Research Advances in Fatigue Repair and Life Prolongation of Steel Structures
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摘要: 承受交变荷载作用的钢结构构件在发生疲劳破坏时往往没有明显的征兆,极易造成巨大的经济损失和重大人员伤亡。因此,如何有效地提升钢材及钢结构构件的疲劳性能、延长其疲劳寿命,一直受到国内外学者的高度重视。在全面回顾国内外钢结构疲劳修复与延寿技术现状和进展的基础上,重点介绍了冷喷涂技术及其应用于钢结构疲劳修复与延寿的研究现状和最新进展,认为选择合适的冷喷涂工艺参数和冷喷涂粉末在钢构件表面制备性能优异的涂层可以有效地提高钢结构构件的疲劳性能。在总结现有成果的基础上,并结合在冷喷涂提升钢材疲劳性能方面的研究成果和经验,指出冷喷涂技术在应用于钢结构疲劳修复与延寿方面有较大的应用潜力,但当前冷喷涂层和钢基体的结合机理、二者的协同受力与变形行为以及疲劳断裂机制等相关理论亟待完善,挖掘适合于钢结构工程的冷喷涂技术的应用场景和技术体系是该技术在钢结构疲劳修复与延寿领域的主要发展方向。Abstract: Steel structural components that are subjected to alternating loads often have no obvious signs of fatigue failure, which can easily cause huge economic losses and heavy casualties. Therefore, how to effectively improve the fatigue performance of steel and steel structural components and prolong their fatigue life has always been highly valued by scholars at home and abroad.Based on a comprehensive review of the current status and recent advances in fatigue repair and life prolongation techniques for steel structures at home and abroad, the paper focused on the cold spraying technique and its application in fatigue repair and life prolongation of steel structures. The process parameters and cold spraying powder coatings with excellent performance on the surface of steel components can effectively improve the fatigue performance of steel structural components.On the basis of summarizing the existing results, combined with the research results and experience in improving the fatigue performance of steel by cold spraying, it was pointed out that cold spraying technique showed a great application potential in the fatigue repair and life prolongation of steel structures. The combination mechanism of the spray coating and the steel substrate, the cooperative force and deformation behavior of the two, and the fatigue fracture mechanism and other related theories needed to be improved. Exploring the application scenarios and technical system of cold spraying technique suitable for steel structure engineering should be the main development direction in the fields of fatigue repair and life prolongation.
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Key words:
- steel structures /
- fatigue failure /
- fatigue repair /
- fatigue life prolonging /
- cold spraying
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[1] 雷宏刚,付强,刘晓娟.中国钢结构疲劳研究领域的30年进展[J].建筑结构学报,2010,31(增刊1):84-91. [2] 徐灏著.疲劳强度[M].北京:高等教育出版社,1988. [3] 张威,魏宏刚.焊接吊车梁疲劳裂缝及加固试验的研究[J].包钢科技,2013,39(3):66-68. [4] 姚悦,傅中秋,徐捷,等.顶板与U肋焊缝水平裂纹钻孔止裂参数研究[J].工业建筑,2018,48(10):40-45. [5] 刘天笳,吉伯海,傅中秋,等.钢桥疲劳裂纹钻孔止裂技术多孔布置方法研究[J].合肥工业大学学报(自然科学版),2016,39(10):1376-1380. [6] 沈军,谢怀勤.先进复合材料在航空航天领域的研发与应用[J].材料科学与工艺,2008,16(5):737-740. [7] 张宁,岳清瑞,杨勇,等.碳纤维布加固钢结构疲劳试验研究[J].工业建筑,2004,34(4):19-21. [8] 伍希志,程军圣,杨宇,等.CFRP修复裂纹钢板的疲劳试验及参数研究[J].机械强度,2017,39(4):804-809. [9] TENG J G,FERNANDO D,YU T.Finite element modelling of debonding failures in steel beams flexurally strengthened with CFRP laminates[J].Engineering Structures,2015,86:213-224. [10] HANMANT S,PRASHANT K,MADHURI K,et al.Fatigue analysis of pre-cracked aluminium alloy thin sheets repaired with a CFRP patch at elevated temperature[J].Journal of the Institution of Engineers (India):Series C,2020,101(2):303-311. [11] BOCCIARELLI M,COLOMBI P,FAVA G,et al.Fatigue performance of tensile steel members strengthened with CFRPplates[J].Composite Structures,2009,87(4):334-343. [12] 郑云,叶列平,岳清瑞.CFRP加固疲劳损伤钢结构的断裂力学分析[J].工业建筑,2005,35(10):79-82. [13] 郑云,陈煊,李忠煜,等.碳纤维加固钢结构的疲劳寿命分析[J].钢结构,2013,28(2):1-6. [14] 郑云,叶列平,岳清瑞.FRP加固钢结构的研究进展[J].工业建筑,2005,35(8):20-25. [15] 黄瑞芬,罗建民,王春琴.激光熔覆技术的应用及其发展[J].兵器材料科学与工程,2005(4):57-59. [16] 胡芳友,刘洪军.激光熔覆对铝合金疲劳性能的影响[J].应用激光,2005(1):4-6. [17] 孙福娟,李晓崴.2A12CZ激光熔覆Al-Y的疲劳性能分析[J].青岛大学学报(自然科学版),2008(2):32-35. [18] DA S S,LIU Q,BRANDT M,et al.Effect of laser clad repair on the fatigue behaviour of ultra-high strength AISI 4340 steel[J].Materials Science&Engineering A,2014,606:46-57. [19] 葛茂忠,项建云,范真.激光熔覆修复对TC4钛合金疲劳裂纹扩展速率的影响[J].材料导报,2018,32(16):2803-2808. [20] 王一博,应丽霞,董国君,等.激光熔覆技术研究进展及其工业应用[J].中国材料进展,2009,28(3):17-21. [21] 阮仲伟.激光熔覆微气孔与增强颗粒对铝合金激光冲击强化及疲劳裂纹扩展行为的研究[D].镇江:江苏大学,2019. [22] 马思远.球墨铸铁制动盘热疲劳裂纹的激光仿生修复研究[D].长春:吉林大学,2020. [23] 佟鑫.激光仿生耦合处理铸铁材料的抗热疲劳性能研究[D].长春:吉林大学,2009. [24] 尹越,刘锡良.钢结构疲劳裂纹的止裂和修复[C]//第四届全国现代结构工程学术研讨会论文集.2004. [25] 袁周致远,吉伯海,傅中秋,等.钢箱梁顶板与竖向加劲肋疲劳裂纹的冲击裂缝闭合修复试验研究[J].工业建筑,2017,47(5):27-31. [26] 杨转运,刘会,吴汉辉.粘贴钢板法在桥梁加固中的应用[J].施工技术,2005,34(9):7-10. [27] 傅中秋,吉伯海.钢桥疲劳与维护[M].北京:人民交通出版社,2016. [28] 王东坡,龚宝明,吴世品,等.焊接接头与结构疲劳延寿技术研究进展综述[J].华东交通大学学报,2016,33(6):1-14. [29] 艾丽.疲劳荷载作用下钢桥疲劳寿命与延寿方法研究[D].武汉:武汉科技大学,2015. [30] 杜百平,马宝钿,李年,等.中间退火使疲劳损伤钢延寿的微观力学解释[J].机械强度,2002,24(4):613-616,499. [31] 杜百平,李年,马宝钿,等.疲劳损伤钢件延寿机理及效果[J].机械强度,2006,28(1):40-45. [32] 盛杰.激光喷丸强化IN718镍基合金高温疲劳特性及其延寿机理[D].镇江:江苏大学,2019. [33] PAPYRIN A N,ALKHIMOV A P,KOSAREV V F,et al.Experimental study of interaction of supersonic gas jet with a substrate under cold spray process[C]//Proceedings of the International Thermal Spray Conference.2001:423-431. [34] ASSADI H,KREYE H,GÄRTNER F,et al.Cold spraying:a materials perspective[J].Acta Materialia,2016,116:382-407. [35] ASSADI H,GÄRTNER F,STOLTENHOFF T,et al.Bonding mechanism in cold gas spraying[J].Acta Materialia,2003,51(15):4379-4394. [36] 钟厉,王昭银,张华东.冷喷涂沉积机理及其装备的研究进展[J].表面技术,2015,44(4):15-22. [37] GRUJICIC M,ZHAO C L,DEROSSET W S,et al.Adiabatic shear instability based mechanism for particles/substrate bonding in the cold-gas dynamic-spray process[J].Materials&Design,2004,25(8):681-688. [38] LI C J,LI W Y,WANG Y Y.Formation of metastable phases in cold-sprayed soft metallic deposit[J].Surface&Coatings Technology,2004,198(1/2/3):469-473. [39] 葛益,雒晓涛,李长久.冷喷涂固态颗粒沉积中颗粒间结合形成机制研究进展[J].表面技术,2020,49(7):60-67. [40] WANG Q,BIRBILIS N,ZHANG M X.Process optimisation of cold spray Al coating on AZ91 alloy[J].Surface Engineering,2014,30(5):323-328. [41] WANG Q,BIRBILIS N,ZHANG M X.Interfacial structure between particles in an aluminum deposit produced by cold spray[J].Materials Letters,2011,65(11):1576-1578. [42] WANG Q,SPENCER K,BIRBILIS N,et al.The influence of ceramic particles on bond strength of cold spray composite coatings on AZ91 alloy substrate[J].Surface&Coatings Technology,2010,205(1):50-56. [43] SANSOUCY E,KIM G E,MORAN A L,et al.Mechanical characteristics of Al-Co-Ce coatings produced by the cold spray process[J].Journal of Thermal Spray Technology,2007,16(5):651-660. [44] GHELICHI R,MACDONALD D,BAGHERIFARD S,et al.Microstructure and fatigue behavior of cold spray coated Al5052[J].Acta Materialia,2012,60(19):6555-6561. [45] PETRCKOVK,KONDS J,GUAGLIANO M.Mechanical performance of cold-sprayed A357 aluminum alloy coatings for repair and additive manufacturing[J].Journal of Thermal Spray Technology,2017,26(8):1888-1897. [46] ZIEMIAN C W,SHARMA M M,BOUFFARD B D,et al.Effect of substrate surface roughening and cold spray coating on the fatigue life of AA2024 specimens[J].Materials and Design,2014,54:212-221. [47] CAVALIERE P,SILVELLO A.Crack repair in aerospace aluminum alloy panels by cold spray[J].Journal of Thermal Spray Technology,2017,26(4):661-670. [48] CAVALIERE P,SILVELLO A.Finite element analyses of pure Ni cold spray particles impact related to coating crack behaviour[J].Surface Engineering,2018,34(5):361-368. [49] FACCOLI M,CORNACCHIA G,MAESTRINI D,et al.Cold spray repair of martensitic stainless steel components[J].Journal of Thermal Spray Technology,2014,23(8):1270-1280. [50] CIZEK J,MATEJKOVA M,DLOUHY I,et al.Influence of coldsprayed,warm-sprayed,and plasma-sprayed layers deposition on fatigue properties of steel specimens[J].Journal of Thermal Spray Technology,2015,24(5):758-768. [51] DAYANI S B,SHAHA S K,GHELICHI R,et al.The impact of AA7075 cold spray coating on the fatigue life of AZ31B cast alloy[J].Surface&Coatings Technology,2018,337:150-158. [52] YANG J F,YANG J L,XIE J,et al.Improved fatigue crack propagation performance of Q355B steel with cold-sprayed A5052and Al coatings[J].Surface and Coatings Technology,2019.DOI: 10.1016/j.surfcoat.2019.125000. [53] SILVELLO A,CAVALIERE P,RIZZO A,et al.Fatigue bending behavior of cold-sprayed nickel-based superalloy coatings[J].Journal of Thermal Spray Technology,2019,28(5):930-938.
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