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- Herausgeber: John Wiley & Sons
- Kategorie: Fachliteratur
- Sprache: Englisch
Since the middle of the 20th Century yield design approaches have been identified with the lower and upper bound theorem of limit analysis theory – a theory associated with perfect plasticity. This theory is very restrictive regarding the applicability of yield design approaches, which have been used for centuries for the stability of civil engineering structures.
This book presents a theory of yield design within the original "equilibrium/resistance" framework rather than referring to the theories of plasticity or limit analysis; expressing the compatibility between the equilibrium of the considered structure and the resistance of its constituent material through simple mathematical arguments of duality and convex analysis results in a general formulation, which encompasses the many aspects of its implementation to various stability analysis problems.
After a historic outline and an introductory example, the general theory is developed for the three-dimensional continuum model in a versatile form based upon simple arguments from the mathematical theory of convexity. It is then straightforwardly transposed to the one-dimensional curvilinear continuum, for the yield design analysis of beams, and the two-dimensional continuum model of plates and thin slabs subjected to bending. Field and laboratory observations of the collapse of mechanical systems are presented along with the defining concept of the multi-parameter loading mode. The compatibility of equilibrium and resistance is first expressed in its primal form, on the basis of the equilibrium equations and the strength domain of the material defined by a convex strength criterion along with the dual approach in the field of potentially safe loads, as is the highlighting of the role implicitly played by the theory of yield design as the fundamental basis of the implementation of the ultimate limit state design (ULSD) philosophy with the explicit introduction of resistance parameters.
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Seitenzahl: 237
Veröffentlichungsjahr: 2013
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Table of Contents
Preface
Chapter 1. Origins and Topicality of a Concept
1.1. Historical milestones
1.2. Topicality of the yield design approach
1.3. Bibliography
Chapter 2. An Introductory Example of the Yield Design Approach
2.1. Setting the problem
2.2. Potential stability of the structure
2.3. To what extent potential stability is a relevant concept?
2.4. Bibliography
Chapter 3. The Continuum Mechanics Framework
3.1. Modeling the continuum
3.2. Dynamics
3.3. The theory of virtual work
3.4. Statically and kinematically admissible fields
3.5. Bibliography
Chapter 4. Primal Approach of the Theory of Yield Design
4.1. Settlement of the problem
4.2. Potentially safe loads
4.3. Comments
4.4. Some usual isotropic strength criteria
4.5. Bibliography
Chapter 5. Dual Approach of the Theory of Yield Design
5.1. A static exterior approach
5.2. A kinematic necessary condition
5.3. The π functions
5.4. π functions for usual isotropic strength criteria
5.5. Bibliography
Chapter 6. Kinematic Exterior Approach
6.1. Equation of the kinematic exterior approach
6.2. Relevant virtual velocity fields
6.3. One domain, two approaches
6.4. Bibliography
Chapter 7. Ultimate Limit State Design from the Theory of Yield Design
7.1. Basic principles of ultimate limit state design
7.2. Revisiting the yield design theory in the context of ULSD
7.3. The yield design theory applied to ULSD
7.4. Conclusion
7.5. Bibliography
Chapter 8. Optimality and Probability Approaches of Yield Design
8.1. Optimal dimensioning and probabilistic approach
8.2. Domain of potential stability
8.3. Optimal dimensioning
8.4. Probabilistic approach of yield design
8.5. Bibliography
Chapter 9. Yield Design of Structures
9.1. The curvilinear one-dimensional continuum
9.2. Implementation of the yield design theory
9.3. Typical strength criteria
9.4. Final comments
9.5. Bibliography
Chapter 10. Yield Design of Plates: the Model
10.1. Modeling plates as two-dimensional continua
10.2. Dynamics
10.3. Theorem/principle of virtual work
10.4. Plate model derived from the three-dimensional continuum
10.5. Bibliography
Chapter 11. Yield Design of Plates Subjected to Pure Bending
11.1. The yield design problem
11.2. Implementation of the yield design theory
11.3. Strength criteria and π functions
11.4. Final comments
11.5. Bibliography
Index
First published 2013 in Great Britain and the United States by ISTE Ltd and John Wiley & Sons, Inc.
Apart from any fair dealing for the purposes of research or private study, or criticism or review, as permitted under the Copyright, Designs and Patents Act 1988, this publication may only be reproduced, stored or transmitted, in any form or by any means, with the prior permission in writing of the publishers, or in the case of reprographic reproduction in accordance with the terms and licenses issued by the CLA. Enquiries concerning reproduction outside these terms should be sent to the publishers at the undermentioned address:
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© ISTE Ltd 2013
The rights of Jean Salençon to be identified as the author of this work have been asserted by him in accordance with the Copyright, Designs and Patents Act 1988.
Library of Congress Control Number: 2013931025
British Library Cataloguing-in-Publication Data
A CIP record for this book is available from the British Library
ISBN: 978-1-84821-540-5
Preface
“One of the principal objects of theoretical research in any department of knowledge is to find the point of view from which the subject appears in its greatest simplicity”1
This book originates from the lecture notes for a course on yield design taught at Hong Kong City University during recent years. It is presented in the form of a survey of the theory of yield design, which brings together and summarizes the books and lecture notes I published in French on that topic when teaching at École Nationale des Ponts et Chausssées and École Polytechnique (Paris, France).
The terminology “yield design” has been chosen as a counterpart and translation of the French “Calcul à la rupture” or “Analyse à la rupture” which has been used for a long time by civil engineers and others to refer to stability analyses of structures where only the concepts of equilibrium and resistance are taken into account.
In an explicit form, such analyses have been carried out for nearly four centuries, if we take Galileo’s Discorsi as a starting point of the story, but they were overshadowed by the achievements of the theory of elasticity in the 19th Century.
To make a long story short, we may jump to the mid-20th Century when we observe a renewal of interest in the yield design methods with the development of the theory of plasticity. At that time, within the framework of the perfectly plastic model with associated flow rule for the constituent material, the lower and upper bound theorems of limit analysis and the theory of limit loads were established, which provide the traditional yield design approaches with sound theoretical bases. In particular, the upper bound theorem of limit analysis refers to the kinematic approach, where the rate of work by the external forces is compared with the plastic dissipation rate. Also, after several unconvincing attempts based on the concept of a rigid perfectly plastic material, the status of limit loads was definitely settled in the 1970s through the mathematical theorem of existence and uniqueness of the solution to the elastoplastic evolution problem: under the assumption of elastic and perfectly plastic behavior with associated flow rule, these loads are the maximum loads that can actually be sustained by the system considered in a given geometry.
This is a happy ending to the story from the theoretical point of view but, since it is dependent on the assumption of a perfectly plastic behavior with associated flow rule, it may appear as substantiating the idea that the yield design approach loses all interest when this assumption is not valid (which is often the case for practical problems, e.g. stability analyses of earth structures in civil engineering).
As a matter of fact, the lower and upper bound theorems are only the consequences of the sole assumption that the resistance of the constituent material is defined by a convex domain assigned to the internal forces. In particular, the upper bound theorem is derived from the dual definition of this domain without referring to a flow rule or constitutive equation. Therefore, these theorems hold as the lower and upper bound theorems for the extreme loads in the yield design theory, encompassing the many aspects of its implementation to various stability analysis problems. From the theoretical viewpoint, the status of the extreme loads is now restricted to that of upper bounds for the stability or load carrying capacity of the system. This does not make any difference in what concerns the application of the method to practice since practical validation is the general rule come what may.
Therefore, the purpose of this book is to present a theory of yield design within the original “equilibrium/resistance” framework without referring to the theories of plasticity or limit analysis. The general theory is developed for the three-dimensional continuum model in a versatile form based on simple arguments from the mathematical theory of convexity. It is then straightforwardly transposed to the one-dimensional curvilinear continuum, for the yield design analysis of beams, and to the two-dimensional continuum model of plates and thin slabs subjected to bending.
The book is structured as follows:
Chapters 4 – 6 present the core of the theory:
Acknowledgment
The author wishes to express his gratitude to Professors Habibou Maitournam, Noël Challamel and Pierre Suquet for their friendly comments and suggestions that contributed to the improvement of this book.
Jean SALENÇONMarch 2013
1 GIBBS J.W., Proceedings of the American Academy of Arts and Sciences, May 1880 – June 1881, XVI, VIII, Boston, University Press/John Wilson & Co., pp. 420–421, 1881.
Chapter 1
Origins and Topicality of a Concept
Limit state design is, to some extent, a familiar terminology within the syllabuses of civil engineers’ education, as it appears explicitly in the stability analyses of various types of structures or is present “anonymously” in the methods used for such analyses. Nevertheless, the variety of the corresponding approaches often makes it difficult to recognize that they proceed from the same fundamental principles, which are now the basis of the ultimate limit state design (ULSD) approach to the safety analysis of structures. As an introduction to the theory, this chapter will both present some famous historical milestones and the topicality of the subject referring to the principles of ULSD.
1.1. Historical milestones
1.1.1. Dialogs concerning two new sciences
The fundamental concept to be acknowledged first is that of yield strength as introduced by Galileo in his Discorsi [GAL 38a] on the simple experiment of a specimen in pure tension (Figure 1.1).
Figure 1.1.Longitudinal pull test (Galileo, Discorsi, 1st day [GAL 38a])
Galileo uses this first characterization of the tenacity and coherence (tenacità e coerenza) of the material to explain the difficulty he finds in breaking a rod or a beam in tension while it is far easier to break it in bending: “A prism or solid cylinder of glass, steel, wood or other breakable material which is capable of sustaining a very heavy weight when applied longitudinally is, as previously remarked, easily broken by the transverse application of a weight which may be much smaller in proportion as the length of the cylinder exceeds its thickness”. Considering a cantilever beam () built in a wall (section ) and subjected to a weight applied at the other extremity (section ), he first defines the “”. Then, he assumes that this resistance to tension will be localized in the section of the beam where it is fastened to the wall and that “”. The reasoning follows “” [GAL 38a]. Introducing the second fundamental concept of the yield design approach, namely , by writing the balance equation for the lever about , Galileo finally relates the “” to its “ ” through the ratio of the short lever arm 2 to the long lever arm .
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