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Structural and Multidisciplinary Optimization
Erschienen in: Structural and Multidisciplinary Optimization 3/2014

01.09.2014 | RESEARCH PAPER

A non-parametric free-form optimization method for shell structures

verfasst von: Masatoshi Shimoda, Yang Liu

Erschienen in: Structural and Multidisciplinary Optimization | Ausgabe 3/2014

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Abstract

This paper presents a numerical shape optimization method for the optimum free-form design of shell structures. It is assumed that the shell is varied in the out-of-plane direction to the surface to determine the optimal free-form. A compliance minimization problem subject to a volume constraint is treated here as an example of free-form design problem of shell structures. This problem is formulated as a distributed-parameter, or non-parametric, shape optimization problem. The shape gradient function and the optimality conditions are theoretically derived using the material derivative formulae, the Lagrange multiplier method and the adjoint variable method. The negative shape gradient function is applied to the shell surface as a fictitious distributed traction force to vary the shell. Mathematically, this method is a gradient method with a Laplacian smoother in the Hilbert space. Therefore, this shape variation makes it possible both to reduce the objective functional and to maintain the mesh regularity simultaneously. With this method, the optimal smooth curvature distribution of a shell structure can be determined without shape parameterization. The calculated results show the effectiveness of the proposed method for the optimum free-form design of shell structures.
Vorheriger Artikel Analysis and design of acoustic transition sections for impedance matching and mode conversion
Nächster Artikel Structural static reanalysis for modification of supports

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Literatur
Azegami H (1994) A solution to domain optimization problems. Trans Japan Soc Mech Eng Series A 60:1479–1486CrossRef
Azegami H, Kaizu S, Shimoda M, Katamine E (1997) Irregularity of shape optimization problems and an improvement technique. Comput Aided Optimum Des Struct V:309–326
Azegami H, Takeuchi K (2006) A smoothing method for shape optimization: traction method using the robin condition. Int J Comput Methods 3:21–33CrossRefMATHMathSciNet
Belegundu A, Rajan S (1988) A shape optimization approach based on natural design variables and shape functions. Comput Methods Appl Mech Eng 66(1):87–106CrossRefMATH
Bletzinger KU, Firl M, Linhard J, Wuchner R (2009) Computational morphogenesis of free form shells: filter methods to create alternative solutions. In: Proceedings of the IASS Symposium 2009, Valencia
Bletzinger KU, Firl M, Linhard J, Wuchner R (2010) Optimal shapes of mechanically motivated surfaces. Comput Methods Appl Mech Eng 199(5–8):324–333CrossRefMATH
Braibant V, Fleury C (1984) Shape optimal design using b-splines. Comput Methods Appl Mech Eng 44:247–267CrossRefMATH
Choi KK, Kim NH (2005a) Structural sensitivity analysis and optimization, vol 1. Springer, New York
Choi KK, Kim NH (2005b) Structural sensitivity analysis and optimization, vol 2. Springer, New York
Imam M (1982) Three-dimensional shape optimization. Int J Numer Methods Eng 18:661–673CrossRefMATH
Isler H (1961) New shapes for shells. Bulletin of the IASS Paper C3(8)
Le C, Bruns T, Tortorelli D (2011) A gradient-based parameter-free approach to shape optimization. Comput Methods Appl Mech Eng 200:985–996CrossRefMATHMathSciNet
Leiva PL (2010) Freeform optimization: a new capability to perform grid by grid shape optimization of structures. In: 6th China-Japan-Korea joint symposium on optimization of structural and mechanical systems
Scherer M, Denzer R, Steinmann P (2010) A fictitious energy approach for shape optimization. Int J Numer Meth Eng 82:269–302MATHMathSciNet
Ramm E, Bletzinger K-U, Reitiger R (1993) Shape optimization of shell structures. Int J Shell Spat Struct 34(2):103–121
Rao V, Hinton E (1994) Analysis and optimization of prismatic plate and shell structures with curved planform. Shape Optim Comput Struct 52(2):341–351CrossRef
Reddy JN (1999) Theory and analysis of elastic plates. Taylor and Francis, Philadelphia
Shimoda M, Azegami H, Sakurai T (1995) Shape optimization of linear elastic structures subject to multiple loading conditions-? a traction method approach to minimum volume design. Curr Top Comput Mech ASME 305:319–326
Shimoda M, Nakata Y (2012) Application of shape optimization method to artificial leaf design. In: WIT Transactions on Ecology and Environment, vol 160. WIT Press. doi:10.​2495/​DN120151
Shimoda M, Tsuji J (2006) Non-parametric shape optimization method for rigidity design of automotive sheet metal structures. SAE J Pass Cars Mech Syst 2006-01-0584:483–492
Shimoda M, Tsuji J, Azegami H (2007) Non-parametric shape optimization method for thin-walled structures under strength criterion. Transactions of the Wessex institute on the built environment. Comput Aided Optim Des Struct X 91:179–188
Sokolowski J, Zolesio JP (1991) Introduction to shape optimization: shape sensitivity analysis. Springer-Verlag, New York
Taroco E, Feijoo RA (2004) A unified approach for shape sensitivity analysis of elastic shells. Struct Multidisc Optim 27:66–79CrossRefMATHMathSciNet
Thomas H, Zhou M, Schramm U (2002) Issues of commercial optimization software development. Struct Multidiscip Optim 23(2):97–110CrossRef
Ugail H, Wilson MJ (2003) Efficient shape parameterization for automatic design optimization using a partial differential equation formulation. Comput Struct 81:2601–2609CrossRef
Uysal M, Gul R, Uzman U (2007) Optimum shape design of shell structures. Eng Struct 29:80–87CrossRef
Yamazaki K, Vanderplaats GN (1993) Design sensitivity analysis with isoparametric shell elements. Struct Optim 5:152–158CrossRef
Metadaten
Titel
A non-parametric free-form optimization method for shell structures
verfasst von
Masatoshi Shimoda
Yang Liu
Publikationsdatum
01.09.2014
Verlag
Springer Berlin Heidelberg
Erschienen in
Structural and Multidisciplinary Optimization / Ausgabe 3/2014
Print ISSN: 1615-147X
Elektronische ISSN: 1615-1488
DOI
https://doi.org/10.1007/s00158-014-1059-1

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