Download this article
Download this article For screen
For printing
Recent Issues
Volume 11, Issue 4
Volume 11, Issue 3
Volume 11, Issue 2
Volume 11, Issue 1
Volume 10, Issue 4
Volume 10, Issue 3
Volume 10, Issue 2
Volume 10, Issue 1
Volume 9, Issue 4
Volume 9, Issue 3
Volume 9, Issue 2
Volume 9, Issue 1
Volume 8, Issue 4
Volume 8, Issue 3
Volume 8, Issue 2
Volume 8, Issue 1
Volume 7, Issue 4
Volume 7, Issue 3
Volume 7, Issue 2
Volume 7, Issue 1
Volume 6, Issue 4
Volume 6, Issue 3
Volume 6, Issue 2
Volume 6, Issue 1
Volume 5, Issue 3-4
Volume 5, Issue 2
Volume 5, Issue 1
Volume 4, Issue 3-4
Volume 4, Issue 2
Volume 4, Issue 1
Volume 3, Issue 4
Volume 3, Issue 3
Volume 3, Issue 2
Volume 3, Issue 1
Volume 2, Issue 2
Volume 2, Issue 1
Volume 1, Issue 2
Volume 1, Issue 1
The Journal
About the Journal
Editorial Board
Submission Guidelines
Submission Form
Policies for Authors
Ethics Statement
ISSN: 2325-3444 (e-only)
ISSN: 2326-7186 (print)
Author Index
To Appear
Other MSP Journals
This article is available for purchase or by subscription. See below.
Computational analysis of one-dimensional multiple-memory shape memory alloys under thermomechanical loading

Amin Alipour and Mahmoud Kadkhodaei

Vol. 10 (2022), No. 1, 51–74

The novel idea of embedding multiple memory by locally augmentation of transformation properties have enhanced the functionality of shape memory alloys with respect to traditional SMAs posing only a single set of transformation properties. However, it is necessary to model the behavior of such kind of multiple-memory SMAs in order to study their response, when used in smart structures. A computational method based on finite element analysis is presented in this paper to simulate the multiple-memory behavior. This method can be applied in investigation of various designed 1D multiple-memory structures under general thermomechanical loadings and boundary conditions. To evaluate the model, a series of case studies under constant temperature, constant stress, and constant strain are carried out using the numerical approach. To verify the model, first, 3 multiple stress plateau wires are modeled using the numerical technique, and the FE results are compared with existing experimental data, showing an acceptable agreement. Then, the model is applied in simulating a functionally graded SMA, and the results are closely validated with the experimental ones. At last, a proposed multiple-memory actuator is studied and its actuation response is explained in detail under thermomechanical loadings.

PDF Access Denied

We have not been able to recognize your IP address as that of a subscriber to this journal.
Online access to the content of recent issues is by subscription only.

Please contact your institution's librarian suggesting a subscription, for example by using our journal-recom­mendation form. Or, visit our subscription page for instructions on purchasing a subscription.

You may also contact us at
or by using our contact form.

shape memory alloy, multiple-memory, thermomechanical
Mathematical Subject Classification
Primary: 74Sxx
Received: 1 September 2021
Revised: 7 November 2021
Accepted: 27 December 2021
Published: 14 September 2022

Communicated by Emilio Barchiesi
Amin Alipour
Department of Mechanical Engineering
Isfahan University of Technology
Department of Mechanical Engineering
Isfahan University of Technology
Isfahan 84156-83111
Mahmoud Kadkhodaei
Department of Mechanical Engineering
Isfahan University of Technology
Department of Mechanical Engineering
Isfahan University of Technology
Isfahan 84156-83111