双金属抗震减灾复合材料设计与抗震特性分析
摘要
提出了Fe/Zn双金属抗震减灾复合材料的设计构想和复合理论基础。为验证Fe/Zn双金属复合材料具有抗震减灾作用,利用有限元软件ANSYS对材料的性能作数值仿真,分析了Fe/Zn复合材料试件在地震荷载下的动力特性。复合材料中,Fe保证构件刚度、恢复力及不发生过大变形;Zn的塑性变形改变材料的自振周期,同时吸收地震能量。
The mechanic model of developing Fe/Zn earthquake resistant composite is put forward.A numerical simulation of the material characteristics by finite element software ANSYS to check the earthqueke-resistant capability of Fe/Zn composite was made.The earthqueke-resistant capabilities of Fe/Zn composite under the earthquake action were analyzed.In the composite,Fe is contributing to ensure component rigidity,resilience and avoiding the big distortion and the plastic distortion of Zn can alter the composite vibration cycle and absorb the earthquake energy.
The mechanic model of developing Fe/Zn earthquake resistant composite is put forward.A numerical simulation of the material characteristics by finite element software ANSYS to check the earthqueke-resistant capability of Fe/Zn composite was made.The earthqueke-resistant capabilities of Fe/Zn composite under the earthquake action were analyzed.In the composite,Fe is contributing to ensure component rigidity,resilience and avoiding the big distortion and the plastic distortion of Zn can alter the composite vibration cycle and absorb the earthquake energy.
引文
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[2]Prelim inary report of the seismological and engineering aspects of 1994 Northridge earthquake[R].EERC,1994.
[3]周福霖.工程结构减震控制[M].北京:地震出版社,1997.
[4]Nobuyuk iM,Tsutomu S.The 1994 Hokkaido Toho-Ok i earthquake sequence:the complex activity of intra-slab and plate-boundary earthquakes[J].Physics of the Earth and P lanetary Interiors,2000,121(1-2):3~58.
[5]Anon.How flexib ility of bu ild ings affects their earthquake response[J].Ind ian Concrete Journal,2003,77(3):967~968.
[6]Booth E D.Earthquake engineering in the 1990 s:Ach ievem ents,concerns and future d irections[J].Proceed ings of the Institution of C ivil Engi-neers,1998,128(2):154~166.
[7]Kemp A R.D esign ing for ductility[J].Structural Engineer,2003,81(6):13~14.
[8]Nelson L,John W,G raham H.Ductility reduction factor in the seism ic design of bu ild ings[J].Earthquake Engineering&Structures Dynam ics,1998,27(7):749~769.
[9]高慧婷,刘勇兵,包晓军等.开发Fe/Zn抗震复合材料的构想[J].材料科学与工艺,2004,12(2):220~224.
[10]包晓军,刘勇兵,曹占义,等.抗震复合材料的单向拉伸与循环变形行为[J].材料科学与工艺,2005,13(5):163~166.
[11]罗伯D.计算材料学[M].项金钟,吴兴惠译.北京:化学工业出版社,2002.
[12]普瑞斯特雷M J N,塞勃勒F,卡尔维G M.桥梁抗震设计与加固[M].北京:人民交通出版社,1997.
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