Transfer of Natural Micro Structures to Bionic Lightweight Design Proposals

doi:10.1016/S1672-6529(13)60241-3

摘要/Abstract

关键词: biomimetic, finite elements, design space, design principle, topology optimization, parametric optimization, dia-toms, radiolarian

Abstract:

The abstraction of complex biological lightweight structure features into a producible technical component is a funda-mental step within the transfer of design principles from nature to technical lightweight solutions. A major obstacle for the transfer of natural lightweight structures to technical solutions is their peculiar geometry. Since natural lightweight structures possess irregularities and often have extremely complex forms due to elaborate growth processes, it is usually necessary to simplify their design principles. This step of simplification/abstraction has been used in different biomimetic methods, but so far, it has an arbitrary component, i.e. it crucially depends on the competence of the person who executes the abstraction. This paper describes a new method for abstraction and specialization of natural micro structures for technical lightweight compo-nents. The new method generates stable lightweight design principles by using topology optimization within a design space of preselected biological archetypes such as diatoms or radiolarian. The resulting solutions are adapted to the technical load cases and production processes, can be created in a large variety, and may be further optimized e.g. by using parametric optimization.

Key words: finite elements, design space, design principle, topology optimization, parametric optimization, dia-toms, radiolarian, biomimetic

M. Maier, D. Siegel, K.-D. Thoben, N. Niebuhr, C. Hamm. [J]. J4, 2013, 10(4): 469-478.

M. Maier, D. Siegel, K.-D. Thoben, N. Niebuhr, C. Hamm. Transfer of Natural Micro Structures to Bionic Lightweight Design Proposals[J]. J4, 2013, 10(4): 469-478.

参考文献

[1] Darwin C. The Origin of Species, Mundus Publishing, 1928.

[2] Nachtigall W. Bionik - Design für funktionelles Gestalten, Springer Verlag, Heidelberg, Germany, 1997. (in German)

[3] Liu K, Jiang L. Bio-inspired design of multiscale structures for function integration. Nano Today, 2011, 6, 155–175.

[4] Milwich M, Speck T, Speck O, T. Stegmaier, Planck H. Biomimetics and technical textiles: Solving engineering problems with the help of nature’s wisdom. American Journal of Botany, 2006, 93, 1455–1465.

[5] Ma J F, Chen W Y, Zhao L, Zhao D H. Elastic buckling of bionic cylindrical shells based on bamboo. Journal of Bionic Engineering, 2008, 5, 231–238.

[6] Jiao H, Zhang Y, Chen W. The lightweight design of low RCS pylon based on structural bionics. Journal of Bionic Engineering, 2010, 7, 182–190.

[7] Zhao L, Ma J, Wang T, Xing D. Lightweight design of me-chanical structures based on structural bionic methodology. Journal of Bionic Engineering, 2010, 7, 224–231.

[8] Xing D H, Chen W, Zhao L, Ma J F. Structural bionic design for high-speed machine tool working table based on distri-bution rules of leaf veins. Science China Technological Sciences, 2012, 55, 2091–2098.

[9] Zhao L, Ma J, Chen W, Guo H. Lightweight design and verification of grantry machining center crossbeam based on structural bionics. Journal of Bionic Engineering, 2011, 8, 201–206.

[10] Hamm C, Merkel R, Springer O, Jurkojc P, Maier C, Prechtel K, Smetacek V. Architecture and material proper-ties of diatom shells provide effective mechanical protection. Nature, 2003, 421, 841–843.

[11] Sumper M, Brunner E. Learning from diatoms: Nature’s tools for the production of nanostructured silica. Advanced Functional Materials, 2006, 16, 17–26.

[12] Hamm C. Kieselalgen als Muster für technische Konstruktionen. BIOSpektrum, 2005, 1, 41–43. (in German)

[13] Hamm C. Evolutionary Light Structure Engineering: Ein Verfahren zur Verbesserung des Strukturleichtbaus, Technical report, Alfred-Wegener-Institut für Polar-und Meeresforschung, 2008. (in German)

[14] Round R E, Crawford R M, Mann D G. The Diatoms, Press Syndicate of the University of Cambridge, Cambridge, 1990.

[15] Smetacek V. A watery arms race. Nature, 2001, 411, 745–745.

[16] Hamm C, Smetacek V. Armor: Why, when and how? In: Falkowski P G, Knoll A H (eds.), Evolution of Primary Producers in the Sea, Elsevier, Amsterdam, 2007, 311–332.

[17] Maier M, Schulz J, Thoben K D. Verfahren zur funktionalen Ähnlichkeitssuche technischer Bauteile in 3D-Datenbanken. Datenbank-Spektrum, 2012, 12, 131–140. (in German)

[18] Niebuhr N. Konstruktion von Offshore - Gründungsstrukturen nach Biologischem Leichtbauverfahren. Master’s thesis, University of technology, business and design - Hochschule Wismar, 2010. (in German)

[19] Friedrichs L, Maier M, Hamm C. A new method for exact three-dimensional reconstructions of diatom frustules. Journal of Microscopy, 2012, 248, 208–217.

[20] Nahrendorf M, Badea C, Hedlund L W, Figueiredo J L, Sosnovik D E, Johnson G A, Weissleder R. High-resolution imaging of murine myocardial infarction with de-layed-enhancement cine micro-CT. American Journal of Physiology: Heart and Circulatory Physiology, 2007, 292, H3172–H3178.

[21] Marinello F, Bariani P, Savio E, Horsewell A, De Chiffre L. Critical factors in SEM 3D stereo microscopy. Measurement Science and Technology, 2008, 19, 065705.

[22] Losic D, Pillar R, Dilger T, Mitchell J, Voelcker N. Atomic force microscopy (AFM) characterisation of the porous sil-ica nanostructure of two centric diatoms. Journal of Porous Materials, 2007, 14, 61–69.

[23] Yonath A. X-ray crystallography at the heart of life science. Current Opinion in Structural Biology, 2011, 21, 622–626.

[24] Pierson J, Sani M, Tomova C, Godsave S, Peters P. Toward visualization of nanomachines in their native cellular envi-ronment. Histochemistry and Cell Biology, 2009, 132, 253–262.

[25] Gipson D J, Mills P, Wouts R, Grininger M, Vonck J, Kühl-brandt W. Direct structural insight into the sub-strate-shuttling mechanism of yeast fatty acid synthase by electron cryomicroscopy. Proceedings of the National Academy of Sciences of USA, 2010, 107, 9164–9169.

[26] Bendsøe M P, Sigmund O. Topology Optimization -Theory, Methods and Applications, Springer-Verlag, New York, 2003.

[27] Bendsøe M P, Kikuchi N. Generating optimal topologies in optimal design using a homogenization method. Computer Methods in Applied Mechanics and Engineering, 1988, 71, 197–224.

[28] Lindby T, Santos J L T. Shape optimization of three-dimensional shell structures with the shape parame-terization of a CAD system. Structural and Multidiscipli-nary Optimization, 1999, 18, 126–133.

[29] Van der Auweraer H, Van Langenhove T, Brughmans M, Bosmans I, Masri N, Donders S. Application of mesh morphing technology in the concept phase of vehicle de-velopment. International Journal of Vehicle Design, 2007, 43, 281–305.