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TECHNICAL PAPERS

Variational Estimates for the Effective Response of Shape Memory Alloy Actuated Fiber Composites

[+] Author and Article Information
J. P. Briggs

Charles Schwab & Company, SF211MN-8-223, 101 Montgomery Street, San Francisco, CA 94104

P. Ponte Castaneda

Department of Mechanical Engineering and Applied Mechanics, University of Pennsylvania, Philadelphia, PA 19104-6315

J. Appl. Mech 69(4), 470-480 (Jun 20, 2002) (11 pages) doi:10.1115/1.1464873 History: Received April 10, 2001; Revised September 27, 2001; Online June 20, 2002
Copyright © 2002 by ASME
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References

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Figures

Grahic Jump Location
Longitudinal, isothermal stress cycling for an SMA fiber where the initial phase mixture and strain are determined by temperature
Grahic Jump Location
Longitudinal, isothermal stress cycling with compression for an SMA fiber where the initial phase mixture and strain are determined by temperature
Grahic Jump Location
Longitudinal, isothermal stress cycling of an SMA fiber with a prestress
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Thermal cycling of an SMA fiber with a constant tensile prestress
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Fiber composite with local coordinate system
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Loading and heating scenarios for SMA composite
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Traction-free temperature cycle using three different matrix stiffnesses
Grahic Jump Location
Initial application of longitudinal traction of 100 MPa on the composite with subsequent temperature cycle
Grahic Jump Location
Initial application of transverse shear traction of 100 MPa on the composite with subsequent temperature cycle
Grahic Jump Location
Initial longitudinal prestress in the fiber with subsequent temperature cycle
Grahic Jump Location
Initial thermal transformation strain with a single longitudinal traction of 300 MPa on the composite
Grahic Jump Location
Initial thermal transformation strain with a single longitudinal stress cycle of 200 MPa on the composite
Grahic Jump Location
Initial thermal transformation strain with a single transverse shear stress cycle of 300 MPa on the composite
Grahic Jump Location
Initial thermal transformation strain with a single longitudinal and transverse shear stress cycle of 300 MPa on the composite

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