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Modeling the progressive collapse behavior of metal foams

โœ Scribed by Sergey L. Lopatnikov; Bazle A. Gama; John W. Gillespie Jr.

Book ID
103833435
Publisher
Elsevier Science
Year
2007
Tongue
English
Weight
566 KB
Volume
34
Category
Article
ISSN
0734-743X

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โœฆ Synopsis

Quasi-static axial compression behavior of cellular materials can be explained by two ideal deformation scenarios: homogeneous deformation and progressive collapse. An elastic-plastic-rigid (E-P-R) foam model is used to derive the energy absorbed under these two deformation scenarios. It has been identified that the progressive collapse mode of deformation can absorb more energy than homogeneous deformation prior to full densification. The additional energy is shown to be proportional to the magnitude of the tangent modulus in the plateau region of the stress-strain curve. The model also shows that energy absorption is equivalent for all deformation states of progressive and homogenous collapse for materials that exhibit elastic-perfectly-plastic-rigid behavior.

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