[1]郭敏灵,董 钊,孟文波,等.海上高产气井防砂管柱冲蚀-腐蚀耦合作用风险评估研究[J].复杂油气藏,2021,14(02):111-118.[doi:10.16181/j.cnki.fzyqc.2021.02.022]
 GUO Minling,DONG Zhao,MENG Wenbo,et al.Risk assessment of erosion-corrosion coupling effect of sand control string in offshore high-yield gas wells[J].Complex Hydrocarbon Reservoirs,2021,14(02):111-118.[doi:10.16181/j.cnki.fzyqc.2021.02.022]
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海上高产气井防砂管柱冲蚀-腐蚀耦合作用风险评估研究
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《复杂油气藏》[ISSN:1674-4667/CN:31-2019/TQ]

卷:
14
期数:
2021年02期
页码:
111-118
栏目:
油气工程
出版日期:
2021-06-25

文章信息/Info

Title:
Risk assessment of erosion-corrosion coupling effect of sand control string in offshore high-yield gas wells
作者:
郭敏灵1董 钊2孟文波2崔书姮1张 群1
1.中海油能源发展股份有限公司工程技术湛江分公司,2.中海石油(中国)有限公司湛江分公司,广东 湛江 524057
Author(s):
GUO Minling1DONG Zhao2MENG Wenbo2CUI Shuheng1ZHANG Qun1
1.Zhanjiang Branch Compang of CNOOC Energy Technology & Services Limited;2.CNOOC Zhanjiang Branch Company,Zhanjiang 524057,China
关键词:
冲蚀腐蚀耦合耦合作用实验预测模型管柱寿命
Keywords:
erosion corrosion couplingcoupling experimentprediction modelstring life
分类号:
TE983
DOI:
10.16181/j.cnki.fzyqc.2021.02.022
文献标志码:
A
摘要:
冲蚀腐蚀耦合作用对海上高产气井防砂管柱的损害机理比单一腐蚀或冲蚀作用更为复杂,实验显示,耦合作用下的管材损失速率比单一作用高16.27%~251.79%。结合冲蚀腐蚀实验和已有的冲蚀腐蚀理论模型,考虑CO2分压、温度、流速、粒径和含砂量等因素影响,建立了适用于筛管冲蚀腐蚀耦合作用的经验模型;以南海L-1气田为目标区,分析11口井防砂筛管冲蚀腐蚀情况并预测管柱寿命。
Abstract:
The damage mechanism of the erosion-corrosion coupling effect on the sand control string of offshore high-production gas wells is more complicated than that of single corrosion or erosion effect. The experimental results showed that the pipe loss rate under coupling action is from 16.27% to 251.79% higher than a single action. Combined with the erosion-corrosion experiment and the existing erosion-corrosion theoretical model,considering the influence of CO2 partial pressure,temperature,flow rate,particle size,and sand content,etc.,it was established an empirical model for the erosion-corrosion coupling of screens. Taken L-1 Gasfield in the South China Sea as the target area,the erosion-corrosion conditions of 11 wells for sand control screens were analyzed and the service life of pipe string was predicted.

参考文献/References:

[1]伍丽娟,曹砚峰,翟晓鹏,等.金属网布防砂筛管冲蚀规律研究进展[J].冶金与材料,2020,40(4):4-6.
[2]胡成,邓福成,杨永刚,等.基于正交试验的割缝筛管冲蚀磨损分析[J].石油机械,2020,48(1):149-154.
[3]张锐,郝思臻,刘泽华,等.基于CFD的深水气井防砂筛管冲蚀仿真模拟[J].实验室研究与探索,2019,38(11):73-77,82.
[4]邱浩,曹砚锋,文敏,等.基于油井生产动态数据的出砂油井筛管冲蚀模型[J].石油钻采工艺,2019,41(6):796-801.
[5]廖华林,董林,牛继磊,等.砾石充填条件下筛管堵塞与冲蚀特性试验[J].中国石油大学学报(自然科学版),2019,43(3):90-97.
[6]匡韶华,王宝权.筛管冲蚀磨损研究综述及预防措施[J].石油工业技术监督,2015,31(4):44-48.
[7]刘新锋,张海龙,李效波,等.海上稠油热采筛管冲蚀影响因素[J].石油钻采工艺,2012,34(z1):73-75.
[8]方培林,杨凯,权宝华,等.渤海某油田井下管柱腐蚀原因分析[J].涂层与防护,2020,41(3):1-6,17.
[9]赵密锋,付安庆,秦宏德,等.高温高压气井管柱腐蚀现状及未来研究展望[J].表面技术,2018,47(6):44-50.
[10]林海,许杰,范白涛,等.渤海油田井下管柱CO2腐蚀规律与防腐选材现状[J].表面技术,2016,45(5):97-103.
[11]刘杰,李建东,尹志福,等.井下管柱腐蚀分析及缓蚀剂应用[J].腐蚀科学与防护技术,2016,28(1):95-96.
[12]蒲仁瑞,刘唯贤,李敏,等.气井管柱腐蚀机理研究及防治[J].钻采工艺,2003,26(1):80-82.
[13]PARSIM,NAJMIK,NAJAFIARDF,etal.Acompre-hensivereviewofsolidparticleerosionmodelingforoilandgaswellsandpipelinesapplications[J].JournalofNaturalGasScienceandEngineering,2014,21:850-873.
[14]SGROTTOL,NORILERD,WIGGERSVR,etal.CycloneoptimizationbycomplexmethodandCFDsim-ulation[J].PowderTechnology,2015,277:11-21.
[15]MANSOURIA,ARABNEJADH,SHIRAZISA,etal.AcombinedCFD/experimentalmethodologyforerosionprediction[J].Wear,2014,332/333:1090-1097.
[16]KHANOUKIHA,ZAHEDIP,SHIRAZISA,etal.Ero-sionmodelinginhighconcentrationslurryflow[C]//ASME2017FluidsEngineeringDivisionSummerMeeting,Waikoloa:ASME,2017:V01CT15A008.
[17]VIEIRARE,PARSIM,ZAHEDIP,etal.Ultrasonicmeasurementsofsandparticleerosionunderupwardmulti-phaseannularflowconditionsinavertical-horizontalbend[J].InternationalJournalofMultiphaseFlow,2017,93:48-62.
[18]GILLESPIEQ,BEARESP,JONESC.Sandcontrolsc-reenerosion-whenareyouatrisk?[C]//8thEuropeanFormationDamageConference,Scheveningen:SPE,2009:SPE-122269-MS.

备注/Memo

备注/Memo:
收稿日期:2020-12-28;改回日期:2021-05-18。
第一作者简介:郭敏灵(1986—),女,硕士,现从事海洋油气开发实验研究工作,E-mail:guoml3@cnooc.com.cn。
基金项目:国家重大专项深水油气田开发钻完井工程关键技术研究及配套工艺(2016ZX05028-001-09)。
更新日期/Last Update: 2021-06-30