吉林大学学报(地球科学版)

• 地球探测与信息技术 • 上一篇    

古龙南地区低阻油层胶结指数和饱和度指数影响因素实验

宋延杰1,2,姜艳娇1,2,宋杨3,张依妮3   

  1. 1.东北石油大学地球科学学院,黑龙江 大庆163318;
    2.非常规油气成藏与开发省部共建国家重点实验室培育基地,黑龙江 大庆163318;
    3.中油辽河工程有限公司,辽宁 盘锦124010
  • 收稿日期:2013-07-21 出版日期:2014-03-26 发布日期:2014-03-26
  • 作者简介:宋延杰(1963-),男,教授,博士,主要从事测井方法与资料解释研究,E-mail:syj1963@263.net
  • 基金资助:

    国家自然科学基金项目(41274110)

Experimental on the Influencing Factors of m and n of Low Resistivity Oil Reservoirs in Southern Gulong Area

Song Yanjie1,2, Jiang Yanjiao1,2, Song Yang3, Zhang Yini3   

  1. 1.College of Earth Sciences, Northeast Petroleum University, Daqing163318, Heilongjiang, China;
    2.Accumulation and Development of Unconventional Oil and Gas,State Key Laboratory Cultivation Base Jointly-Constructed by Heilongjiang Province and the Ministry of Science and Technology,Daqing163318,Heilongjiang,China;
    3.China Liaohe Petroleum Engineering Co. ,Ltd.,Panjin124010,Liaoning,China
  • Received:2013-07-21 Online:2014-03-26 Published:2014-03-26

摘要:

采用变胶结指数m和饱和度指数n的阿尔奇公式仍是目前定量评价低阻油层饱和度的主要方法之一。然而,由于不同地区低阻油层的成因不同,从而使得低阻油层mn的影响因素随地区不同而发生变化。因此,针对不同地区低阻油层,有必要研究其阿尔奇公式mn的影响因素及变化规律。依据古龙南地区葡萄花低电阻率油层划分标准以及考虑岩性、物性、电性变化,选取了低阻油层岩样,设计了岩样岩石物理实验。基于岩石物理实验数据,绘制mn与物性参数、孔隙结构参数、黏土附加导电能力参数的交会图。经分析可知:低阻油层的mn值小于常规油层的mn值,并随孔渗综合指数、中值半径、平均半径、半径均值的增大而增大。低阻油层的m值随泥质体积分数、阳离子交换容量、微孔隙体积与可动流体体积之比的增大而减小,随核磁共振测量的T2几何平均值的增加而增大;n值随孔隙度、孔隙度和泥质体积分数比值的增加而增大。低阻油层的m值与T2几何平均值、微孔隙体积与可动流体体积之比关系较好,n值与孔渗综合指数、平均半径、最大半径、半径均值的相关性非常好。研究表明,低阻油层的m值受孔隙结构和泥的影响较大,而n受孔隙结构影响较大。可用T2几何平均值或微孔隙体积与可动流体体积之比确定低阻油层的m值,可用孔渗综合指数、平均半径、最大半径、半径均值确定低阻油层的n值。

关键词: 低阻油层, 胶结指数, 饱和度指数, 岩石物理实验, 孔隙结构参数

Abstract:

At present, Archie’s formula with variable cementation exponent(m) and saturation exponent(n) is still applied in quantitative evaluation of saturation of low resistivity oil reservoirs as one of the main methods. However, the influencing factors of m and n in low resistivity oil reservoirs are varied with area due to the different causes of low resistivity oil reservoirs. Therefore, the study on influencing factors and variation laws of m and n in Archie’s formula in low resistivity oil reservoirs in different areas is necessary. Samples of low resistivity oil reservoirs are cored in Putaohua Formation of southern Golong area according to division standard of low resistivity oil reservoirs, and also have definite variation of lithology, physical property, electric property. Then, petrophysical experiment of one sample is designed. A plot of m and n with parameters of petrophysics, pore structure, excess clay conductivity is made from petrophysical experiment data. The analysis shows that the values of m and n in low resistivity oil reservoirs is less than those of m and n in conventional oil reservoirs, and m and n in low resistivity oil reservoirs increase as porosity and permeability composite index, median radius, mean radius, radius mean increase. The m of low resistivity oil reservoirs decreases as shale volume fraction, cation exchange capacity, the ratio of micropore volume and movable fluid volume increase, and increases as T2 geometric mean value increases, while the n of low resistivity oil reservoirs increases as porosity, the ratio of porosity and shale volume fraction increase. The m has a good correlation with T2 geometric mean value, the ratio of micropore volume and movable fluid volume in low resistivity oil reservoirs, while the n has an excellent correlation with porosity and permeability composite index, mean radius, maximum radius, radius mean. The result reveals that pore structure has a larger effect on m and n of low resistivity oil reservoirs, and also shale volume fraction has a larger effect on m of low resistivity oil reservoirs, and T2 geometric mean value or the ratio of micropore volume and movable fluid volume can be used to determine the mof low resistivity oil reservoirs, and porosity and permeability composite index, average radius, maximum radius, radius mean can be used to determine the n of low resistivity oil reservoirs.

Key words: low resistivity oil reservoirs, cementation exponent, saturation exponent, petrophysical experiment, pore structure parameters

中图分类号: 

  • P631.8
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