Thermally modulated shape memory alloy friction pendulum (tmSMA‐FP) for substantial near‐fault earthquake structure protection

Summary Vibration control of structures under near‐fault earthquakes by employing a friction pendulum supplemented with thermally modulated shape memory alloy (SMA) springs as damper system is studied. Temperature modulation of the SMA spring during the earthquake effectively alters its hysteretic e...

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Published inStructural control and health monitoring Vol. 24; no. 11; pp. e2021 - n/a
Main Authors Gur, Sourav, Frantziskonis, George N., Mishra, Sudib K.
Format Journal Article
LanguageEnglish
Published Pavia John Wiley & Sons, Inc 01.11.2017
Subjects
Control systems
Earthquake damage
Earthquakes
Efficiency
Energy dissipation
Friction
friction pendulum
Ground motion
Hybrid systems
Hysteresis loops
Isolation systems
Modulation
near‐fault earthquakes
Nonlinear analysis
Seismic activity
shape memory alloy (SMA)
Shape memory alloys
Springs (elastic)
Structural damage
Temperature effects
thermo‐mechanical model
Vibration control
Online AccessGet full text
ISSN1545-2255
1545-2263
DOI10.1002/stc.2021

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Abstract Summary Vibration control of structures under near‐fault earthquakes by employing a friction pendulum supplemented with thermally modulated shape memory alloy (SMA) springs as damper system is studied. Temperature modulation of the SMA spring during the earthquake effectively alters its hysteretic energy dissipation capacity and thereby the control efficiency of the isolation system. The response of a structure with the isolation system is evaluated through nonlinear dynamic time‐history analysis under a set of recorded near‐fault ground motions. Through temperature modulation that effectively yields a large SMA hysteretic energy dissipation, the hybrid friction pendulum system with SMA temperature modulation shows enormous control efficiency. A parametric study reveals that under a wide range of conditions, the thermally modulated SMA friction pendulum isolation system shows improved control efficiency over conventional friction pendulum and SMA friction pendulum isolation systems. Further, the temperature‐tuned SMA hysteresis loops substantially suppress the high frequency components of earthquake motions, thus reducing the possibility of damage to the structure.
AbstractList Summary Vibration control of structures under near‐fault earthquakes by employing a friction pendulum supplemented with thermally modulated shape memory alloy (SMA) springs as damper system is studied. Temperature modulation of the SMA spring during the earthquake effectively alters its hysteretic energy dissipation capacity and thereby the control efficiency of the isolation system. The response of a structure with the isolation system is evaluated through nonlinear dynamic time‐history analysis under a set of recorded near‐fault ground motions. Through temperature modulation that effectively yields a large SMA hysteretic energy dissipation, the hybrid friction pendulum system with SMA temperature modulation shows enormous control efficiency. A parametric study reveals that under a wide range of conditions, the thermally modulated SMA friction pendulum isolation system shows improved control efficiency over conventional friction pendulum and SMA friction pendulum isolation systems. Further, the temperature‐tuned SMA hysteresis loops substantially suppress the high frequency components of earthquake motions, thus reducing the possibility of damage to the structure.
Summary Vibration control of structures under near-fault earthquakes by employing a friction pendulum supplemented with thermally modulated shape memory alloy (SMA) springs as damper system is studied. Temperature modulation of the SMA spring during the earthquake effectively alters its hysteretic energy dissipation capacity and thereby the control efficiency of the isolation system. The response of a structure with the isolation system is evaluated through nonlinear dynamic time-history analysis under a set of recorded near-fault ground motions. Through temperature modulation that effectively yields a large SMA hysteretic energy dissipation, the hybrid friction pendulum system with SMA temperature modulation shows enormous control efficiency. A parametric study reveals that under a wide range of conditions, the thermally modulated SMA friction pendulum isolation system shows improved control efficiency over conventional friction pendulum and SMA friction pendulum isolation systems. Further, the temperature-tuned SMA hysteresis loops substantially suppress the high frequency components of earthquake motions, thus reducing the possibility of damage to the structure.
Author Frantziskonis, George N.
Gur, Sourav
Mishra, Sudib K.
Author_xml – sequence: 1
  givenname: Sourav
  surname: Gur
  fullname: Gur, Sourav
  organization: University of Arizona Tucson
– sequence: 2
  givenname: George N.
  orcidid: 0000-0003-1672-3433
  surname: Frantziskonis
  fullname: Frantziskonis, George N.
  email: frantzis@email.arizona.edu
  organization: University of Arizona Tucson
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  givenname: Sudib K.
  surname: Mishra
  fullname: Mishra, Sudib K.
  organization: Indian Institute of Technology Kanpur
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Snippet Summary Vibration control of structures under near‐fault earthquakes by employing a friction pendulum supplemented with thermally modulated shape memory alloy...
Summary Vibration control of structures under near-fault earthquakes by employing a friction pendulum supplemented with thermally modulated shape memory alloy...
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SubjectTerms Control systems
Earthquake damage
Earthquakes
Efficiency
Energy dissipation
Friction
friction pendulum
Ground motion
Hybrid systems
Hysteresis loops
Isolation systems
Modulation
near‐fault earthquakes
Nonlinear analysis
Seismic activity
shape memory alloy (SMA)
Shape memory alloys
Springs (elastic)
Structural damage
Temperature effects
thermo‐mechanical model
Vibration control
Title Thermally modulated shape memory alloy friction pendulum (tmSMA‐FP) for substantial near‐fault earthquake structure protection
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fstc.2021
https://www.proquest.com/docview/1948868133
Volume 24
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