A Review of the Research on the Fatigue Properties of Ultra-high Strength Cement-based Grouting Materials
SHA Jianfang1,2, XIA Zhongsheng1,2,*, LIU Jianzhong1,2, GUO Fei1,2, XU Haiyuan1,2
1 State Key Laboratory of High Performance Civil Engineering Materials, Nanjing 210008, China; 2 Jiangsu Sobute New Materials Co. Ltd., Nanjing 211103, China
Abstract: Offshore wind power is an important part of the development of clean energy in the future, and the wind turbine foundation is one of the key points of offshore wind farm construction. The foundation of offshore fan is mostly connected by grouting, and the upper and lower parts of the foundation are formed into a stress structure by pouring ultra-high strength cement-based grout into the inner and outer steel cylinders. In the long service life of the fan, the grouting connection section will bear up to 100 million times axial and bending moment load effects, and the fatigue problem is more prominent. As an important part of grouting connection, grouting material’s fatigue performance is an important performance index to evaluate the bearing capacity of grouting connection. Ultra-high strength cement-based grouting materials and high strength concrete all belong to the category of cement-based materials, which have common points in fatigue damage mechanism. The fatigue damage and ultimate failure mechanism of water mud based materials under uniaxial constant amplitude fatigue load is a hot topic in this field. However, as a new type of building material, the research on the fatigue performance of ultra-high strength grouting material is relatively less due to the research and development level. In recent years, the units of materials in the industry have carried out the research on the relationship between the fatigue strength and fatigue life of related products. Based on the brand products in the industry, relevant universities have successively carried out the research on the static and fatigue performance of different structural forms of grouting connection sections, and have also made some achievements. However, the influence factors and damage mechanism of ultra-high strength grouting materials are still blank. For concrete materials used in engineering, researchers have carried out a relatively complete study on fatigue performance, including fatigue damage and ultimate failure mechanism under repeated load, fatigue performance under uniaxial and multiaxial compression, tension, bending tension and composite load, test methods, influencing factors and mechanism, etc. Due to the influence of test equipment, conditions, environment and other factors, the results show diversity and discreteness. In the aspect of ultra-high strength grouting materials, the researchers focus on the fatigue performance acquisition, performance prediction and the research of the fatigue performance of the grouting joint under different service conditions, and form the relevant specifications for the fatigue performance calculation of grouting materials in offshore wind farms. This paper reviews the relevant progress of domestic and foreign scholars in the fatigue performance and damage mechanism of concrete and grouting materials, and draws the research experience of the fatigue performance of concrete, in order to provide guidance and reference for the fatigue performance research of ultra-high strength grouting materials. It also expounds the commonly used fatigue life prediction model of concrete, and makes parameter interpretation and adaptability analysis on the fatigue calculation model of grouting material in offshore wind farm in DNV-GL series of specifications, so as to promote the relevant practitioners and researchers to further understand the fatigue properties of ultra-high strength grouting materials.
沙建芳, 夏中升, 刘建忠, 郭飞, 徐海源. 超高强水泥基灌浆材料疲劳性能研究综述[J]. 材料导报, 2021, 35(11): 11013-11026.
SHA Jianfang, XIA Zhongsheng, LIU Jianzhong, GUO Fei, XU Haiyuan. A Review of the Research on the Fatigue Properties of Ultra-high Strength Cement-based Grouting Materials. Materials Reports, 2021, 35(11): 11013-11026.
Igwemezie V, Mehmanparast A, Kolios A. Renewable & Sustainable Energy Reviews,2019,101,181.
2
Song C. Shanxi Energy and Conservation,2010(2),46(in Chinese).
宋础.山西能源与节能,2010(2),46.
3
Guo L P. Study on fatigue property and equation of high performance concrete with high proportion ground blast furnace slag. Master's Thesis, Southeast University, China,2005(in Chinese).
郭丽萍.大掺量磨细矿渣高性能砼疲劳性能研究与疲劳方程的建立.硕士学位论文,东南大学,2005.
4
Zhou B M. Experimental study on compressive fatigue properties of UHTCC. Master's Thesis, Zhejiang University, China,2015(in Chinese).
Zheng K R. Effect of mineral admixtures on fatigue behavior of concrete and mechanism. Ph. D. Thesis, Southeast University, China,2005(in Chinese).
郑克仁.矿物掺合料对混凝土疲劳性能的影响及机理.博士学位论文,东南大学,2005.
6
Ou J P, Lin Y Q. China Civil Engineering Journal,1999(5),15(in Chinese).
欧进萍,林燕清.土木工程学报,1999(5),15.
7
Ma N J. Journal of Tianjin Vocational Institutes,2018,20(7),109(in Chinese).
马纳静.天津职业院校联合学报,2018,20(7),109.
8
Xin L, Jiang F X, Jiang J Y, et al. Journal of Qingdao University of Technology,2011(3),18(in Chinese).
辛雷,姜福香,蒋金洋,等.青岛理工大学学报,2011(3),18.
9
Holmen J O. ACI Special Publication,1982,75,71.
10
Zhou H Y,Liu H Y,Zhao X H,et al. Concrete,2019(12),1(in Chinese).
周宏宇,刘洪宇,赵晓花,等.混凝土,2019(12),1.
11
Hong J X, Miao C W, Shi X X, et al. Journal of Nanjing University of Science and Technology,2013,37(1),150(in Chinese).
洪锦祥,缪昌文,石杏喜,等.南京理工大学学报,2013,37(1),150.
12
Zhu J S,Xiao R C,Song Y P. Journal of Building Materials,2005.8(5),484(in Chinese).
朱劲松,肖汝诚,宋玉普.建筑材料学报,2005,8(5),484.
13
Zhu J S,Zhu X C. Engineering Mechanics,2012,29(5),107(in Chinese).
朱劲松,朱先存.工程力学,2012,29(5),107.
14
Liu J C,Chen T,Ma Z R,et al. Grouting technology of offshore wind fram, China Water & Power Press, China,2016(in Chinese).
刘晋超,陈涛,马兆荣,等.海上风电灌浆技术,中国水利水电出版社,2016.
15
Xu S N,Dong L X,Wang B W,et al. Journal of Hydraulic Engineering,2014,45(1),1(in Chinese).
徐世娘,董丽欣,王冰伟,等.水利学报,2014,45(1),1.
16
Fan Z Y. Study on fatigue damage of concrete based on ICT technique. Master's Thesis, Harbin Institute of Technology, China,2018(in Chinese).
樊梓元.基于ICT技术的混凝土疲劳损伤分析研究.硕士学位论文,哈尔滨工业大学,2018.
17
Pease B J, Scheffler G A, Janssen H. Construction and Building Mate?rials,2012,36,419.
18
Wei T, Dang F N, Xie Y L. Sadhana,2015,40(1),263.
19
Obara Y, Tanikura I, Jung J, et al. Journal of Advanced Concrete Technology,2016,14(8),433.
20
Promentilla M A B, Sugiyama T. Journal of Advanced Concrete Technology,2010,8(2),97.
21
Promentilla M A B, Sugiyama T. Advances in computed tomography for geomaterials: GeoX 2010,John Wiley & Sons, Inc, New York, USA,2013.
22
Lindquist W B, Venkatarangan A. Physics & Chemistry of the Earth Part A Solid Earth & Geodesy,1999,24(7),593.
23
Meng X H. Experimental and theoretical research on residual strength of concrete under fatigue loading. Ph.D. Thesis, Dalian University of Technology, China,2006(in Chinese).
孟宪宏.混凝土疲劳剩余强度试验及理论研究.博士学位论文,大连理工大学,2006.
24
Van Ornum J. Transctions,1903,51,443.
25
Aas?Jakobsen K. Fatigue of concrete beams and columns,Norwegian, 1970.
26
Matsushita H, Tokumitsu Y. Proceeding of JSCE,1972,198(2),127.
27
Gray W,Melaughlin J F, Antrim J C. ACI Journal,1961,58,149.
28
Murdock J W. Engineering Experiment Station Bulletin,1965,475,25.
29
Bennett E W, Muir S E J. Magazine of Concrete Research,1967,19(59),113.
30
Sparks P R, Menzies J B. Magazine of Concrete Research,1973,25(83),73.
31
Kim J K, Kim Y Y. Cement and Concrete Research,1996,26(10),1513.
32
Wu P G, Zhao G Y, Bai L M. China Civil Engineering Journal,1994,27(3),33(in Chinese).
吴佩刚,赵光仪,白利明.土术工程学报,1994,27(3),33.
33
Chen X, Liu Z, Guo S, et al. Construction and Building Materials,2019,205,10.
34
Erik L N, Ramon I. ACI Materials Journal,1988,85(3),248.
35
Chen Z F S,Li Q B. Journal of Hydraulic Engineering,2008,39(4),385(in Chinese).
陈樟福生,李庆斌.水利学报,2008,39(4),385.
36
Lan S R, Guo Z H. Journal of Materials in Civil Engineering,1999,11(2),105.
37
Wang R M, Zhao G F, Song Y P. China Civil Engineering Journal,1991,24(4),38(in Chinese).
王瑞敏,赵国藩,宋玉普.土术工程学报,1991,24(4),38.
38
Lv P Y. Experimental study on dynamic strength and deformation of concrete under uniaxial and biaxial action. Ph.D. Thesis, Dalian University of Technology, China,2001(in Chinese).
吕培印.混凝土单轴、双轴动态强度和变形试验研究.博士学位论文,大连理工大学,2001.
39
Zhu J S. Experimental study on fatigue properties of plain concrete under biaxial stress states and theories on failure prediction.Ph.D. Thesis, Dalian University of Technology, China,2003(in Chinese).
朱劲松.混凝土双轴疲劳试验与破坏预测理论研究.博士学位论文,大连理工大学,2003.
40
Shen J Y. Experimental study on dynamic biaxial compression test and damage constitutive model of full?graded concrete. Master's Thesis, Dalian Jiaotong University, China,2018(in Chinese).
申佳玉.全级配混凝土动态双轴压试验及其损伤本构模型研究.硕士学位论文,大连交通大学,2018.
41
Shen L. Test and design index of multi?axial dynamic mechanical properties of hydraulic concrete. Ph.D. Thesis, Dalian University of Techno?logy, China,2018(in Chinese).
沈璐.水工混凝土多轴动态力学特性试验及设计指标研究.博士学位论文,大连理工大学,2018.
42
Badly P F, Vial D J, Hanus J L. International Journal of Impact Engineering,2011,38(2),73.
43
Chen J Y, Zhang Z X. Engineering Failure Analysis,2011,18(7),1784.
44
Fujikake K, Mori K, Uebayashi K. Structures and Materials,2000,(8),511.
45
Zeng S J, Ren X D, Li J. Journal of Structural Engineering,2013,139(9),1582.
46
Surendra P, Shah A P F, Richard A. Journal of structural Engineering,1983,109(7),1695.
47
Taliercio A, Gobbi E. Magazine of Concrete Research,1996,48(176),151.
48
Hooi T T. Magazine of Concrete Research,2000,52(1),7.
49
Cao W, Hu J Z. China Civil Engineering Journal,2005,38(8),31(in Chinese).
曹伟,胡建周.土术工程学报,2005,38(8),31.
50
Cornelissen H A W, Reinhardt H W. Magazine of Concrete Research,1984,36(129),216.
Zhang B, Philips D V, Wu K. Magazine of Concrete Research,1996,48(177),361.
53
Zhao K,Qiao C S,Luo F R,et al. Chinese Journal of Rock Mechanics and Engineering,2014,33(S2),3466(in Chinese).
赵凯,乔春生,罗富荣,等.岩石力学与工程学报,2014,33(S2),3466.
54
L?hning T, Vo?beck M, Kelm M. Proceedings of the Institution of Civil Engineers?Energy,2013,166(4),153.
55
S?rensen E V. Nordic Concrete Research,2011,44,1.
56
Liu D H,Yuan G K,Chen T,et al. Southern Energy Construction,2016(S1),76(in Chinese).
刘东华,元国凯,陈涛,等.南方能源建设,2016(S1),76.
57
Andersen M S, Petersen P. Global Wind Power,2004,1,1.
58
Wilke F. Load bearing behaviour of grouted joints subjected to predominant bending. Ph.D. Thesis, Leibniz University,2014.
59
Li Z X,Chen T,Zhao Q,et al. Journal of Building Structures,2017(s1),465(in Chinese).
李筑轩,陈涛,赵淇,等.建筑结构学报,2017(s1),465.
60
Lotsberg I. Marine Structures,2013,32,113.
61
Chen T, Zhang C H, Zhao Q, et al. The Ocean Engineering,2017,35(3),112(in Chinese).
陈涛,张持海,赵淇,等.海洋工程,2017,35(3),112.
62
Chen T, Zhang C H, Zhao Q, et al. Naval Architecture and Ocean Engineering,2018,34(5),1(in Chinese).
陈涛,张持海,赵淇,等.船舶与海洋工程,2018,34(5),1.
63
Han L H, Tao Z, Yan W B. Earthquake Engineering and Engineering Dynamics,2001,21(1),64(in Chinese).
韩林海,陶忠,阎维波.地震工程与工程振动,2001,21(1),64.
64
Nie J G, Wang Y H, Fan J S. China Civil Engineering Journal,2014(1),47(in Chinese).
聂建国,王宇航,樊健生.土木工程学报,2014(1),47.
65
Zhong W Q, Zhang H M. Low Temperature Architecture Technology,2014,36(6),83(in Chinese).
仲伟秋,张宏民.低温建筑技术,2014,36(6),83.
66
Zhao Q, Chen T, Wang X, et al. Structural Engineers,2016,32(5),59(in Chinese).
赵淇,陈涛,王衔,等.结构工程师,2016,32(5),59.
67
Billington C J, Tebbett I E. In: Proceedings of the Annual Offshore Technology Conference. Houston, Texas,1980,pp.449.
68
Ingebrigtsen T, Loset ?, Nielsen S G. In: 22nd Offshore Technology Conference. Houston, Texas,1990,pp.615.
69
Boswell L F, D'Mello C. In: Offshore Technology Conference. Houston, Texas,1986.
70
Lohaus L, Anders S. Wind energy, Springer, Berlin,2007,pp.309.
71
Schaumann P, Wilke F. In: Proceedings of the 8th German Wind Energy Conference. Dewek,2006.
72
Schaumann P, Bechtel A, Lochte?Holtgreven S. In: Proceedings of the European Wind Energy Conference. Honolulu, Hawaii,2010,pp.2047.
73
Schaumann P, Wilke F. In: The Seventeenth International Offshore and Polar Engineering Conference. Lisbon, Portugal,2007,pp.340.
74
Schaumann P, Wilke F, Lochte?Holtgreven S. In: European Wind Energy Conference. Brussels,2008.
75
Schaumann P, Wilke F, Lochte?Holtgreven S. Stahlbau,2008,77(9),647.
76
Schaumann P, Lochte?Holtgreven S. In: DEWEK 2010?10th German Wind Energy Conference. Bremen,2010.
77
Schaumann P, Lochte?Holtgreven S. Stahlbau,2011,80(4),226.
78
Klose M, Mittelstaedt M, Mulve A. In: The Twenty?second International Offshore and Polar Engineering Conference. Rhodes, Greece,2012,pp.434.
79
Chen T, Wang X, Yuan G K, et al. Marine Structures,2018,60,52.
80
Wang X, Chen T, Zhao Q, et al. International Journal of Steel Structures,2016,16(4),1149.
81
Moller A. Wind Engineering,2005,29(5),463.
82
Wang D D, Chen K W, Wang C Q, et al. Ocean Development and Management,2018(S1),140(in Chinese).
汪冬冬,陈克伟,王成启,等.海洋开发与管理,2018(S1),140.
83
Sun Y B, Chen D M. China Harbour Engineering,2016,36(11),42(in Chinese).
孙洋波,陈大明.中国港湾建设,2016,36(11),42.
84
Lotsberg I, Serednicki A, Oerlemans R, et al. The Structural Engineer,2013,91(1),42.
85
Li F Z. Research on load capacity of the corroded reinforced concrete beam after reciprocating load. Master's Thesis, Liaoning Technical University, China,2014(in Chinese).
李富斋.往复荷载作用后锈蚀钢筋混凝土梁承载力研究.硕士学位论文,辽宁工程技术大学,2014.
86
Li F Z, Yang X M. In: Proceedings of the twenty?first national conference on structural engineering. Shenyang, China,2012,pp.42.
李富斋,杨晓明.第21届全国结构工程学术会议.沈阳,2012,pp.42.
87
Wang X Y, Wang L, Zhao Y R. Sichuan Cement,2018(1),316(in Chinese).
王晓勇,王磊,赵燕茹.四川水泥,2018(1),316.
88
Gao W G. Research on fatigue analysis of open type wharf on piles under cyclic loading. Master's Thesis, Tianjin University, China,2008(in Chinese).
高万国.循环荷载作用下高桩码头构件疲劳损伤分析方法研究.硕士学位论文,天津大学,2008.
89
Liu Y, Gu Q, Tian S, et al. Bulletin of the Chinese Ceramic Society,2019,38(5),1356(in Chinese).
刘月,谷倩,田水,等.硅酸盐通报,2019,38(5),1356.
90
Zheng X L, Wang H, Yan J H, et al. Material fatigue theory and engineering application, Science Press, China,2013(in Chinese).
郑修麟,王泓,鄢君辉,等.材料疲劳理论与工程应用,科学出版社,2013.
91
Shi X P, Yao Z K, Li H, et al. China Civil Engineering Journal,1990(3),12(in Chinese).
石小平,姚祖康,李华,等.土木工程学报,1990(3),12.
92
Wang F W, Xu R P, Zhang L X, et al. Journal of Tongji University,2003,31(4),1146(in Chinese).
王凤武,徐人平,张立翔,等.同济大学学报,2003,31(4),1146.
93
Ou Z M, Sun L. Journal of Zhejiang University (Engineering Science),2017,51(6),1074(in Chinese).
欧祖敏,孙璐.浙江大学学报(工学版),2017,51(6),1074.
94
Yang K W, Luo X G. Journal of Hunan Institute of Engineering (Natural Science Edition),2016,26(1),76(in Chinese).
杨科文,罗许国.湖南工程学院学报(自然科学版),2016,26(1),76.
95
Zhao Y L, Sun W. Journal of Chongqing Jiaotong University,1999(1),19(in Chinese).
赵永利,孙伟.重庆交通学院学报,1999(1), 19.
96
Susmel L, Meneghetti G, Atzori B. Journal of Engineering Materials and Technology,2009,131(2),021.
97
Zhao H X. Development of fatigue life prediction toolbox based on fracture mechanics. Master's Thesis, Northeastern University, China,2012(in Chinese).
赵海翔.基于断裂力学的疲劳寿命预测工具箱的开发.硕士学位论文,东北大学,2012.
98
Ji J L, Li H J, Yan G L, et al. Journal of Wuhan University of Technology (Transportation Science & Engineering).2009,33(1),95(in Chinese).
季家林,李慧剑,闫国亮,等.武汉理工大学学报(交通科学与工程版),2009,33(1),95.
99
Lei D, Zhao J H, Gong M, et al. Journal of Experimental Mechanics,2008(5),60(in Chinese).
雷冬,赵建华,龚明,等.实验力学,2008(5),60.
10
0 Zhang L, Yuan J X, Liu W J, et al. Journal of Harbin Institute of Technology,2011(s1),53(in Chinese).
张莉,袁家欣,刘文晶,等.哈尔滨工业大学学报,2011(s1),53.
1 Tang H W, Li S B, Zhu C M. Journal of the China Railway Society,2007(3),86(in Chinese).
汤红卫,李士彬,朱慈勉.铁道学报,2007(3),86.
2 Yang Y, Fu D Y, Yong B. Journal of Chongqing Technology and Business University (Natural Science Edition),2019,36(3),87(in Chinese).
杨艺,付道一,雍彬.重庆工商大学学报(自然科学版),2019,36(3),87.
3 Song C. Shanxi Energy and Conservation,2010(3),37(in Chinese).