Optimal Structural Design under Stability Constraints

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Mechanics of Elastic Stability 13

ISBN:	9401077371
ISBN 13:	9789401077378
Autor:	Gajewski, Antoni/Zyczkowski, Michal
Verlag:	Springer Verlag GmbH
Umfang:	xvi, 470 S.
Erscheinungsdatum:	06.10.2011
Auflage:	1/2011
Produktform:	Kartoniert
Einband:	Kartoniert

Inhaltsangabe1. Elements of the theory of structural stability.- 1.1 Definition of stability.- 1.1.1 Lyapunov’s definition of stability.- 1.1.2 Lyapunov’s first method.- 1.1.3 Lyapunov’s second method.- 1.1.4 The fundamental problem of stability for deformable bodies.- 1.2 Stability of elastic structures.- 1.2.1 Classification of loadings.- 1.2.2 Kinetic analysis.- 1.2.3 Static criterion of the loss of stability.- 1.2.4 Energy approach for conservative systems.- 1.2.5 Energy approach for nonconservative systems.- 1.2.6 Effect of imperfections.- 1.2.7 Coincident critical points and their relation to optimal design.- 1.2.8 Stability under combined loadings.- 1.3 Elastic-plastic stability.- 1.3.1 General remarks.- 1.3.2 Plastically active and passive zones.- 1.3.3 Example of a column.- 1.3.4 Bifurcation and stability.- 1.4 Stability and buckling in creep conditions.- 1.4.1 General remarks.- 1.4.2 Creep stability of perfect structures.- 1.4.3 Creep buckling of imperfect structures.- 1.4.4 Snap-through in creep conditions.- 2. Problems of optimal structural design.- 2.1 Formulation of optimization problems.- 2.2 Design objectives and their criteria.- 2.3 Design variables.- 2.4 Constraints and their criteria.- 2.4.1 Classification of constraints.- 2.4.2 Strength constraints and the shapes of uniform strength.- 2.4.3 Stability constraints.- 2.4.4 Stiffness or compliance constraints.- 2.4.5 Vibration constraints.- 2.4.6 Relaxation constraints.- 2.4.7 Technological constraints.- 2.5 Equation of state.- 2.6 Stability constraints in structural optimization.- 2.6.1 General remarks.- 2.6.2 Eigenvalue as constraints, multimodal optimal design.- 2.6.3 Simultaneous mode design, mode interaction.- 2.6.4 Local stability condition and the shapes of uniform stability.- 2.6.5 Peculiarities of creep buckling constraints.- 2.6.6 Historical notes and surveys.- 3. Methods of structural optimization.- 3.1 Calculus of variations.- 3.1.1 General remarks.- 3.1.2 Classical problems of calculus of variations.- 3.1.3 Equality constraints.- 3.1.4 Functions of functionals.- 3.1.5 Vectorial notation for single integrals.- 3.1.6 Variable ends, transversality conditions, corners.- 3.1.7 Problems of Bolza and Mayer.- 3.1.8 Sufficient conditions.- 3.1.9 Approximate methods of variational calculus.- 3.2 Pontryagin’s maximum principle.- 3.2.1 Equations of state and boundary conditions.- 3.2.2 Objective functional.- 3.2.3 Hamiltonian and the maximum principle.- 3.2.4 Inequality constraints.- 3.2.5 Problems of Bolza and Mayer.- 3.2.6 Additional parametric optimization.- 3.2.7 Balakrishnan’s e-method in optimal control.- 3.3 Sensitivity analysis.- 3.3.1 General remarks.- 3.3.2 Approach based on differential equations of state.- 3.3.3 Variational approach.- 3.3.4 Eigenvalue problems.- 3.3.5 Optimal structural remodeling and reanalysis.- 3.3.6 Application of perturbation methods.- 3.4. Parametric optimization, mathematical programming.- 3.4.1 Statement of the problem, necessary conditions.- 3.4.2 Methods of transformation linearizing the inequality constraints.- 3.4.3 Finite element discretization.- 3.4.4 Application of sensitivity analysis.- 3.4.5 Numerical methods of parametric optimization.- 3.4.6 Decomposition in parametric structural optimization.- 3.4.7 Multicriterial optimization.- 4. Elastic and inelastic columns.- 4.1 Stability of non-prismatic columns.- 4.1.1 General nonlinear governing equations.- 4.1.2 General precritical state and relevant conditions of loss of stability.- 4.1.3 Momentless precritical state and relevant conditions of loss of stability.- 4.1.4 Inextensible axis and neglecting of shear deformations.- 4.1.5 Examples of loadings independent of state variables.- 4.1.6 Examples of loadings dependent on state variables.- 4.1.7 Effective forms of constitutive equations.- 4.2 Unified approach to optimization of columns.- 4.2.1 General statement of the optimization problems.- 4.2.2 Geometric relations for typical cross-sections.- 4.2.3 Solution by Pontryagin’s maxi

Artikelnummer: 5645486 Kategorie: Mechanik, Akustik

Beschreibung

Beschreibung

The first optimal design problem for an elastic column subject to buckling was formulated by Lagrange over 200 years ago. However, rapid development of structural optimization under stability constraints occurred only in the last twenty years. In numerous optimal structural design problems the stability phenomenon becomes one of the most important factors, particularly for slender and thin-walled elements of aerospace structures, ships, precision machines, tall buildings etc. In engineering practice stability constraints appear more often than it might be expected; even when designing a simple beam of constant width and variable depth, the width - if regarded as a design variable - is finally determined by a stability constraint (lateral stability). Mathematically, optimal structural design under stability constraints usually leads to optimization with respect to eigenvalues, but some cases fall even beyond this type of problems. A total of over 70 books has been devoted to structural optimization as yet, but none of them has treated stability constraints in a sufficiently broad and comprehensive manner. The purpose of the present book is to fill this gap. The contents include a discussion of the basic structural stability and structural optimization problems and the pertinent solution methods, followed by a systematic review of solutions obtained for columns, arches, bar systems, plates, shells and thin-walled bars. A unified approach based on Pontryagin's maximum principle is employed inasmuch as possible, at least to problems of columns, arches and plates. Parametric optimization is discussed as well.