Linear Elasticity.- 5.1 Hooke's law and the simple tension experiment.- 5.2 The governing equations of linear eleasticity.- 5.3 Simple solutions.- 5.4 The Navier equation in linear elasticity.- 6 Energy.- 6.1 Strain energy and work.- 6.2 Kirchoff's uniqueness theorem.- 6.3 The reciprocal theorem.- 6.4 The Castigliano theorem.- 6.5 Potential energy.- 7 The General Torsion Problem.- 7.1 Introduction.- 7.2 The torsion function.- 7.3 Shearing stress in the torsion problem.- 7.4 Simple exact solutions in the torsion problem.- 7.5 Approximate formulae in the torsion problem.- 8 The Matrix Analysis of Structures.- 8.1 Introduction.- 8.2 Pin-jointed elements.- 8.3 Two and three dimensional pin-jointed structures.- 8.4 Beam elements.- 8.5 Equivalent nodal forces.- 9 Two Dimensional Elastostatics.- 9.1 Plane strain, plane stress and generalised plane stress.- 9.2 Exactsolutions to problems in plane strain.- 9.3 Approximations in two dimensional elastostatics.- Appendix 1 The Variational Calculus.- A1.1 The fundamental lemma.- A1.2 Functionals and the variational calculus.- A1.3 Construction of functionals.- A1.4 One dimensional fourth-order problems.- A1.5 Variational formulation of fourth-order problems.- References.
1 Vectors.- 1.1 Introduction to vector algebra.- 1.2 The scalar product.- 1.3 The vector product.- 1.4 Applications of vectors to forces.- 1.5 Triple products.- 1.6 The index notation for vectors.- 1.7 Vector differential calculus.- 1.8 Vector integral calculus.- 2 Cartesian Tensors.- 2.1 Introduction.- 2.2 Rotation of Cartesian coordinates.- 2.3 Cartesian tensors.- 2.4 Properties of tensors.- 2.5 The rotation tensor.- 2.6 Isotropic tensors.- 2.7 Second order symmetric tensors.- 3 The Analysis of Stress.- 3.1 Introduction.- 3.2 The stress tensor.- 3.3 Principal axes.- 3.4 Maximum normal and shear stresses.- 3.5 Plane stress.- 3.6 Photoelastic measurement of principal stresses.- 4 The Analysis of Strain.- 4.1 The strain tensor.- 4.2 Physical interpretation of the strain tensor.- 4.3 Principal axes, principal strains.- 4.4 Principal strains and the strain rosette.- 4.5 The compatibility equations for strain.- 5 Linear Elasticity.- 5.1 Hooke's law and the simple tension experiment.- 5.2 The governing equations of linear eleasticity.- 5.3 Simple solutions.- 5.4 The Navier equation in linear elasticity.- 6 Energy.- 6.1 Strain energy and work.- 6.2 Kirchoff's uniqueness theorem.- 6.3 The reciprocal theorem.- 6.4 The Castigliano theorem.- 6.5 Potential energy.- 7 The General Torsion Problem.- 7.1 Introduction.- 7.2 The torsion function.- 7.3 Shearing stress in the torsion problem.- 7.4 Simple exact solutions in the torsion problem.- 7.5 Approximate formulae in the torsion problem.- 8 The Matrix Analysis of Structures.- 8.1 Introduction.- 8.2 Pin-jointed elements.- 8.3 Two and three dimensional pin-jointed structures.- 8.4 Beam elements.- 8.5 Equivalent nodal forces.- 9 Two Dimensional Elastostatics.- 9.1 Plane strain, plane stress and generalised plane stress.- 9.2 Exactsolutions to problems in plane strain.- 9.3 Approximations in two dimensional elastostatics.- Appendix 1 The Variational Calculus.- A1.1 The fundamental lemma.- A1.2 Functionals and the variational calculus.- A1.3 Construction of functionals.- A1.4 One dimensional fourth-order problems.- A1.5 Variational formulation of fourth-order problems.- References.
Es gelten unsere Allgemeinen Geschäftsbedingungen: www.buecher.de/agb
Impressum
www.buecher.de ist ein Internetauftritt der buecher.de internetstores GmbH
Geschäftsführung: Monica Sawhney | Roland Kölbl | Günter Hilger
Sitz der Gesellschaft: Batheyer Straße 115 - 117, 58099 Hagen
Postanschrift: Bürgermeister-Wegele-Str. 12, 86167 Augsburg
Amtsgericht Hagen HRB 13257
Steuernummer: 321/5800/1497