基于化学动力学的地层硫酸钡结垢模型研究

doi:10.11885/j.issn.1674-5086.2014.01.08.04

西南石油大学学报(自然科学版)

基于化学动力学的地层硫酸钡结垢模型研究

李洪建1 *，陈满1，石祥超1，唐鑫2，王德玉2

1. 西南石油大学石油与天然气工程学院，四川成都610500
2. 中国石油长庆油田分公司第六采油厂，陕西西安710018

出版日期:2016-08-01 发布日期:2016-08-01
通讯作者: 李洪建，E-mail：lhj63@263.net

Study on Barium Sulfate Scale Model Based on Chemical Kinetics

LI Hongjian1*, CHEN Man1, SHI Xiangchao1, TANG Xin2, WANG Deyu2

1. School of Petroleum and Natural Gas Engineerring，Southwest Petroleum University，Chengdu，Sichuan 610500，China
2. The Sixth Oil Recovery Plant of Changqing Oilfield Company，PetroChina，Xi′ an，Shaanxi 710018，China

Online:2016-08-01 Published:2016-08-01

摘要/Abstract

摘要：

成垢离子在地层中发生沉淀反应的规律与普通水溶液中的不尽相同。多孔介质渗流过程中的扩散与沉淀反
应的反应系数需要通过岩芯流动实验中所测得的出口端钡离子浓度拟合得到。在已有的岩芯结垢模型与地层结垢模
型求解方法中，需要分别假设入口端与近井地带边界处的钡离子与硫酸根离子的浓度比远小于1，这一假设使模型有
很大的局限性。采用罗巴托与牛顿法求解岩芯结垢模型，取消了关于离子浓度比的假设；并详细推导了地层结垢模
型，修正了控制方程中的二阶项系数，研究了低硫酸根离子浓度的海水作为注入水的情况下，不同无因次扩散系数，无
因次化学反应系数，边界浓度比对地层结垢模型中阻力系数的影响。结果表明，采用低硫酸根离子浓度注入水降低边
界离子浓度比，阻力系数将大大降低；若离子浓度比与无因次反应系数降低相同的百分比，前者将导致更大的阻力系
数减幅。

关键词: 油田注水, 硫酸钡, 离子浓度比, 结垢模型, 阻力系数

Abstract:

Reaction of ions in porous media were not the same as in common water solution Diffusion and reaction coefficients
in porous media had to be calculated by fitting core scale model with measured outlet barium concentration in core flooding
test. The original solvers of both core and formation scale model made the assumptions that barium and sulfate ion ratio should
be far less than 1，which largely restricted the model′s application. By using Lobatto and Newton methods to solve core scale
model without the assumption upon ion ratio we obtained the formation scale model，and modified the coefficient of second
order term in the control equation. We also studied the effects of different dimensionless diffusion coefficients，dimensionless
reaction coefficients and influence of ion ratios on impedance coefficient of formation scale model when injecting low sulfate
seawater. The results showed that low sulfate seawater could greatly lower the ion ratio and would decrease the impedance
coefficient greatly，and that with the same percentage of decrease in ion ratio and dimensionless reaction coefficient，the former
would result in greater reduction of impedance coefficient.

Key words: water flooding, barium sulfate, ion ratio, scale model, impedance coefficient

中图分类号:

TE319

李洪建1 *，陈满1，石祥超1，唐鑫2，王德玉2. 基于化学动力学的地层硫酸钡结垢模型研究[J]. 西南石油大学学报(自然科学版), DOI: 10.11885/j.issn.1674-5086.2014.01.08.04.

LI Hongjian1*, CHEN Man1, SHI Xiangchao1, TANG Xin2, WANG Deyu2. Study on Barium Sulfate Scale Model Based on Chemical Kinetics[J]. 西南石油大学学报(自然科学版), DOI: 10.11885/j.issn.1674-5086.2014.01.08.04.

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基于化学动力学的地层硫酸钡结垢模型研究

Study on Barium Sulfate Scale Model Based on Chemical Kinetics

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