Superelastic damping of TiNi alloy wire under heavy mechanical shock in structural engineering 被引量：2

Superelastic damping of TiNi alloy wire under heavy mechanical shock in structural engineering

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摘要 Based on superelastic damping application in structural engineering, the damping characteristics of commercial Ti-50.8Ni(mole fraction, %) alloy have been systematically studied by adjusting frequency of mechanical shock, temperature, stress, strain and number of cycling. The results show that at extremely low frequency mechanical shock at room temperature, the superelastic damping capacity increases with controlled strain, and such capacity of each cycle is greater than 50%. When the frequency of mechanical shock is 0.10.3 Hz, the superelastic damping capacity above room temperature is relatively large at high strain; when the temperature approaches to M_d, the damping begins at low stress. For specimen cycled under 0.5 Hz, above 6% strain mechanical shock at relatively high temperature, further large-strain cycling exhibits more than 35% damping capacity. The superelastic damping of trained specimen is relatively stable at 2050 ℃ and 0.10.5 Hz frequency mechanical shock. Based on superelastic damping application in structural engineering, the damping characteristics of commercial Ti-50.8Ni(mole fraction, %) alloy have been systematically studied by adjusting frequency of mechanical shock, temperature, stress, strain and number of cycling. The results show that at extremely low frequency mechanical shock at room temperature, the superelastic damping capacity increases with controlled strain, and such capacity of each cycle is greater than 50%. When the frequency of mechanical shock is 0.10.3 Hz, the superelastic damping capacity above room temperature is relatively large at high strain; when the temperature approaches to M_d, the damping begins at low stress. For specimen cycled under 0.5 Hz, above 6% strain mechanical shock at relatively high temperature, further large-strain cycling exhibits more than 35% damping capacity. The superelastic damping of trained specimen is relatively stable at 2050 ℃ and 0.10.5 Hz frequency mechanical shock.

作者陈庆福田文彦左晓宝倪立峰

机构地区 School of Materials and Chemical Engineering School of Civil Structural Engineering

出处《中国有色金属学会会刊：英文版》 CSCD 2004年第2期278-283,共6页 Transactions of Nonferrous Metals Society of China

基金 Projects(2 0 0 0 10 10 5 5,2 0 0 110 10 62 )supportedbytheNaturalScienceFoundationofLiaoningProvince,China

关键词 TINI合金结构工程振动超弹性阻尼机械工程高阻尼合金 NiTi alloy superelastic damping low frequency mechanical shock structural engineering

分类号 TG139 [一般工业技术—材料科学与工程] TG21 [金属学及工艺—铸造]

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参考文献13

1[1]Dolce M, Cardone D, Marnetto R. Implementation and testing of passive control devices based on shape memory alloys[J]. Earthquake Engineering and Structural Dynamics, 2000, 29:945-968.
2[2]van Humbeeck J, Delaey L. Role of interfaces on materials damping[A]. Roth B R, Misa M S. Proc of International Conference on Martensitic Transformations [C]. Toronto, ASM-USA, 1985. 59-64
3[3]Hodgson D, Kramer G. High damping superelastic collects for high speed drilling[A]. Duerig T, Wayman C M. SMST-94 Proc 1st Intl Conf on Shape Memory and Superelastic Technologies[C]. Califronia, USA, 1994. 371- 376.
4[4]Chiodo J D, Anson A W, Billett E H, et al. Eco-design for active reassembly using smart materials[A].Pelton Alan, Hodgson Dared, Russell Scott, et al.SMST-97 Proc 2nd Intl Conf on Shape Memory and Superelastic Technologies [C]. California, USA,1997. 269-274.
5[5]van Humbeeck J. Non-medical applications of SMAs [J]. Mater Sci and Eng, 1999, A273 -275:134 -148.
6[6]Ma R Z, Jiang M H, Xu Z Y. Introduction to Functional Materials [B]. Beijing: Metallurgical Industry Press, 1999. 550-562.
7[7]Hodgson D E. Damping application of shape memory alloys[J]. Materials Science Forum, 2002, 394 - 395:69 - 74.
8[8]Dolce M, Cardone D. Mechanical behavior of shape memory alloys for seismic applications 2. Austenite NiTi wires subjected to tension[J]. International Journal of Mechanical Sciences, 2001, 43 : 2657 - 2677.
9[9]van Humbeeck J, Stoiber J, Delaey L, et al. High damping capacity of shape memory alloys [ J ].Zeitschrift fuer Metallkunde, 1995, 86(3): 176 -183.
10[10]van Humbeeck J. Damping properties of shape memory alloys during phase transformation[J]. Journal de Physique IV, 1996, 6(8) : 371 - 379.

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中国有色金属学会会刊：英文版

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Superelastic damping of TiNi alloy wire under heavy mechanical shock in structural engineering 被引量：2

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