Research Progress of Erosion Wear Theory of Gathering and Transportation Pipes
DOI:
https://doi.org/10.54097/ije.v2i1.5383Keywords:
Erosion wear mechanism, Plastic metal, Brittle metals, Influence factorAbstract
The development process of erosion wear theory research in the past 60 years is reviewed, the content and limitations of various mainstream erosion wear theories are analyzed, and the research and discovery of the influencing factors of erosion wear in various stages are summarized. The conclusion is that erosion wear is affected by many factors, which is difficult to be explained by a universal theory. It is believed that the research direction of erosion wear theory should focus on the test of highly reduced erosion conditions, supplemented by numerical simulation analysis, and combined with the comprehensive research of macro and micro.
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References
Peng Wenshan. Study on erosion mechanism of multiphase flow elbow containing solid particles [D]. China University of Petroleum (East China), 2017.
Xu Shang. Erosion simulation research and influence factor analysis of oil and gas field gathering pipeline [J] . Petroleum Pipes and Instruments, 2019, 5 (6): 4.
Zhao Xianping, Ye Guilin, Zhu Chongwu, Sun Jianrong. Experimental Study on Erosion Wear Behavior of 20 Carbon Steel at Different Temperatures [J]. Boiler Technology, 2017, 048 (001): 47-50.
Chen Chuanhui, Li Qingtang, Zhang Linjin, et al. Erosion Wear Behavior and Mechanism of Stainless Steel at High Temperature [J]. Material Protection, 2012, 45 (7): 4.
Wan Xihuang, Wang Benwu, Zhang Shaoguang, et al.Analysis and understanding of erosion of Christmas trees in moderate sand control wells [J]. Offshore Oil, 2021,41 (01): 32-38.
Zhang Jixin, Kang Jian, Fan Jianchun, et al. Study on erosion wear of oil and gas field surface manifold under fracturing condition [J]. Oil and Gas Field Surface Engineering, 2016, 35 (8): 5.
Qiu Hao, Li Zhong, Wen Min, et al. Risk Analysis and Optimization of Sand Control Screen Erosion in Deepwater A Gas Field, South China Sea [J]. Petroleum Machinery, 2022, 50 (10): 7.
Peng Donghua, Dong Shaohua, Zhang Xing, et al. Research progress of erosion wear in oil and gas pipeline industry [J]. Oil and gas storage and transportation, 2021, 40 (7): 12.
Li Qingtang. Development of high temperature erosion wear equipment and experimental study on erosion wear [D]. Nanjing: Nanjing University of Technology, 2011.
Zou Fengbin. Study on erosion and wear of surface high-pressure manifold of shale gas "industrial" fracturing Chengdu: Southwest Petroleum University, 2016.
Zheng Hualin, Zhang Yiwei, Liu Shaohu. Study on the influence of hydraulic fracturing erosion wear on the remaining life of coiled tubing [J]. Science and Technology of Work Safety in China, 2016.
FINNIE I. The mechanism of erosion of ductile metals[C]. New York: 3rd US National Congress of Applied Mechanics, 1958: 527-532.
BITTER J G. A study of erosion phenomena[J]. Wear, 1963, 6(3): 169-190.
SHELDON G L, ASHOK K. An investigation of impingement erosion using single particles[J]. Wear, 1972, 21(1): 195-209.
Tilly G P. A two stage mechanism of ductile erosion[J]. Wear, 1973, 23:87.
EVANS A G, BAO G, FAN B. Mixed mode delamination cracking in brittle matrix composites[J]. Mechanics of Material, 1979, 13(11): 311-319.
Hutchings I M.A model for the erosion of metals by spherical particles atnormal incidence[J].Wear, 1981, 70: 269.
Levy A V. The platelet mechanism of erosion of ductile metals[J]. Wear, 1986, 108(1): 1-21.
Levy A V. The erosion-corrosion behavior of protective coatings[J]. Surface and Coatings technology, 1988, 36(1-2): 387-406.
Lin Fuyan, Shao Hesheng. Study on the mechanism of low angle erosion wear [J]. Journal of China University of Mining and Technology, 1991, 20 (3): 28-34.
Shao Hesheng. The Foundation and Development of Abrasive Wear [J]. Electric Machinery, 1982 (04): 1-9.
Nathan G K, Jones W J D. The empirical relationship between abrasive wear and the applied conditions[J]. Wear, 1966, 9(4): 300-309.
Larsen-Badse J. Influence of grit diameter and specimen size on wear during sliding abrasion[J]. Wear, 1968, 12(1): 35-53.
Kragelskii I V, Mikhin N M, Myshkin N K, et al. The mechanism of the intital stage of selective transfer during frictional contact[J]. Wear, 1978, 47(1): 133-138.
Xu L, Kennon N F. A study of the abrasive wear of carbon steels[J]. Wear, 1991, 148(1): 101-112.
AHLERT K. Effects of particle impingement angle and surface wetting on solid particle erosion of AISI 1018 steel[D]. tulsa: The University of Tulsa, 1994.
Xie Wenwei, Deng Jianxin, Zhou Houming, He Chao. Research Status and Prospect of Numerical Simulation of Material Erosion Wear [J]. Corrosion and Protection, 2012,33 (07): 601-604.
Meng H C, Ludema K C. Wear models and predictive equations: their form and content[J]. Wear, 1995, 181: 443-457.
Aziz M A, Mahmoud T S, Aal A A. Modeling and optimizing of factors affecting erosion–corrosion of AA6063–(TiC/Al2O3) hybrid composites by experimental design method[J]. Materials Science and Engineering: A, 2008, 486(1-2): 313-320.
Qu Wentao, Cheng Jiarui. Study on erosion behavior of 20Cr steel by sand ratio [J]. Henan Science and Technology, 2013 (19): 57.
Sun Bingcai, Fan Jianchun, Wen Dong, et al. Impact of High Pressure on Erosion Wear of High Pressure Manifold [J]. Lubrication and Sealing, 2014, 39 (04): 11-14.
Ben-Ami Y, Uzi A, Levy A. Modelling the particles impingement angle to produce maximum erosion[J]. Powder Technology, 2016, 301:1032-1043.
Ahmed D H, Naser J, Deam R T. Particles impact characteristics on cutting surface during the abrasive water jet machining: Numerical study[J]. Journal of materials processing technology, 2016, 232: 116-130.
Khan M M. Dixit G. Erosive wear response of SIC P reinforced aluminium based metal matrix composite: Effects of test environments[J]. Journal of Mechanical Engineering and Sciences, 2017, 11(1):2401.
Chen Xiaochen, Deng Songsheng, Guan Jinfa, et al. Study on Morphological Characteristics and Mechanism of Abrasive Water Jet Erosion Metal Damage [J]. Journal of Tribology, 2018, 38 (01): 8-16.
