注水泥环空动态顶替界面长距离数值模拟
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摘要
借助流体力学软件FLUENT对环空注水泥层流顶替进行了长距离的数值模拟。利用流体体积法(VOF)对两相顶替界面进行了界面重构。对顶替界面达到动态稳定形态的过程进行了描述,对不同偏心度、密度差、顶替速度和流体黏度条件下的顶替界面进行了模拟。模拟结果显示,顶替开始后界面长度不断拉长,在正密度差下界面会达到动态稳定(在一个范围内波动)或者绝对稳定,并以此稳定界面向前推进,而动态稳定界面会使得窄间隙留下无法驱替的滞留层。在同心环空中,只要存在正密度差即可达到绝对稳定的界面;在偏心环空中高密度差下界面会达到绝对稳定,其他情况会获得动态稳定界面,此密度差节点与偏心度呈正相关;负密度差下界面均无法达到稳定;从对顶替界面达到稳定状态的影响效果来看,从大到小依次为偏心度、密度差、顶替速度和流体流变性能。该模拟结果对水泥浆密度设计、隔离液用量和环空注水泥施工有很好的指导性作用。
In this paper,the displacement process of cement in annulus was simulated by FLUENT software.Displacement interface of two-phase in 300 mannulus is to be re-constructed by Volume of Fluid(VOF)method.Under conditions of different density contrast,rheological property,displacement rate and eccentricity of casing,the dynamically interfaces were simulated and the changing processes were recorded.Simulation results showed that,the interface is absolute stable as long as the density difference is positive in concentric annulus.This positive value needs higher in eccentric annulus and its node is positively related to the eccentricity;otherwise a dynamic stable interface which fluctuates in small scope would be achieved.Under the negative density contrast,the interface cannot reach a steady state.The influence factors from high to low are:degree of eccentricity,density difference,displacement velocity and fluid rheological properties.Smaller casing eccentricity,larger density difference and displacement rate,can reduce the dynamic interface length and enhance the displacement efficiency.The length of the interface is shorter.The simulation results could guide the design of spacer and cementing.
In this paper,the displacement process of cement in annulus was simulated by FLUENT software.Displacement interface of two-phase in 300 mannulus is to be re-constructed by Volume of Fluid(VOF)method.Under conditions of different density contrast,rheological property,displacement rate and eccentricity of casing,the dynamically interfaces were simulated and the changing processes were recorded.Simulation results showed that,the interface is absolute stable as long as the density difference is positive in concentric annulus.This positive value needs higher in eccentric annulus and its node is positively related to the eccentricity;otherwise a dynamic stable interface which fluctuates in small scope would be achieved.Under the negative density contrast,the interface cannot reach a steady state.The influence factors from high to low are:degree of eccentricity,density difference,displacement velocity and fluid rheological properties.Smaller casing eccentricity,larger density difference and displacement rate,can reduce the dynamic interface length and enhance the displacement efficiency.The length of the interface is shorter.The simulation results could guide the design of spacer and cementing.
引文
[1]高永海,孙宝江,刘东清,等.环空水泥浆顶替界面稳定性数值模拟研究[J].石油学报,2005,26(5):118-121.
[2]廖华林,李根生,张树坤.小眼井层流注水泥顶替机理分析[J].石油钻探技术,2003,31(6):30-32.
[3]杨建波,邓建民,冯予淇,等.低速注水泥时密度差对顶替效率影响规律的数值模拟研究[J].石油钻探技术,2008,36(5):62-65.
[4]SMITH T.Cementing displacement practices-field applications[J].Journal of Petroleum Technology,1990,42(5):564-566.
[5]冯福平,艾池,杨丰宇,等.偏心环空层流顶替滞留层边界位置研究[J].石油学报,2010,31(5):858-862.
[6]刘希圣,樊洪海,丁岗.幂律流体在定向井偏心环空内流动规律的研究[J].石油大学学报(自然科学版),1988(4/5):34-45.
[7]杨树人,申加年,张景富.幂律流体偏心环空轴向层流流动的速度分布[J].大庆石油学院学报,1997,21(1):122-125.
[8]李静,林承焰,王言峰.非牛顿流体顶替机理研究综述[J].钻井液与完井液,2009,26(1):75-77.
[9]SAIRAM P K S,MARK S,RONNIE M.Accurate and fast method for predicting actual top-of-cement depths in eccentric wellbores[R].SPE126703,2010.
[10]LI X,NOVOTNY R.Study on cement displacement by lattice-boltzmann method[R].SPE102979,2006.
[11]魏淑惠,张长海,陈皖,等.基于计算流体动力学的偏心环空流场数值模拟[J].大庆石油学院学报,2007,31(6):62-64.
[12]王常斌,陈皖,田迪,等.幂律流体偏心环空流场的CFD模拟[J].钻井液与完井液,2009,26(3):62:64.
[13]郑永刚.定向井层流注水泥顶替的机理[J].石油学报,1995,16(4):133-139.
[14]高永海,孙宝江,赵欣欣,等.前置液流变性对顶替界面稳定性影响的数值模拟[J].中国石油大学学报(自然科学版),2007,31(6):51-54.
[15]SAVERY M,DARBE R.Modeling fluid interfaces during cementing using a 3D mud displacement simulator[R].OTC18513,2007.
[16]周仕明,李根生,方春飞.元坝地区146.1mm尾管固井技术难点与对策[J].石油钻探技术,2010,38(4):41-44.
[17]王瑞金,张凯,王刚.Fluent技术基础与应用实例[M].北京:清华大学出版社,2007:46-49.
[18]韩占忠,王敬,兰小平.FLUENT:流体工程仿真计算实例与应用[M].北京:北京理工大学出版社,2004:137-171.
[19]王斌斌,王瑞和,步玉环.不同流态下水泥浆环空顶替的数值模拟研究[J].钻井液与完井液,2010,27(3):76-78.
[20]孙宝江,高永海,刘东清.水泥浆流变性分析及其环空流动的数值模拟[J].水动力学研究与进展,2007,22(3):317-324.
[21]李明忠,王成文,王长权,等.大斜度井偏心环空注水泥顶替数值模拟研究[J].石油钻探技术,2012,40(5):40-44.
[2]廖华林,李根生,张树坤.小眼井层流注水泥顶替机理分析[J].石油钻探技术,2003,31(6):30-32.
[3]杨建波,邓建民,冯予淇,等.低速注水泥时密度差对顶替效率影响规律的数值模拟研究[J].石油钻探技术,2008,36(5):62-65.
[4]SMITH T.Cementing displacement practices-field applications[J].Journal of Petroleum Technology,1990,42(5):564-566.
[5]冯福平,艾池,杨丰宇,等.偏心环空层流顶替滞留层边界位置研究[J].石油学报,2010,31(5):858-862.
[6]刘希圣,樊洪海,丁岗.幂律流体在定向井偏心环空内流动规律的研究[J].石油大学学报(自然科学版),1988(4/5):34-45.
[7]杨树人,申加年,张景富.幂律流体偏心环空轴向层流流动的速度分布[J].大庆石油学院学报,1997,21(1):122-125.
[8]李静,林承焰,王言峰.非牛顿流体顶替机理研究综述[J].钻井液与完井液,2009,26(1):75-77.
[9]SAIRAM P K S,MARK S,RONNIE M.Accurate and fast method for predicting actual top-of-cement depths in eccentric wellbores[R].SPE126703,2010.
[10]LI X,NOVOTNY R.Study on cement displacement by lattice-boltzmann method[R].SPE102979,2006.
[11]魏淑惠,张长海,陈皖,等.基于计算流体动力学的偏心环空流场数值模拟[J].大庆石油学院学报,2007,31(6):62-64.
[12]王常斌,陈皖,田迪,等.幂律流体偏心环空流场的CFD模拟[J].钻井液与完井液,2009,26(3):62:64.
[13]郑永刚.定向井层流注水泥顶替的机理[J].石油学报,1995,16(4):133-139.
[14]高永海,孙宝江,赵欣欣,等.前置液流变性对顶替界面稳定性影响的数值模拟[J].中国石油大学学报(自然科学版),2007,31(6):51-54.
[15]SAVERY M,DARBE R.Modeling fluid interfaces during cementing using a 3D mud displacement simulator[R].OTC18513,2007.
[16]周仕明,李根生,方春飞.元坝地区146.1mm尾管固井技术难点与对策[J].石油钻探技术,2010,38(4):41-44.
[17]王瑞金,张凯,王刚.Fluent技术基础与应用实例[M].北京:清华大学出版社,2007:46-49.
[18]韩占忠,王敬,兰小平.FLUENT:流体工程仿真计算实例与应用[M].北京:北京理工大学出版社,2004:137-171.
[19]王斌斌,王瑞和,步玉环.不同流态下水泥浆环空顶替的数值模拟研究[J].钻井液与完井液,2010,27(3):76-78.
[20]孙宝江,高永海,刘东清.水泥浆流变性分析及其环空流动的数值模拟[J].水动力学研究与进展,2007,22(3):317-324.
[21]李明忠,王成文,王长权,等.大斜度井偏心环空注水泥顶替数值模拟研究[J].石油钻探技术,2012,40(5):40-44.
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