变系数ΔlogR方法及其在泥页岩有机质评价中的应用

doi:10.6038/pg20140144

地球物理学进展 ›› 2014, Vol. 29 ›› Issue (1): 312-317.doi: 10.6038/pg20140144

变系数ΔlogR方法及其在泥页岩有机质评价中的应用

刘超^1,2, 卢双舫³, 薛海涛³

1. 东北石油大学地球科学学院, 大庆 163318;
2. 大庆油田有限责任公司勘探开发研究院, 大庆 163712;
3. 中国石油大学(华东)非常规油气研究院, 青岛 266580

收稿日期:2013-06-11 修回日期:2013-11-12 出版日期:2014-02-20 发布日期:2014-02-20
作者简介:刘超，男，1985年生，吉林省人，博士研究生，从事石油地质及油气地球化学研究工作.（E-mail：lcyxdz@163.com）
基金资助:
国家973项目（2011CB211701）、中石油科技创新基金（2011D-5006-0101）和黑龙江省普通高等学校新世纪优秀人才培养计划（1252-NCET-012）联合资助.

Variable-coefficient ΔlogR model and its application in shale organic evaluation

LIU Chao^1,2, LU Shuang-fang³, XUE Hai-tao³

1. College of Earth Sciences, Northeast Petroleum University, Daqing 163318, China;
2. Exploration and Development Research Institute, Daqing Oilfield Corp.Ltd., Daqing 163712, China;
3. Institute of Unconventional Oil and Gas and New Energy, China University of Petroluem, Qingdao 266555, China

Received:2013-06-11 Revised:2013-11-12 Online:2014-02-20 Published:2014-02-20

摘要/Abstract

摘要： 为提高ΔlogR方法对陆相地层有机质评价的适应性，通过修改模型系数、引入新的测井参数，提出变系数的ΔlogR方法.研究发现， ΔlogR方法中孔隙度曲线和电阻率曲线间的比例系数与预测结果误差密切相关，将其视为变量并合理地确定其值能明显减少预测误差；有机质具有低波阻抗的特点，对重矿物欠发育地层，利用波阻抗信息和电测信息可以很好地评价有机质含量.将变系数ΔlogR方法应用于罗69井TOC和氯仿沥青“A”评价，应用结果表明，变系数ΔlogR方法有利于减少TOC的预测误差，也适合对氯仿沥青“A”评价， TOC对应的比例系数“K_TOC”小于氯仿沥青“A”对应比例系数“K_A”， TOC 预测相对误差小于氯仿沥青“A”相对误差，与理论分析相符.变系数ΔlogR方法为评价泥页岩残余烃（油）量提供了新的参考方法.

Abstract: Some problems which have made the evaluation results less reliable or even led to wrong conclusions arised when ΔlogR model is used to evaluate organic content of shales, especially shales from continental basins, because of differences, such as mineral composition and content et al between continental shales and marine shales.In this article, we mainly deal with the way that can help improve the applicability and accuracy of model in the evaluation of shale heterogeneities.As a result, variable-coefficient ΔlogR model is put forward by modifying “K” value, adding new logging curves et al then TOC and chloroform asphalt “A” is evaluated respectively based on datas form well Luo 69.It is concluded that reasonable “K” between porosity curve and resistivity curve is the comprehensive result of porosity, kerogen and hydrocarbon content, more importantly, “K” value and prediction error is closely related；Instead of the old manually way, a new method which takes advantage of curve shape, lithology information and can help get the baseline value quickly by using computer to do it automatically is proposed.Density log which can help provide more information in most cases is used in Variable-coefficient ΔlogR model in view of source rocks, especially high-quality source rocks, have lower wave impedance.The case of well Luo 69 shows that Variable-coefficient ΔlogR model is good for TOC evaluation and can also be a feasible method for chloroform asphalt “A” evaluating, meanwhile TOC usually corresponds to lower “K” and higher precision than chloroform asphalt “A”.Variable-coefficient ΔlogR model has provided a new way for the evaluation of residual hydrocarbon content in shales.

中图分类号:

P631

刘超, 卢双舫, 薛海涛. 2014. 变系数ΔlogR方法及其在泥页岩有机质评价中的应用. 地球物理学进展, 29(1): 312-317. doi: 10.6038/pg20140144 .

LIU Chao, LU Shuang-fang, XUE Hai-tao. 2014. Variable-coefficient ΔlogR model and its application in shale organic evaluation. Progress in Geophysics. 29(1): 312-317. doi: 10.6038/pg20140144 .

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: http://www.progeophys.cn/CN/10.6038/pg20140144

http://www.progeophys.cn/CN/Y2014/V29/I1/312

参考文献

Curtis J B.2002. Fractured shale-gas systems[J]. AAPG Bulletin, 86(11): 1921-1938.
Guo Z Q, Sun P, Liu W H.2012. The carbon calculation by ΔlogR technology in Sanhu area of Qaidam basin[J]. Progress in Geophysics (in Chinese), 27(2): 626-633.
He J L, Deng S W, Chen W L, et al.2006. Evaluation of oil shale in the southern Songliao basin using logging techniques[J]. Journal of Jilin University (Earth Science Edition) (in Chinese), 36(6): 909-914.
Hu H T, Lu S F, Liu C, et al.2011. Models for calculating organic carbon content from logging information: Comparison and analysis[J]. Acta Sedimentologica Sinica (in Chinese), 29(6): 1199-1205.
Hao J F, Zhou C C, Li X, et al.2012. Summary of shale gas evaluation applying geophysical logging[J]. Progress in Geophysics (in Chinese), 27(4): 1624-1632.
Li D H, Li J Z, Wang S J, et al.2009. Analysis of controls on gas shale reservoirs[J]. Natural Gas Industry (in Chinese), 29(5): 22-26.
Li L, Liu B, Li X S, et al.2010. Application of multi-attribute prediction to the Weixinan depression dominate source rock[J]. Progress in Geophysics (in Chinese), 25(5): 1737-1743.
Liu C, Lu S F, Huang W B, et al.2011. Improvement of ΔLogr and its application in source rocks evaluation[J]. Petroleum Geology & Oilfield Development in Daqing (in Chinese), 30(3): 27-31.
Liu C.2011. Evaluating source rock using logging data-Improvement and application[D]. Daqing: Northeast Petroleum University (in Chinese), 15-21.
Magara K.1978. Compaction and Fluid Migration. New York: Elsevier Scientific, 319.
Miao G W, Liu C, Wang D, et al.2011. The application of impedance inversion for characteristics analysis and reservoir prediction in Jilin coalfield[J]. Progress in Geophysics (in Chinese), 26(5): 1788-1795.
Passey Q R, Creaney S, Kulla J B, et al.1990. A practical model for organic richness from porosity and resistivity logs[J]. AAPG Bulletin, 74(12): 1777-1794.
Teng G E, Jiang Q G, Tao C, et al.2010. Research progress, challenge and prospect of the source rocks in China[J]. Sino-Global Energy (in Chinese), 15(12): 37-51.
Tang L N.2011. Well logging evaluation of source rock and its application in Bohai bay oil exploitation[J]. Science & Technology (in Chinese), 29(21): 51-54.
Tan M J, Zhang S Y.2010. Progress in geophysical logging technology for shale gas researvoirs[J]. Progress in Geophysics (in Chinese), 25(6): 2024-2030.
Tang H F, Li R L, Wu Y H, et al.2011. Textural characteristics of volcanic strata and its constraint to impedance inversion[J]. Chinese J. Geophys. (in Chinese), 54(2): 620-627.
Wang S D, Wang B.2012. Time-lapse Bayesian AVO waveform inversion[J]. Chinese J. Geophys. (in Chinese), 55(7): 2422-2431.
Yang Y M, Mao J L, Li J J.2012. Shale gas reservoir characteristics and geological evaluation of prospective areas: A case study with the Eastern Uplift of Liaohe depression[J]. Special Oil and Gas Reservoir (in Chinese), 19(2): 46-49.
Yu X T.2009. Application of well logging technology to source rocks evaluation[J]. Journal of Yangtze University (Natural Science Edition) (in Chinese), 6(2): 198-200.
Yan J P, Cai J G, Zhao M H, et al.2009. Advances in the study of source rock evaluation by geophysical logging and its significance in resource assessment[J]. Progress in Geophysics (in Chinese), 24(1): 270-279.
Zhang P X.2012. Shale gas logging evaluation-a case study of marine strata in south eastern Sichuan[J]. Special Oil and Gas Reservoir (in Chinese), 19(2): 12-15.
Zhang J C, Jin Z J, Yuan M S.2004. Reservoiring mechanism of shale gas and it’s distribution[J]. Natural Gas Industry (in Chinese), 24(7): 15-18.
Zou C N, Zhu R K, Bai B, et al.2011. First discovery of nano-pore throat in oil and gas reservoir in China and its scientific value[J]. Acta Petrologica Sinica (in Chinese), 27(6): 1857-1864.
Zhu Z Y, Wang G W, Zhu G Y.2002. The application of artificial neural network to the source rock’s evaluation[J]. Progress in Geophysics (in Chinese), 17(1): 137-140.
Zhu Z Y, Liu H, Li Y M.2003. The analysis and application of ΔlogR method in the source rock's identification[J]. Progress in Geophysics (in Chinese), 18(4): 647-649.
Zhang Y M, Zhang S F, Qi L.2008. Sandstone porosity inversion based on seismic data[J]. Geophysical Prospecting for Petroleum (in Chinese), 47(2): 136-140.

[1]	屈念念,李家斌,张西君,刘俊. 基于重磁资料研究贵州省深部构造特征[J]. 地球物理学进展, 2019, 34(5): 1785-1793.
[2]	安鹏,曹丹平,赵宝银,杨晓利,张明. 基于LSTM循环神经网络的储层物性参数预测方法研究[J]. 地球物理学进展, 2019, 34(5): 1849-1858.
[3]	陈稳,薛国强,陈卫营,周楠楠,卢云飞. SOTEM多分量激电响应特性分析[J]. 地球物理学进展, 2019, 34(5): 1859-1865.
[4]	豆辉,徐逸鹤. 黏性逆时偏移成像研究进展[J]. 地球物理学进展, 2019, 34(5): 1866-1877.
[5]	毛庆辉,王鹏,曾隽. 水力压裂微地震事件定位方法综述[J]. 地球物理学进展, 2019, 34(5): 1878-1886.
[6]	尚新民,王延光,崔庆辉,金昌昆,赵翠霞,滕厚华,赵胜天. 准南缘山前带精细近地表建模技术研究[J]. 地球物理学进展, 2019, 34(5): 1887-1892.
[7]	石战战,夏艳晴,王元君,周怀来,庞溯,池跃龙. 基于L₁-L₁范数稀疏表示的共偏移距道集地震数据重建方法[J]. 地球物理学进展, 2019, 34(5): 1893-1899.
[8]	王迪,陈敏,王健伟,盛志超,严曙梅,马美媛,李东哲,郑欣. 基于T₂和毛管压力分类转换的渗透率计算新方法[J]. 地球物理学进展, 2019, 34(5): 1900-1909.
[9]	王海波,张伟,张宏,肖虎,高云路,顾剑华,唐美斌,韩峰. 高精度可控震源在深反射地震采集中的应用[J]. 地球物理学进展, 2019, 34(5): 1910-1916.
[10]	王静, 张军华, 王延光, 杨勇, 冯德永, 武刚, 黄德峰. 特征值相干理论诠释及效果比较[J]. 地球物理学进展, 2019, 34(5): 1917-1923.
[11]	王维红,包培楠,陈国飞,林弘喆. 基于最小平方的横波速度拟合及应用[J]. 地球物理学进展, 2019, 34(5): 1924-1929.
[12]	王亚,王孟华,田建章,王成泉,彭玲丽,冯小英,周兴海,张浩. 一种适用于深潜山及内幕的有效储层地震预测方法——以廊固凹陷杨税务潜山为例[J]. 地球物理学进展, 2019, 34(5): 1930-1937.
[13]	吴曲波,潘自强,陈金勇,Mubarak,Hani. 利用瞬态瑞雷面波法探测浅层玄武岩三维分布——以沙特Sabkhah Ad Dumathah地区为例[J]. 地球物理学进展, 2019, 34(5): 1938-1944.
[14]	严小丽,康慧敏,王光杰,何国丽,李红领. AMT方法在鳌山卫花岗岩地区深部地热构造勘探中的应用[J]. 地球物理学进展, 2019, 34(5): 1945-1953.
[15]	尹奇峰,潘冬明,郭全仕,何情. 基于快速模拟退火算法的井中微地震事件定位反演[J]. 地球物理学进展, 2019, 34(5): 1954-1961.

变系数ΔlogR方法及其在泥页岩有机质评价中的应用

Variable-coefficient ΔlogR model and its application in shale organic evaluation

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

多维度评价

本文评价