Numerical Simulation of Water and Sand Blowouts When Penetrating Through Shallow Water Flow Formations in Deep Water Drilling

被引：0

作者：

REN Shaoran ^{[1
]}

LIU Yanmin ^{[1
]}

GONG Zhiwu ^{[1
]}

YUAN Yujie ^{[2
]}

YU Lu ^{[1
]}

WANG Yanyong ^{[1
]}

XU Yan ^{[1
]}

DENG Junyu ^{[3
]}

机构：

[1] School of Petroleum Engineering, ChinaUniversity of Petroleum (East China)

[2] Department of Petroleum Engineering, Curtin University

[3] Research Institute of Engineering Technology, ChinaNational Petroleum Corporation

来源：

JournalofOceanUniversityofChina | 2018年 / 17卷 / 01期

基金：

中央高校基本科研业务费专项资金资助;

关键词：

shallow water flow(SWF); deepwater drilling; water blowout; SWF hazards; flow simulation;

D O I：

暂无

中图分类号：

TE52 [海上油气田钻井工程];

学科分类号：

082002 ;

摘要：

In this study, we applied a two-phase flow model to simulate water and sand blowout processes when penetrating shallow water flow(SWF) formations during deepwater drilling. We define ‘sand’ as a pseudo-component with high density and viscosity, which can begin to flow with water when a critical pressure difference is attained. We calculated the water and sand blowout rates and analyzed the influencing factors from them, including overpressure of the SWF formation, as well as its zone size, porosity and permeability, and drilling speed(penetration rate). The obtained data can be used for the quantitative assessment of the potential severity of SWF hazards. The results indicate that overpressure of the SWF formation and its zone size have significant effects on SWF blowout. A 10% increase in the SWF formation overpressure can result in a more than 90% increase in the cumulative water blowout and a 150% increase in the sand blowout when a typical SWF sediment is drilled. Along with the conventional methods of well flow and pressure control, chemical plugging, and the application of multi-layer casing, water and sand blowouts can be effectively reduced by increasing the penetration rate. As such, increasing the penetration rate can be a useful measure for controlling SWF hazards during deepwater drilling.

引用

页码：17 / 24

页数：8

共 26 条

[1] Mechanisms of shallow waterflows and drilling practices for intervention. Alberty, Mark W.,Hafle, Mark E.,Mingle, John C.,Byrd, Tom M. SPE Drilling and Completion . 1999
[2] Atlantis, the quest for stray shallow-water-flow sands. Mannaerts, H.,Oldroyd, J.,Williams, M.,Fisher, R.,Radjef, E.,Day, R.,Faulkerson, J.,Pere, A.,Sanders, R.,Thomson, J.,Mix, K. JPT, Journal of Petroleum Technology . 2005
[3] EFFECTS OF TEMPERATURE ON HEAVY OIL-WATER RELATIVE PERMEABILITY OF SAND. Maini, Brij B.,Okazawa, T. Journal of Canadian Studies . 1987
[4] Dealing with shallow-water flow in the deepwater Gulf of Mexico. R. M. Ostermeier,J. H. Pelletier,C. D. Winker,J. W. Nicholson,F. H. Rambow,K. M. Cowan. The Leading EDGE . 2002
[5] Indentifying and mitigating the risks of shallow flow in deepwater cementing operations. BOGAERTS M,DEBRUIJIN G G,MORETTI F,et al. SPE 155733 . 2012
[6] Controlling shallow water flows in deep water. CAMERON C. offshore mediterranean conference and exhibition . 2005
[7] Unconventional method of conductor installation to solve shallow water flow problems. CHOE J,WOLD H C J. SPE 38625 . 1997
[8] Deepwater batchset operations through the magnolia shallow water flow sand. Luke F Eaton,Stephen C Actis,Roger N Williamson,et al. SPE92289 . 2005
[9] A successful field experience:shallow water flow-how to avoid the need for an additional casing string. PEDERSEN R,QIAN T,HAUGLAND T,et al. IADC/SPE112716 . 2008
[10] 南海北部陆坡浅水流评估及深水钻井防治措施
任韶然
宫智武
张亮
李海奎
韩波
任建华
章杨
[J]. 中国石油大学学报(自然科学版), 2017, 41 (04) : 99 - 106

← 1 2 3 →