Boundary Effects in the Eigenstrain Method |
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| Authors: | S.-Y. Lee S. Coratella A. Brügger B. Clausen D.W. Brown K. Langer M. E. Fitzpatrick I. C. Noyan |
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| Affiliation: | 1.Applied Physics and Applied Mathematics,Columbia University,New York,USA;2.Aerospace Mechanics Division,University of Dayton Research Institute,Dayton,USA;3.Civil Engineering and Engineering Mechanics,Columbia University,New York,USA;4.MST-8, Los Alamos National Laboratory,Los Alamos,USA;5.Air Force Research Laboratory, AFRL/RQVS,Wright-Patterson AFB,USA;6.Faculty of Engineering and Computing,Coventry University,Coventry,UK |
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| Abstract: | ![]()
We present a comprehensive study of the effects of internal boundaries on the accuracy of residual stress values obtained from the eigenstrain method. In the experimental part of this effort, a composite specimen, consisting of an aluminum cylinder sandwiched between steel cylinders of the same diameter, was uniformly heated under axial displacement constraint. During the experiment, the sample temperature and the reaction stresses in the load frame in response to changes in sample temperature were monitored. In addition, the local (elastic) lattice strain distribution within the specimen was measured using neutron diffraction. The eigenstrain method, utilizing finite element modeling, was then used to predict the stress field existing within the sample in response to the constraint imposed by the load frame against axial thermal expansion. Our comparison of the computed and measured stress distributions showed that, while the eigenstrain method predicted acceptable stress values away from the cylinder interfaces, its predictions did not match experimentally measured values near them. These observations indicate that the eigenstrain method is not valid for sample geometries with this type of internal boundaries. |
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