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深水海底管线主动加热技术对比分析 被引量:1

Comparison and Analysis of Active Heating Technology in Deepwater Subsea Flowline
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摘要 在水下生产系统设计中,流动安全保障起着重要作用。为了防止生成固体沉积(如蜡和水合物等),常采用热管理策略保障海底管线流体流动安全。热管理策略中被动保温技术无法控制流体的温度和流体冷却时间,而主动加热技术能够克服这一缺点。对主动加热技术进行了对比分析介绍,可供海底管线工程设计借鉴。 Flow assurance plays a crucial role in subsea production system design.In order to prevent the formation of solid deposition,such as wax and hydrate,the thermal management strategy is often used in subsea flowline flow assurance.Passive thermal insulation technology of thermal management strategy cannot control the fluid temperature and fluid cooling time.And active heating technology can overcome this shortcoming.The active heating technology are introduced and analyzed.It is reference for submarine pipeline engineering design.
作者 王东
机构地区 海洋石油工程股份有限公司
出处 《石油化工设备》 CAS 2016年第3期64-68,共5页 Petro-Chemical Equipment
基金 工业和信息化部海洋工程装备科研项目"水下生产系统设计及关键设备研发(一期)"(E-0813C003)
关键词 海底管线 流动保障 加热 主动加热 对比分析 deepwater subsea flowline flow assurance heating active heating comparison analysis
分类号 TQ055.8 [化学工程] TE973.1 [石油与天然气工程—石油机械设备]
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参考文献22

  • 1FU B. Managing Fluid Behavior, Solids Deposition to Ensure Optimum Flow[J]. Offshore, 2000,60 (40) .. 88- 90,225. 被引量:1
  • 2Sylvain Denniel. Review of Flow Assurance Solutions for Deep Water Fields [C]//OTC 16686, Offshore Technology Conference. Houston,2004. 被引量:1
  • 3侯磊,张劲军.基于流动保障的海底油气管道安全策略与技术[J].中国海上油气(工程),2004,16(4):285-288. 被引量:37
  • 4Brown L D. Flow Assurance: Arra Discipline [C]// OTC 14010, Offshore Technology Conference. Hous- ton,2002. 被引量:1
  • 5Minami K,Kurban A P A. Ensuring Flow and Produc- tion in Deepwater Environments [C]//OTC 11035, Offshore Technology Conference. Houston, 1999. 被引量:1
  • 6. Margaret Hight,Janardhan Davalath. Economic Considera- tion for Flowline Heat Loss Control[C]//OTC 12036, Offshore Technology Conference. Houston, 2000. 被引量:1
  • 7Jian Su. Thermal Analysis of Combined Active Heating and Passive Insulation of Deepwater Pipelines[C]// OMAE2002-28491,Offshore Mechanics and Attic En- gineering. Norway, 2002. 被引量:1
  • 8BAI Yong, BAI Qiang. Subsea Pipeline Sand Risers [M]. London: Elsevier Science Ltd. , 2005. 被引量:1
  • 9Hansen A B. Direct Impedance Heating of Deepwater Flowlines [ C]//OTC 11037, Offshore Technology Conference. Houston, 1999. 被引量:1
  • 10Jian Su,Djane R Cerqueira. Thermal Analysis of Sand- wich Pipes with Active Electrical Heating [C]// OMAE2003-37423,Offshore Mechanics and Attic En- gineering. Mexico, 2003. 被引量:1

二级参考文献14

  • 1侯磊,张劲军.基于流动保障的海底油气管道安全策略与技术[J].中国海上油气(工程),2004,16(4):285-288. 被引量:37
  • 2Chin Y D. Maintaining plug-free flow and remediating plugged pipelines. Offshore, 2001,61 (2): 68,70,104 被引量:1
  • 3Mackintosh N, Atakan Z. Flow assurance still leading concern among producers, Offshore, 2000,60 (10): 79,174 被引量:1
  • 4Fu B. Managing fluid behavior, solids deposition to ensure optimum flow. Offshore, 2000,60 (40): 88,90,225 被引量:1
  • 5Remery J, Coutarel A. Pipeline heat loss rigid, flexible,and pipe-inpipe deepwater transport. Offshore, 2001,61 ( 1 ): 76,78 被引量:1
  • 6Minami K, Kurban A P A, Khalil C Net al. Ensuring flow and production in deepwater environments. 31th Annual SPE et al Offshore Technology Conf. OTC-11035,1999,3: 671 - 679 被引量:1
  • 7Illeman J R. Pipeline blockage remediation can reach five miles. Offshore, 1998,58(3): 106 - 107 被引量:1
  • 8Chin W C. Modern flow assurance methods: clogged pipelines, wax deposition, hydrate plugs. Offshore, 2000,60 (9): 92 - 94,180 被引量:1
  • 9Torres J M,Tucker C, Khurana S et al. Deep water challenges for ensuring pipe flow. Hart's E&P,2000,73(7) :42-48 被引量:1
  • 10Pattee F M,Kopp F. Impact of electrically-heated systems on the operation of deep water subsea. 32th Annual SPE et al Offshore Technology Conf. OTC-11894,2000,3:127- 136 被引量:1

共引文献42

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二级引证文献8

石油化工设备
2016年 第3期

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