Elastoplastic topology optimization of cyclically loaded structures via direct methods for shakedown

• Published in: Structural and multidisciplinary optimization Vol. 64; no. 1; pp. 189 - 217
• Main Authors: Boissier, Mathilde, Deaton, Joshua D., Beran, Philip A., Vermaak, Natasha
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.07.2021; Springer Nature B.V; Springer Verlag
• Subjects: Computational Mathematics and Numerical Analysis; Design; Elastic deformation; Elastic limit; Elastic recovery; Elasticity; Elastoplasticity; Engineering; Engineering Design; Lower bounds; Mathematics; Mechanics; Numerical Analysis; Optimization; Optimization and Control; Partial differential equations; Physics; Plastic deformation; Research Paper; Strain; Theoretical and Applied Mechanics; Topology optimization; Weight reduction; Direct method; Elastoplastic; Shakedown; Level set method; Shape optimization
• ISSN: 1615-147X; 1615-1488
• DOI: 10.1007/s00158-021-02875-6

For the first time, the lower bound shakedown theorem is integrated into a level set–based topology optimization framework to identify lightweight elastoplastic designs. Shakedown is a cyclic elastoplastic behavior in which, upon cycling beyond the elastic limit, the accumulation of plastic strain arrests and purely elastic behavior is recovered. In contrast to most elastoplastic topology optimization, the use of a lower bound shakedown limit allows elastoplastic shakedown limits to be rigorously estimated using only the elastic solution. Under small deformation assumptions, this amounts to solving one simple partial differential equation, avoiding the non-linearity associated with plasticity, and thus simplifying the resolution process. Numerical results are provided for several benchmark examples. The results highlight the design performance enhancements attributed to allowing elastoplastic shakedown to occur instead of designing to first yield. In particular, up to 10% reduction in weight is found for the simple structures considered.