Springer Berlin Heidelberg New York Barcelona Hong Kong London ONLINE LIBRARY Engineering Milan Paris Tokyo http://www.springer.de/engine/ M. P. Bendsoe, O. Sigmund Topolo gYOptimization Theory, Methods and Applications With 140 Figures Springer Prof. Dr. techn. Martin P. Bendsoe Technical University of Denmark Department of Mathematics 2800 Lyngby Denmark Prof. Dr. techn. Ole Sigmund Technical University of Denmark Department of Mechanical Engineering, Solid Mechanics 2800 Lyngby Denmark ISBN 3-540-42992-i Springer-Verlag Berlin Heidelberg New York CIP data applied for Die Deutsche Bibliothek - CIP-Einheitsaufnahme Bends0e, Martin P. : Topology optimization : theory, methods and applications / M. P. Bendsoe ; 0. Sigmund. - Berlin ; Heidelberg ; New York ; Barcelona ; Hong Kong ; London ; Milan ; Paris ; Tokyo : Springer, 2003 (Engineering online library) ISBN 3-540-42992-1 This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilm or in other ways, and storage in data banks. Duplication of this publication or parts thereof is permitted only under the provisions of the German Copyright Law of September 9, 1965, in its current version, and permission for use must always be obtained from Springer-Verlag. Violations are liable for prosecution act under German Copyright Law. Springer-Verlag Berlin Heidelberg New York a member of BertelsmannSpringer Science+Business Media GmbH http://www.springer.de © Springer-Verlag Berlin Heidelberg 2003 Printed in Germany The use of general descriptive names, registered names, trademarks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. Typesetting: Camera ready by authors Cover-design: Medio, Berlin Printed on acid-free paper (cid:9) SPIN: 10859778 (cid:9) 62 / 3020 hu - 5 4 3 2 10 - To the women of our lives: Susanne, Charlotte, Anne and Birgitte Preface "The art of structure is where to put the holes" Robert Le Ricolais, 1894-1977 This is a completely revised, updated and expanded version of the book titled "Optimization of Structural Topology, Shape and Material" (Bendsoe 1995). The field has since then developed rapidly with many new contributions to theory, computational methods and applications. This has meant that a simple editing of Bendspe (1995) had to be superseded by what is to a large extent a completely new book, now by two authors. This work is an attempt to provide a unified presentation of methods for the optimal design of topology, shape and material for continuum and discrete structures. The emphasis is on the now matured techniques for the topology design of continuum structures and its many applications that have seen the light of the day since the first monograph appeared. The technology is now well established and designs obtained with the use of topology optimization methods are in production on a daily basis. The efficient use of materials is important in many different settings. The aerospace industry and the automotive industry, for example, apply sizing and shape optimization to the design of structures and mechanical elements. Shape optimization is also used in the design of electromagnetic, electro- chemical and acoustic devices. The subject of non-linear, finite-dimensional optimization for this type of problem is now relatively mature. It has pro- duced a number of successful algorithms that are widely used for structural optimization. However, these methods are unable to cope with the problem of topology optimization, for either discrete or continuum structures. The optimization of the geometry and topology of structural lay-out has great impact on the performance of structures, and the last decade has seen a great amount of work in this important area of structural optimization. This has mainly been spurred by the success of the material distribution method for generating optimal topologies of structural elements. This defines shape in terms of a material density and geometry is described by what amounts to a raster representation as seen in computer graphics. Today one naturally distinguishes between the search for "classical" designs made from a given material, and methods that allow for a broader range of material usage. When considering materials in the large, the method unifies two subjects, each of intrinsic interests and previously considered distinct. One is structural optimization at the level of macroscopic design, using a macroscopic definition VIII of geometry given by for example thicknesses or boundaries. The other subject is micromechanics, the study of the relation between microstructure and the macroscopic behaviour of a composite material. Moreover, the introduction of composite material in the shape design context leads naturally to the design of materials themselves, widening the field of applications of structural design techniques. Materials with microstructure enter naturally in problems of optimal structural design, be it shape or sizing problems. This was for example clearly demonstrated in the paper by Cheng & Olhoff (1981) on optimal thickness distribution for elastic plates. Their work led to a series of works on optimal design problems introducing microstructure in the formulation of the prob- lem. The material distribution method for topology design first introduced as as a natural a computational tool in Bendsoe & Kikuchi (1988) can be seen continuation of these studies and has lead to the capability to reliably predict optimal topologies of continuum structures. For thin structures, that is, structures with a low fraction of available material compared to the spatial dimension of the structure, the material dis- tribution method predicts grid- and truss-like structures. Thus the material distribution method supplements classical analytical methods for the study of fundamental properties of grid like continua, as first treated by Michell. Ap- plications of numerical methods to truss problems and other discrete models were first described in the early sixties but now we see that these challenging large-scale problems can be solved with specialized algorithms that use the most recent developments in mathematical programming. In its most general setting shape optimization of continuum structures should consist of a determination for every point in space if there is material in that point or not. Alternatively, for a FEM discretization every element is a potential void or structural member. In this setting the topology of the structure is not fixed a priori, arid the general formulation should allow for the prediction of the layout of a structure. Similarly, the lay-out of a truss structure can be found by allowing all connections between a fixed set of nodal points as potential structural or vanishing members. Topology design problems formulated this way are inherently discrete optimization problems. For truss problems it is natural to avoid this by using the continuously vary- ing cross-sectional bar areas as design variables, allowing for zero bar areas. For continuum structures one can apply an interpolation scheme that works with a density of isotropic materials together with methods that steer the optimized designs to "classical" black and white designs or one can use a relaxation of the problem that introduces anisotropic composites such as lay- ered periodic media, also leading to a description of shape by a density of material. Irr both cases the density can take on all values between zero and one, and one can also make physical sense of intermediate density values. The approach to topology design outlined above is sometimes known as the ground structure approach. This means that for an initially chosen layout IX of nodal points in the truss structure or in the finite element mesh, the optimum structure connecting the imposed boundary conditions and external loads is found as a subset of all the elements of the initially chosen set of connections between the truss nodal points or the initially chosen set of finite elements. The positions of nodal points are not used as design variables, so a high number of nodal points should be used in the ground structure to obtain efficient topologies. Also, the number of nodal points is not used as design variables, so the approach appears as a standard sizing problem and for continuum structures, the topology design problem has been cast as a problem of finding the optimal density distribution of material in a fixed domain, modelled with a fixed FEM mesh. This is of major importance for the implementation of topology optimization methods. The field of structural optimization combines mechanics, variational cal- culus and mathematical programming to obtain better designs of structures. This places any author in a somewhat problematic position on how to present the material at hand. Here we take an operational approach, with strict mathematical formalism reserved for situations where this is crucial for a precise statement of results. The monograph falls in two parts. The first part (Chaps. 1 and 2) deals with the topology design within the framework of searching for optimum "classical designs" made from isotropic materials, cov- ering theory and computational procedures and describing the broad range of applications that have appeared in recent years. The second part concentrates on compliance design and emphasizes the use of composites and materials in the large for optimal structural design (Chap. 3). Here the particular format of the compliance functional plays a significant role, and this is also exploited for trusses, where much fundamental understanding can be obtained from a series of problem statements that can be devised (Chap. 4). The monograph also contains a substantial bibliography together with bibliographical notes' covering the main subjects of this exposition as well as related background material the reader may want to consult (Chap. 6). Finally, appendices (Chap. 5) cover various more technical aspects of the area, and Matlab codes that can be used for initial experiments in the field are included. It is the aim of this monograph to demonstrate the importance of topology and material design for structural optimization and that effective and mature means for handling such design problems do exist. Structural optimization enforces rather than removes the creative aspect of designing and the final design must be a product of creativity rather than availability or lack of analysis facilities. A topology design methodology is an important brick in providing such facilities. To avoid long lists of references in the text, use is made of bibliographical notes for a survey of the literature. Reference to the notes is by numbers in square brackets, e.g., [36].
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