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《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:

2007年03期

Page:

1-6

Research Field:

Publishing date:

2007-09-20

Info

Title:

Deformation Characteristic of Concrete Beams Embedded Superelastic Shape Memory Alloy

Author(s):

OU Jin-ping¹; 2;  KUANG Ya-chuan¹; 3

1. School of Civil Engineering and Hydraulic, Dalian University of Technology, Dalian 116024, Liaoning, China; 2. School of Civil Engineering, Harbin Institute of Technology, Harbin 150090, Heilongjiang, China; 3. School of Civil Engineering and Architecture, Central South University, Changsha 410075, Hunan, China

Keywords:

smart concrete;  shape memory alloy;  superelasticity;  deformation characteristic;  self-restoring

PACS:

TU375.1

DOI:

-

Abstract:

Taking advantage of the superelasticity effect of shape memory alloy(SMA)and the characteristic of applying large forces on the resisting member in the transformation of SMA when restoring, smart concrete beam was developed by embedding superelastic SMA into the tensile zone of concrete beams during concrete casting. Deformation behavior and influence of factors on the deformation characteristic of SMA smart concrete beam were investigated experimentally. Self-restoring mechanism of SMA smart concrete beam embedded superelastic SMA was analyzed. Experimental results show that SMA significantly increases structural survivability and allows structure to recover from residual deformation by damaged earthquake and typhoon; the crack almost closes completely when unloading after generating a large deflection in the beams. Increasing the consumption of superelastic SMA can significantly improve the capacity of self-restoration of SMA concrete beams, but the steel main bars play a very negative role in reducing residual deformation.

References:

[1] 张 誉.混凝土结构基本原理[M].北京:中国建筑工业出版社,2000:2-3. ZHANG Yu.Basic Principle of Concrete Structure[M].Beijing:China Architecture & Building Press,2000:2-3.
[2]过镇海.钢筋混凝土原理[M].北京:清华大学出版社,1999:1-2. GUO Zhen-hai.Reinforced Concrete Principle[M].Beijing:Tsinghua University Press,1999:1-2.
[3]欧进萍.重大工程结构的累积损伤与安全性评定[C]//杨 卫,郑泉水,靳征谟.走向21世纪的中国力学--中国科协第9次“青年科学家论坛”报告文集.北京:清华大学出版社,1996:179-189. OU Jin-ping.Cumulation Damage and Security Assess of Momentous Project Structure[C]//YANG Wei,ZHENG Quan-shui,JIN Zheng-mo.China Mechanics Towards 21 Century:Report Corpus of China Association for Science and Technology 9th Youth Scientist Forum.Beijing:Tsinghua University Press,1996:179-189.
[4]YUJI S,YOSHIKAZU K,TOSSHIBUMI F,et al.Experimental Study on Enhancement of Self-restoration of Concrete Beams Using SMA Wire[C]//SPIE.Proceedings of SPIE.Bellingham:SPIE,2003:178-186.
[5]SUN Guo-jun,SUN Shuang-shuang,XU Xiao-dong,et al.A Study on the Thermomechanical Deformation of Elastic Beam with Embedded Shape Memory Alloy Wires[J].Materials and Design,2000,21(6):525-528.
[6]CHOI S,LEE J J.The Shape Control of a Composite Beam with Embedded Shape Memory Alloy Wire Actuators[J].Smart Materials and Structures,1998,7(6):759-770.
[7]ARUP K M,IHOSVANY N.Smart Prestressing with Shape-memory Alloy[J].Journal of Engineering Mechanics,1998,124(10):1 121-1 128.
[8]LI Hui,LIU Zhi-qiang,OU Jin-ping.Study on Damage Emergency Repair Performance of a Simple Beam Embedded with Shape Memory Alloys[J].Advances in Structural Engineering,2004,7(6):495-502.
[9]WILDE K,GARDONI P,FUJINO Y.Base Isolation System with Shape Memory Alloy Device for Highway Bridges[J].Engineering Structures,2000,22(1):222-229.
[10]DESROCHES R,DELEMONT M.Seismic Retrofit of Simply Supported Bridges Using Shape Memory Alloys[J].Engineering Structures,2002,24(5):325-332.

Memo

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Common functions

Last Update: 2007-09-20