[1] 吕志林,姜旭,强旭红,等.正交异性钢桥面板横隔板局部模型疲劳试验研究[J].结构工程师,2021,37(6):163-171.
Lü Zhilin,Jiang Xu,Qiang Xuhong,et al.Fatigue experimental study of local diaphragm model in orthotropic steel bridge decks[J].Structural Engineers,2021,37(6):163-171.(in Chinese)
[2] 李建中,吕西林,李翔,等.汶川地震中钢筋混凝土框架结构的震害[J].结构工程师,2008,24(3):9-11.
Li Jianzhong,Lü Xilin,Li Xiang,et al.Seismic damage of reinforced concrete frame structures in Wenchuan earthquake[J].Structural Engineers,2008,24(3):9-11.(in Chinese)
[3] Janke L,Czaderski C,Motavalli M,et al.Applications of shape memory alloys in civil engineering structures—overview,limits and new ideas[J].Materials and Structures,2005,38(5):578-592.
[4] Lee W J,Weber B,Leinenbach C.Recovery stress formation in a restrained Fe-Mn-Si-based shape memory alloy used for prestressing or mechanical joining[J].Construction and Building Materials,2015,95(1):600-610.
[5] Izadi M R,Ghafoori E,Motavalli M,et al.Iron-based shape memory alloy for the fatigue strengthening of cracked steel plates:effects of re-activations and loading frequencies[J].Engineering Structures,2018,176:953-967.
[6] Mohd J J,Leary M,Subic A,et al.A review of shape memory alloy research,applications and opportunities[J].Materials and Design,2014,56:1078-1113.
[7] Cladera A,Weber B,Leinenbach C,et al.Iron-based shape memory alloys for civil engineering structures:an overview[J].Construction and Building Materials,2014,63(30):281-293.
[8] 任红梅,彭功生.SMA在结构加固修复中的应用研究[J].结构工程师,2018,34(6):175-180.
Ren Hongmei,Peng Gongsheng.Research on application of SMA in structure strengthening and rehabilitation[J].Structural Engineers,2018,34(6):175-180.(in Chinese)
[9] 方成,王伟,陈以一.基于超弹性形状记忆合金的钢结构抗震研究进展[J].建筑结构学报,2019,40(7):1-12.
Fang Cheng,Wang Wei,Chen Yiyi.State-of-the-art for application of superelastic shape memory alloy in seismic resistant steel structures[J].Journal of Building Structures,2019,40(7):1-12.(in Chinese)
[10] 刘林林,林成新,孙德平,等.Fe-Mn-Si形状记忆合金的应用研究现状及展望[J].天津理工大学学报,2010(2):42-47.
Liu Linlin,Lin Chengxin,Sun Deping,et al.Current application studies and prospect of Fe-Mn-Si shape memory alloy[J].Journal of Tianjin University of Technology,2010(2):42-47.(in Chinese)
[11] 邹芹,党赏,李艳国,等.Fe-基形状记忆合金的研究进展[J].材料导报,2019,23:3955-3962.
Zou Qin,Dang Shang,Li Yanguo,et al.Research progress of Iron-based shape memory alloys:a review[J].Materials Reports,2019,23:3955-3962(in Chinese).
[12] 袁志山,马嘉丽,冯昭伟,等.温度循环对镍钛形状记忆合金超弹性和相变行为的影响[J].热加工工艺,2018,20(47):202-205.
Yuan Zhishan,Ma Jiali,Feng Zhaowei,et al.Effect of temperature cycling on superelasticity and phase transformation behavior of NiTi shape memory alloy[J].Hot Working Technology,2018,20(47):202-205.(in Chinese)
[13] 刘林林. Fe-Mn-Si形状记忆合金约束态的应力诱发马氏体相变[M].北京:科学出版社,2018:18-32.
Liu Linlin.The constrain induced martensitic transformation of Fe-Mn-Si memory alloy[M].Beijing:Science Press,2018:18-32. (in Chinese)
[14] Montoya-Coronado L A,Ruiz-Pinilla J G,Ribas C,et al.Experimental study on shear strengthening of shear critical RC beams using iron-based shape memory alloy strips[J].Engineering Structures,2019,200(Dec.1):109680.
[15] Sergio D A O,Vanderson M D,Marcelo A S,et al.A phenomenological description of shpae memory alloy transformation induced plasticity[J].Meccanica,2018,53(10):2503-2523.
[16] Sawaguchi T,Maruyama T,Otsuka H,et al.Design concept and applications of Fe-Mn-Si-Based alloys—from shape-memory to seismic response control[J].Materials Transactions,2016,57(3):283-293.
[17] Shahverdi M,Michels J,Czaderski C,et al.Iron-based shape memory alloy strips for strengthening RC members:material behavior and characterization[J].Construction and Building Materials,2018,173(10):586-599.
[18] 强旭红,武亚鹏,姜旭.铁基形状记忆合金力学性能和激活回复性能研究[J].同济大学学报:自然科学版,2023,51(5):718-727.
Qiang Xuhong,Wu Yapeng, Jiang Xu.Experimental investigation on mechanical properties and activation-recovery performance of Febased shape memory alloys[J]. Journal of Tongji University(Natural Science),2023,51(5):718-727.
[19] Ghafoori E,Neuenschwander M,Shahverdi M,et al.Elevated temperature behavior of an iron-based shape memory alloy used for prestressed strengthening of civil structures[J].Construction and Building Materials,2019,211(JUN.30):437-452.
[20] 徐祖耀,江伯鸿.形状记忆材料[M].上海:上海交通大学出版社,2000:204-220.
Xu Zuyao,Jiang Bohong.Shape memory materials[M].Shanghai:Shanhai Jiaotong University Press,2000:204-220.(in Chinese)
[21] Li Kang,Dong Zhizhong,Liu Yongchang.A newly developed Fe-based shape memory alloy suitable for smart civil engineering[J].Smart Materials and Structures,2013,22(4):045002(1-7).
[22] 阎石,杜长虹,肖正峰,等.铁基形状记忆合金混凝土框架节点可恢复变形性能分析[J].地震研究,2020,43(3):491-499.
Yan Shi,Du Changhong,Xiao Zhengfeng,et al.Resilient performances analysis of Fe-SMA reinforced frame joints[J].Journal of Seismological Research,2020,43(3):491-499.(in Chinese)
[23] Sato A,Chishima E,Soma K,et al.Shape memory effect in γ^→_←ε transformation in Fe-30Mn-1Si alloy single crystals[J].Acta Metallurgica,1982,30(6):1177-1183.
[24] Sato A,Chishima E,Yamaji Y,et al.Orientation and composition dependencies of shape memory effect in Fe-Mn-Si alloys[J].Acta Metallurgica,1984,32(4):539-547.
[25] Lin H C,Lin K M,Lin C S,et al.The Corrosion behavior of Fe-based shape memory alloys[J].Corrosion Science,2002,44(9):2013-2026.
[26] Maji B C,Das C M,Krishnan M,et al.The corrosion behaviour of Fe-15Mn-7Si-9Cr-5Ni shape memory alloy[J].Corrosion Science,2006,48(4):937-949.
[27] 杨军. Fe-Mn-Si-Cr-Ni系形状记忆合金组织和性能的研究[D].成都:四川大学,2006.
Yang Jun.Study of structures and performance of Fe-Mn-Si-Cr-Ni-based shape memory alloys[D].Chengdu:Sichuan University,2006(in Chinese).
[28] Wan J F,Chen S P,Hsu T Y,et al.Modulus softening during the γ→ɛ martensitic transformation in Fe-25Mn-6Si-5Cr-0.14N alloys[J].Materials Science and Engineering A,2006,438(Nov):887-890.
[29] Hosseini A,Ghafoori E,Al-Mahaidi R,et al.Strengthening of a 19th-century roadway metallic bridge using nonprestressed bonded and prestressed unbonded CFRP plates[J].Construction and Building Materials,2019,209(10):240-259.
[30] Ghafoori E,Hosseini A,Al-Mahaidi R,et al.Prestressed CFRP-strengthening and long-term wireless monitoring of an old roadway metallic bridge[J].Engineering Structures,2018,176:585-605.
[31] Hosseini E,Ghafoori E,Leinenbach C,et al.Stress recovery and cyclic behaviour of an Fe-Mn-Si shape memory alloy after multiple thermal activation[J].Smart Materials and Structures,2018,27(2):025009(1-11).
[32] Hong K,Lee S,Yeon Y,et al.Flexural response of reinforced concrete beams strengthened with near-surface-mounted Fe-based shape-memory slloy strips[J].International Journal of Concrete Structures and Materials,2018,12(1):45.
[33] Rojob H,El-Hacha R.Fatigue performance of RC beams strengthened with self-prestressed iron-based shape memory alloys[J].Engineering Structures,2018,168(1):35-43.
[34] Rojob H,El-Hacha R.Performance of RC beams strengthened with self-prestressed Fe-SMA bars exposed to freeze-thaw cycles and sustained load[J].Engineering Structures,2018,169(15):107-118.
[35] El-Hacha R,Rojob H.Flexural strengthening of large-scale reinforced concrete beams using near-surface-mounted self-prestressed iron-based shape-memory alloy strips[J].Pci Journal,2018,63(6):55-65.
[36] Ghafoori E,Hosseini E,Leinenbach C,et al.Fatigue behavior of a Fe-Mn-Si shape memory alloy used for prestressed strengthening[J].Materials and Design,2017,133:349-362.
[37] Hong K,Yeon Y,Shim W,et al.Recovery behavior of Fe-based shape memory alloys under different restraints[J].Applied Sciences,2020,10(10):3441.
[38] Dong Zhizhong,Klotz U E,Leinenbach C,et al.A novel Fe-Mn-Si shape memory alloy with improved shape recovery properties by VC precipitation[J].Advanced Engineering Materials,2009,11(No.1-2):40-44.
[39] Koster M,Lee W J,Schwarzenberger M,et al.Cyclic deformation and structural fatigue behavior of an FE-Mn-Si shape memory alloy[J].Materials Science and Engineering A,2015,637(J18):29-39.
[40] Michels J,Shahverdi M,Czadershi C,et al.Mechanical performance of Iron-based shape-memory alloy ribbed bars for concrete prestressing[J].ACI Materials Journal,2018,115(6):877-886.
[41] Schranz B,Czaderski C,Shahverdi M,et al.Ribbed iron-based shape memory alloy bars for pre-stressed strengthening applications[C]//IABSE conference,2019.
[42] Leinenbach C,Lee W J,Lis A,et al.Creep and stress relaxation of a FeMnSi-based shape memory alloy at low temperatures[J].Materials Science and Engineering,A Structural Materials:Properties,Misrostructure and Processing,2016,677:106-115.
[43] Soroushian P,Ostowari K,Nossoni A,et al.Repair and strengthening of concrete structures through application of corrective posttensioning forces with shape memory alloys[J].Transportation Research Record Journal of the Transportation Research Board,2001,1770:20-26.
[44] Maruyama T,Kurita T,Kozaki S,et al.Innovation in producing crane rail fish plate using Fe-Mn-Si-Cr based shape memory alloy[J].Materials Science and Technology,2008,24(8):908-912.
[45] Shahverdi M,Czaderski C,Annen P,et al.Strengthening of RC beams by Iron-based shape memory alloy bars embedded in a shotcrete layer[J].Engineering Structures,2016,117:263-273.
[46] Czaderski C,Shahverdi M,BrÖnnimann R,et al.Feasibility of Iron-based shape memory alloy strips for prestressed strengthening of concrete structures[J].Construction and Building Materials,2014,56:94-105.
[47] Czaderski C,Hahnebach B,Motavallia M.RC beam with variable stiffness and strength[J].Construction and Building Materials,2006,20(9):824-833.
[48] Wang W,Chan T M,Shao H L.Seismic performance of beam-column joints with SMA tendons strengthened by steel angles[J].Journal of Constructional Steel Research,2015,109(Jun.):61-71.
[49] Julien M,Moslem S,Czaderski C.Flexural strengthening of structural concrete with iron-based shape memory alloy strips[J].Structural Concrete Journal of the Fib,2018,19:876-891.
[50] Izadi M R,Ghafoori E,Shahverdi M,et al.Development of an iron-based shape memory alloy (Fe-SMA) strengthening system for steel plates[J].Engineering Structures,2018,174:433-446.
[51] Izadi M R,Ghafoori E,Hosseini A,et al.Feasibility of iron-based shape memory alloy strips for prestressed strengthening of steel plates[C]// The fourth International Conference on Smart Monitoring,Assessment and Rehabilitation of Civil Structures SMAR,Zurich,Switzerland,2017:13-15.
[52] Izadi M R,Hosseini A,Michels J,et al.Thermally activated iron-based shape memory alloy for strengthening metallic girders[J].Thin-Walled Structures,2019,141:389-401.
[53] Hosseini A,Ghafoori E,Motavalli M,et al.Flat prestressed unbonded retrofit system for strengthening of existing metallic I-Girders[J].Composites,2018,155B(D.):156-172.
[54] Fritsch E,Izadi M R,Ghafoori E.Development of nail-anchor strengthening system with iron-based shape memory alloy (Fe-SMA) strips[J].Construction and Building Materials,2019,229:117042(1-14).
[55] Wang W,Hosseini A,Ghafoori E.Experimental study on Fe-SMA-to-steel adhesively bonded interfaces using DIC[J].Engineering Fracture Mechanics,2021,244(4):107553.
[56] Wang W D,Li L Z,Hosseini A,et al.Novel fatigue strengthening solution for metallic structures using adhesively bonded Fe-SMA strips:a proof of concept study[J].International Journal of Fatigue,2021,148:106237(1-13).
[57] Izadi M R,Motavalli M,Ghafoori E.Iron-based shape memory alloy (Fe-SMA) for fatigue strengthening of cracked steel bridge connections[J].Construction and Building Materials,2019,227:116800(1-17).
[58] Qiang X H,Wu Y P,Wang Y H,et al.Research Progress and Applications of Fe-Mn-Si-Based Shape Memory Alloys on Reinforcing Steel and Concrete Bridges[J]. Applied Sciences, 2023, 13(6): 3404.
[59] Qiang X H,Wu Y P,Wang Y H, et al.Novel crack repair method of steel bridge diaphragm employing Fe-SMA[J].Engineering Structures, 2023, 292: 116548.
[60] Qiang X H,Wang Y H,Wu Y P, et al.Experimental and numerical study on cracked steel bridge diaphragm reinforced with bonding Fe-SMA plate[J]. Thin-Walled Structures,2023,191:111075.
[61] Lv Z L,Jiang X,Qiang X H,et al.Proactive strengthening of U-rib butt-welded joints in steel bridge decks using adhesively bonded Fe-SMA strips[J]. Engineering Structures, 2024, 301:117316.
[62] Barros J A O,Ferreira D R S M,Fortes A S.Assessing the effectiveness of embedding CFRP laminates in the near surface for structural strengthening[J].Construction and Building Materials,2006,20(7):478-491.
[63] El-hacha R,Soudki K.Prestressed near-surface mounted fibre reinforced polymer reinforcement for concrete structures—a review[J].Canadian Journal of Civil Engineering,2013,40(11):1127-1139.
[64] Shahverdi M,Czaderski C,Motavalli M.Iron-based shape memory alloys for prestressed near-surface mounted strengthening of reinforced concrete beams[J].Construction and Building Materials,2016,112:28-38.
[65] Cladera A,Montoya-coronado L A,Ruiz-pinilla J G,et al.Shear strengthening of slender reinforced concrete T-shaped beams using iron-based shape memory alloy strips[J].Engineering Structures,2020,221:111018.
[66] Czaderski C,Shahverdi M,Michels J.Iron based shape memory alloys as shear reinforcement for bridge girders[J].Construction and Building Materials,2021,274:121793.