Energy absorption of shape memory structures

This project looks at the energy absorption ability of a Nickel-Titanium Shape Memory Alloy in the form of a circular thin-wall tube. Cyclic compression tests were conducted on the Ni-Ti specimen, where the specimen strain is incremented after every complete cycle of loading and unloading. The energ...

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Bibliographic Details
Main Author: Yong, Wei Hong
Other Authors: Liu Yong
Format: Final Year Project (FYP)
Language:English
Published: 2012
Subjects:
Online Access:http://hdl.handle.net/10356/50354
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author Yong, Wei Hong
author2 Liu Yong
author_facet Liu Yong
Yong, Wei Hong
author_sort Yong, Wei Hong
collection NTU
description This project looks at the energy absorption ability of a Nickel-Titanium Shape Memory Alloy in the form of a circular thin-wall tube. Cyclic compression tests were conducted on the Ni-Ti specimen, where the specimen strain is incremented after every complete cycle of loading and unloading. The energy absorption of the specimen was determined by measuring the Force and Displacements parameters of the specimen in the form of Force Vs Displacement graphs. The energy absorbed was determined from the area under the curve of these graphs. The Ni-Ti specimen in the as-received state is in the Austenite phase at room temperature. This was verified by Differential Scanning Calorimetry tests that were conducted on the specimen. Axial compression and Lateral compression of the Ni-Ti specimen were conducted using different arrangements of the Ni-Ti specimen. A total of 6 sets of compression test were conducted and the energy absorption abilities of the Ni-Ti specimen were compared to see which form of loading gives better energy absorption. The results show that for all 3 sets of arrangements tested, axial loading gives better energy absorption capabilities as compared to lateral loading. The specimens under axial loading were able to undergo a full recovery upon unloading for all 3 sets of arrangement with little or almost negligible residual strain. This is in contrast with the specimens under lateral loading, where they were unable to obtain a full recovery upon unloading for all 3 sets of arrangement, and they leave behind significant residual strain or failure of the specimen itself.
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spelling ntu-10356/503542023-03-04T18:24:29Z Energy absorption of shape memory structures Yong, Wei Hong Liu Yong Lu Guoxing School of Mechanical and Aerospace Engineering DRNTU::Engineering::Mechanical engineering This project looks at the energy absorption ability of a Nickel-Titanium Shape Memory Alloy in the form of a circular thin-wall tube. Cyclic compression tests were conducted on the Ni-Ti specimen, where the specimen strain is incremented after every complete cycle of loading and unloading. The energy absorption of the specimen was determined by measuring the Force and Displacements parameters of the specimen in the form of Force Vs Displacement graphs. The energy absorbed was determined from the area under the curve of these graphs. The Ni-Ti specimen in the as-received state is in the Austenite phase at room temperature. This was verified by Differential Scanning Calorimetry tests that were conducted on the specimen. Axial compression and Lateral compression of the Ni-Ti specimen were conducted using different arrangements of the Ni-Ti specimen. A total of 6 sets of compression test were conducted and the energy absorption abilities of the Ni-Ti specimen were compared to see which form of loading gives better energy absorption. The results show that for all 3 sets of arrangements tested, axial loading gives better energy absorption capabilities as compared to lateral loading. The specimens under axial loading were able to undergo a full recovery upon unloading for all 3 sets of arrangement with little or almost negligible residual strain. This is in contrast with the specimens under lateral loading, where they were unable to obtain a full recovery upon unloading for all 3 sets of arrangement, and they leave behind significant residual strain or failure of the specimen itself. Bachelor of Engineering (Mechanical Engineering) 2012-06-01T04:06:57Z 2012-06-01T04:06:57Z 2012 2012 Final Year Project (FYP) http://hdl.handle.net/10356/50354 en Nanyang Technological University 104 p. application/pdf
spellingShingle DRNTU::Engineering::Mechanical engineering
Yong, Wei Hong
Energy absorption of shape memory structures
title Energy absorption of shape memory structures
title_full Energy absorption of shape memory structures
title_fullStr Energy absorption of shape memory structures
title_full_unstemmed Energy absorption of shape memory structures
title_short Energy absorption of shape memory structures
title_sort energy absorption of shape memory structures
topic DRNTU::Engineering::Mechanical engineering
url http://hdl.handle.net/10356/50354
work_keys_str_mv AT yongweihong energyabsorptionofshapememorystructures