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Experimental-Numerical Assessment of Mechanical Behavior of Laboratory-Made Steel and NiTi Shape Memory Alloy Wire Ropes

The mechanical behaviors of laboratory-fabricated steel and superelastic shape memory alloy (SMA) wire ropes are assessed in this study through a comprehensive approach encompassing both experimental investigations and finite element (FE) numerical simulations. The assessment of steel wire ropes inv...

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Published in:	Buildings (Basel) 2024-06, Vol.14 (6), p.1567
Main Authors:	Narjabadifam, Peyman, Fazlalipour, Neda, Mollaei, Somayeh, Momeni, Mohammad, Watandoust, Ali Saman, Chavoshi, Mahdi, Babaeian Amini, Alireza, Karazmay, Farshad
Format:	Article
Language:	English
Subjects:	Cables Comparative analysis Computer simulation Cyclic loads Earthquake loads Earthquakes Energy dissipation experimental-numerical assessment helix angle Highway construction Iran Mechanical analysis mechanical behavior Mechanical properties Metal fatigue Nickel base alloys Numerical analysis quasi-static sinusoidal loading Seismic activity Seismic engineering Shake table tests shape memory alloy (SMA) Shape memory alloys Simulation Simulation methods Single wires Steel Steel wire steel wire ropes Strain Superelasticity Viscoelasticity Wire Wire rope
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container_title	Buildings (Basel)
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creator	Narjabadifam, Peyman Fazlalipour, Neda Mollaei, Somayeh Momeni, Mohammad Watandoust, Ali Saman Chavoshi, Mahdi Babaeian Amini, Alireza Karazmay, Farshad
description	The mechanical behaviors of laboratory-fabricated steel and superelastic shape memory alloy (SMA) wire ropes are assessed in this study through a comprehensive approach encompassing both experimental investigations and finite element (FE) numerical simulations. The assessment of steel wire ropes involves experimental scrutiny under sinusoidal cyclic loading and natural earthquake loading conditions. In parallel, SMA wire ropes’ behaviors are analyzed utilizing FE simulations employing the widely acknowledged ABAQUS software version 2020. The validation of all numerical simulations is undertaken against the experimentally observed behaviors. Moreover, full-scale steel wire ropes are subjected to shaking table tests to validate the simulations, facilitating a comparative analysis between the mechanical responses of SMA and steel wire ropes. The findings demonstrate that SMA wire ropes exhibit superelastic behavior akin to SMA wires, with marginal variations in overall response observed across distinct configurations, akin to steel wire ropes. Furthermore, augmenting the helix angle of SMA wire ropes results in reduced stress and increased strain when exposed to the El Centro earthquake scenario. Nevertheless, the mechanical response of SMA wire ropes closely mirrors that of a single wire.
doi_str_mv	10.3390/buildings14061567
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subjects	Cables Comparative analysis Computer simulation Cyclic loads Earthquake loads Earthquakes Energy dissipation experimental-numerical assessment helix angle Highway construction Iran Mechanical analysis mechanical behavior Mechanical properties Metal fatigue Nickel base alloys Numerical analysis quasi-static sinusoidal loading Seismic activity Seismic engineering Shake table tests shape memory alloy (SMA) Shape memory alloys Simulation Simulation methods Single wires Steel Steel wire steel wire ropes Strain Superelasticity Viscoelasticity Wire Wire rope
title	Experimental-Numerical Assessment of Mechanical Behavior of Laboratory-Made Steel and NiTi Shape Memory Alloy Wire Ropes
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