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Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys

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Zeitschriftentitel: Journal of Intelligent Material Systems and Structures
Personen und Körperschaften: Yang, Shengyou, Dui, Guansuo, Liu, Bingfei
In: Journal of Intelligent Material Systems and Structures, 24, 2013, 4, S. 431-440
Medientyp: E-Article
Sprache: Englisch
veröffentlicht:
SAGE Publications
Schlagwörter:
author_facet Yang, Shengyou
Dui, Guansuo
Liu, Bingfei
Yang, Shengyou
Dui, Guansuo
Liu, Bingfei
author Yang, Shengyou
Dui, Guansuo
Liu, Bingfei
spellingShingle Yang, Shengyou
Dui, Guansuo
Liu, Bingfei
Journal of Intelligent Material Systems and Structures
Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
Mechanical Engineering
General Materials Science
author_sort yang, shengyou
spelling Yang, Shengyou Dui, Guansuo Liu, Bingfei 1045-389X 1530-8138 SAGE Publications Mechanical Engineering General Materials Science http://dx.doi.org/10.1177/1045389x12462651 <jats:p> Recent experimental tests showed that shape memory alloys have a strong dependence of stress–strain curve on the strain rate. This rate-dependent phenomenon is mainly due to the temperature variation of shape memory alloys caused by the latent heat release/absorption during the forward/reverse phase transformation. Since there is an increasing use of shape memory alloys for civil engineering like seismic application, the complex rate-dependent properties, such as the propagation stress and the damping capacity, should be carefully analyzed. This article studies the rate-dependent stress–strain curve, especially the damping capacity, of one-dimensional NiTi shape memory alloys by using a linear model and a nonlinear model taken the rate-independent driving force in the micromechanics-inspired constitutive model. Compared with the experimental data and previous work, both models use fewer material parameters and can easily describe the trend of damping capacity with respect to the strain rate. For their clear physical meaning and simple mathematical expression, both models are useful tools for the dynamic design and simulation of superelastic shape memory alloys in practice. </jats:p> Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys Journal of Intelligent Material Systems and Structures
doi_str_mv 10.1177/1045389x12462651
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series Journal of Intelligent Material Systems and Structures
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title Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_unstemmed Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_full Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_fullStr Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_full_unstemmed Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_short Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_sort modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
topic Mechanical Engineering
General Materials Science
url http://dx.doi.org/10.1177/1045389x12462651
publishDate 2013
physical 431-440
description <jats:p> Recent experimental tests showed that shape memory alloys have a strong dependence of stress–strain curve on the strain rate. This rate-dependent phenomenon is mainly due to the temperature variation of shape memory alloys caused by the latent heat release/absorption during the forward/reverse phase transformation. Since there is an increasing use of shape memory alloys for civil engineering like seismic application, the complex rate-dependent properties, such as the propagation stress and the damping capacity, should be carefully analyzed. This article studies the rate-dependent stress–strain curve, especially the damping capacity, of one-dimensional NiTi shape memory alloys by using a linear model and a nonlinear model taken the rate-independent driving force in the micromechanics-inspired constitutive model. Compared with the experimental data and previous work, both models use fewer material parameters and can easily describe the trend of damping capacity with respect to the strain rate. For their clear physical meaning and simple mathematical expression, both models are useful tools for the dynamic design and simulation of superelastic shape memory alloys in practice. </jats:p>
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author Yang, Shengyou, Dui, Guansuo, Liu, Bingfei
author_facet Yang, Shengyou, Dui, Guansuo, Liu, Bingfei, Yang, Shengyou, Dui, Guansuo, Liu, Bingfei
author_sort yang, shengyou
container_issue 4
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container_title Journal of Intelligent Material Systems and Structures
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description <jats:p> Recent experimental tests showed that shape memory alloys have a strong dependence of stress–strain curve on the strain rate. This rate-dependent phenomenon is mainly due to the temperature variation of shape memory alloys caused by the latent heat release/absorption during the forward/reverse phase transformation. Since there is an increasing use of shape memory alloys for civil engineering like seismic application, the complex rate-dependent properties, such as the propagation stress and the damping capacity, should be carefully analyzed. This article studies the rate-dependent stress–strain curve, especially the damping capacity, of one-dimensional NiTi shape memory alloys by using a linear model and a nonlinear model taken the rate-independent driving force in the micromechanics-inspired constitutive model. Compared with the experimental data and previous work, both models use fewer material parameters and can easily describe the trend of damping capacity with respect to the strain rate. For their clear physical meaning and simple mathematical expression, both models are useful tools for the dynamic design and simulation of superelastic shape memory alloys in practice. </jats:p>
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spelling Yang, Shengyou Dui, Guansuo Liu, Bingfei 1045-389X 1530-8138 SAGE Publications Mechanical Engineering General Materials Science http://dx.doi.org/10.1177/1045389x12462651 <jats:p> Recent experimental tests showed that shape memory alloys have a strong dependence of stress–strain curve on the strain rate. This rate-dependent phenomenon is mainly due to the temperature variation of shape memory alloys caused by the latent heat release/absorption during the forward/reverse phase transformation. Since there is an increasing use of shape memory alloys for civil engineering like seismic application, the complex rate-dependent properties, such as the propagation stress and the damping capacity, should be carefully analyzed. This article studies the rate-dependent stress–strain curve, especially the damping capacity, of one-dimensional NiTi shape memory alloys by using a linear model and a nonlinear model taken the rate-independent driving force in the micromechanics-inspired constitutive model. Compared with the experimental data and previous work, both models use fewer material parameters and can easily describe the trend of damping capacity with respect to the strain rate. For their clear physical meaning and simple mathematical expression, both models are useful tools for the dynamic design and simulation of superelastic shape memory alloys in practice. </jats:p> Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys Journal of Intelligent Material Systems and Structures
spellingShingle Yang, Shengyou, Dui, Guansuo, Liu, Bingfei, Journal of Intelligent Material Systems and Structures, Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys, Mechanical Engineering, General Materials Science
title Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_full Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_fullStr Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_full_unstemmed Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_short Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_sort modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
title_unstemmed Modeling of rate-dependent damping capacity of one-dimensional superelastic shape memory alloys
topic Mechanical Engineering, General Materials Science
url http://dx.doi.org/10.1177/1045389x12462651