基于无监督学习技术的碎屑岩储集层成岩相测井识别与应用: 以沾化凹陷三台组为例

doi:10.7605/gdlxb.2025.046

古地理学报 ›› 2025, Vol. 27 ›› Issue (3): 746-762. doi: 10.7605/gdlxb.2025.046

基于无监督学习技术的碎屑岩储集层成岩相测井识别与应用: 以沾化凹陷三台组为例

孟圆¹(), 贾光华², 李传华², 张立强¹(), 张曙光³

1 中国石油大学(华东)地球科学与技术学院,山东青岛 266580
2 中国石化胜利油田分公司油气勘探管理中心,山东东营 257015
3 中国石油渤海钻探工程有限公司,天津 300450

收稿日期:2023-12-18 修回日期:2024-11-05 出版日期:2025-06-01 发布日期:2025-05-29
通讯作者: 张立强,男,1970年生,教授,博士生导师,主要从事油气储层地质学研究。E-mail: liqiangzhangwxm@163.com。
作者简介:
孟圆,女,1999年生,硕士研究生,主要从事成岩相测井解释和机器学习等研究。E-mail: 754586279@qq.com。

Logging identification and application of diagenetic facies of clastic reservoir by unsupervised learning technology: a case study of the Santai Formation in Zhanhua sag,Bohai Bay Basin

MENG Yuan¹(), JIA Guanghua², LI Chuanhua², ZHANG Liqiang¹(), ZHANG Shuguang³

1 School of Geosciences,China University of Petroleum(East China),Shandong Qingdao 266580,China
2 Oil and Gas Exploration Management Center,Sinopec Shengli Oilfield Company,Shandong Dongying 257015,China
3 CNPC Bohai Driling Engineering Company Limited,Tianjin 300450,China

Received:2023-12-18 Revised:2024-11-05 Online:2025-06-01 Published:2025-05-29
Contact: ZHANG Liqiang,born in 1970,is a professor and doctoral supervisor. His main research focus is on oil and gas reservoir geology. E-mail: liqiangzhangwxm@163.com.
About author:
MENG Yuan,born in 1999,is a master's degree candidate. Her primary research interests include diagenetic facies logging interpretation and machine learning. E-mail: 754586279@qq.com.

摘要/Abstract

摘要：

渤海湾盆地济阳坳陷沾化凹陷埕岛—桩海地区侏罗系三台组近年来成为油气勘探重点层系,但受构造演化复杂、沉积类型多样、岩性多变的影响,储集层非均质性极强,储集层质量预测难度大,而成岩相类型的精确识别与划分对储集层的评价起至关重要的作用。传统利用有监督学习识别全井成岩相的方法在学习样本数目较少的情况下实用性有限,本研究开展基于单因素约束的无监督全井成岩相测井识别方法研究。结合视压实率、胶结物含量、面孔率和裂缝率将研究区成岩相划分为致密压实相、碳酸盐胶结相、溶蚀与裂缝相和不稳定成分弱溶蚀相。确定了GR(自然伽马)、AC(声波时差)、DEN(密度)、RD(深侧向电阻率)4条对成岩作用敏感的测井曲线作为成岩相测井识别的依据。分别对4条曲线聚类范围进行约束,确保了无监督学习方法与成岩相良好的映射关系。基于无监督学习划分的测井相种类,利用铸体薄片等资料实现测井相与成岩相的标定,完成地区成岩相的识别与划分。划分结果表明,溶蚀与裂缝相、不稳定成分弱溶蚀相为研究区储集层有利成岩相,2类成岩相对应较高的孔渗度,溶蚀与裂缝主要分布在含砾砂岩等粗粒岩中,不稳定成分弱溶蚀相主要分布在粉砂岩等细粒岩中。通过盲井成岩相对比,验证学习方法的准确性,进而为缺乏取心井段的储集层成岩相识别提出新的预测方法,对有利储集层的评价及预测具有一定意义。

关键词: 济阳坳陷, 沾化凹陷, 三台组, 成岩相测井识别, 单因素约束, 无监督学习

Abstract:

The intricate tectonic evolution,coupled with diverse sedimentary environments and highly variable lithologies,results in strongly heterogeneous reservoirs in the Santai Formation of the Zhanhua sag,making reservoir quality prediction particularly challenging. This highlights the critical importance of accurately identifying and classifying diagenetic facies for effective reservoir evaluation. Traditional supervised learning methods for whole-well diagenetic facies identification are limited by the availability of training samples and thus often impractical in data-scarce scenarios. To address this,an unsupervised learning approach constrained by single-factor analysis is proposed for the logging-based identification of diagenetic facies. By integrating parameters such as apparent compaction rate,cement content,porosity,and fracture density,four diagenetic facies were identified: dense compaction facies,carbonate-cemented facies,dissolution-fracture facies,and weakly dissolved facies with unstable components. Four diagenesis-sensitive logging curves—GR(natural gamma),AC(acoustic travel time),DEN(density),and RD(deep lateral resistivity)—were selected as inputs for the unsupervised clustering algorithm. The clustering ranges of these curves were individually constrained to establish a reliable correlation between logging responses and diagenetic facies. Calibration of logging facies with diagenetic facies was conducted using core data,including thin-section analysis of cast samples,allowing for regional-scale identification and classification of diagenetic facies. The results show that the dissolution-fracture facies and weakly dissolved facies with unstable components represent the most favorable diagenetic facies for reservoir development. These are associated with relatively high porosity and permeability and are mainly distributed in coarse-grained rocks such as conglomeratic sandstones and,while the weakly dissolved facies with unstable components are mainly distributed in fine-grained rocks like siltstone. The accuracy of the proposed method was validated through comparisons with blind wells,demonstrating its effectiveness in non-cored intervals. This approach provides a novel method for predicting reservoir diagenetic facies and offers practical implications for the evaluation and prediction of high-quality reservoir zones in data-limited settings.

Key words: Jiyang Depression, Zhanhua sag, Santai Formation, diagenetic facies logging identification, single factor constraints, unsupervised learning

中图分类号:

TE122.2

孟圆, 贾光华, 李传华, 张立强, 张曙光. 基于无监督学习技术的碎屑岩储集层成岩相测井识别与应用: 以沾化凹陷三台组为例[J]. 古地理学报, 2025, 27(3): 746-762.

MENG Yuan, JIA Guanghua, LI Chuanhua, ZHANG Liqiang, ZHANG Shuguang. Logging identification and application of diagenetic facies of clastic reservoir by unsupervised learning technology: a case study of the Santai Formation in Zhanhua sag,Bohai Bay Basin[J]. Journal of Palaeogeography（Chinese Edition）, 2025, 27(3): 746-762.

http://www.gdlxb.cn/CN/Y2025/V27/I3/746

图/表 23

图1 济阳坳陷沾化凹陷埕岛—桩海地区构造位置(据侯旭波,2010;朱世发等,2022;修改)

Fig.1 Structural locations of Chengdao-Zhuanghai area in Zhanhua sag,Jiyang depression, Bohai Bay Basin(modified from Hou, 2010;Zhu et al., 2022)

图2 沾化凹陷埕岛—桩海地区三台组储集层砂岩岩石类型

Fig.2 Sandstone rock type of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

图3 沾化凹陷埕岛—桩海地区三台组储集层成岩作用类型微观特征 a—Z181井,3033.72 m,颗粒定向排列,单偏光; b—Z181井,3033.72 m,云母压实变形,正交光; c—CB306井,3319.12 m,石英压实破裂,正交光; d—Z181井,3103.2 m,方解石交代石英加大边,不稳定成分溶蚀,单偏光; e—Z181井,3105.65 m,方解石充填孔隙、石英加大边单偏光,单偏光; f—Z181井,3105.54 m,颗粒几乎完全被方解石交代,单偏光; g—CB306井,3229.18 m,高岭石胶结,扫描电镜; h—CB306井,3319.97 m,晶粒镶嵌型白云石胶结,正交光; i—CB306井,3320.27 m,长石溶蚀,单偏光; j—CB306井,3320.27 m,石英溶蚀, 单偏光; k—CB306井, 3319 m, 在强溶蚀作用下次生孔隙大量发育, 单偏光; l—CB38井, 3537.6 m, 构造应力产生裂缝, 单偏光

Fig.3 Microscopic characteristics of diagenesis types of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

图4 沾化凹陷埕岛—桩海地区三台组储集层成岩演化序列(埋藏史-热史据侯旭波,2010;修改)

Fig.4 Diagenetic evolution sequence of the Santai Formation reservoir in Chengdao-Zhuanghai area, Zhanhua sag(buried history-thermal history modified from Hou, 2010)

图5 沾化凹陷埕岛—桩海地区三台组储集层成岩相微观特征 a—CB38井,3538.49 m,致密压实相,单偏光; b—Z181井,3019.8 m,致密压实相,单偏光; c—Z181井,3105.65 m,碳酸盐胶结相,单偏光; d—CB306井,3316 m,溶蚀与裂缝相,单偏光; e—3320.27 m,溶蚀与裂缝相,单偏光; f—Z181井,3096.42 m,不稳定成分弱溶蚀相,单偏光

Fig.5 Microscopic characteristics of diagenetic facies of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

表1 沾化凹陷埕岛—桩海地区三台组储集层成岩相划分标准

Table1 Standard of diagenetic facies classification of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

成岩相类型	视压实率 /%	胶结物含量 /%	面孔率 /%	裂缝率 /%
致密压实相	>65	<10	<5	<0.5
碳酸盐胶结相	<65	25~30	<5	<0.5
不稳定成分弱溶蚀相	<65	5~10	15~20	<0.5
溶蚀与裂缝相	65~75	2~5	8~30	0.5~1.1

表2 沾化凹陷埕岛-桩海地区三台组储集层成岩相对应测井数据统计

Table2 Statistics of logging data corresponding to diagenesis facies of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

成岩相类型	GR/API	AC/μs·ft^-1	DEN/g·cm^-3	CNL/%	RD/Ω·m
致密压实相	77.5~107.7(89.09)	66.8~74.4(68.36)	1.98~2.61(2.31)	4.3~12.9(6.65)	2.06~5.42(4.45)
碳酸盐胶结相	38.79~79.97(43.03)	68.96~78.83(77.26)	1.92~2.56(2.35)	11.07~14.8(12.09)	12.4~19.56(16.4)
不稳定成分弱溶蚀相	47.24~57.63(53.14)	80.07~85.59(83.14)	1.96~2.25(2.15)	18.49~20.2(19.42)	11.02~13.29(12.6)
溶蚀与裂缝相	51.453~72(60.7)	65.81~78.85(75.94)	2.32~2.24(2.26)	13.64~22.4(17.02)	3.4~15.59(12.69)

图6 沾化凹陷埕岛—桩海地区三台组储集层测井曲线相关性分析

Fig.6 Correlation analysis of logging curves of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

图7 沾化凹陷埕岛—桩海地区Z181井三台组致密压实相储集层测井响应与微观特征

Fig.7 Logging response and microscopic characteristics of tight compaction facies reservoir of Well Z181 in Chengdao-Zhuanghai area,Zhanhua sag

图8 沾化凹陷埕岛—桩海地区Z181井三台组碳酸盐胶结相储集层测井响应与微观特征

Fig.8 Logging response and microscopic characteristics of carbonate cementation facies reservoir of Well Z181 in Chengdao-Zhuanghai area,Zhanhua sag

图9 沾化凹陷埕岛—桩海地区CB306井三台组溶蚀与裂缝相储集层对应测井曲线特征与微观特征

Fig.9 Logging response and microscopic characteristics of dissolution and fracture phase facies reservoir of Well CB306 in Chengdao-Zhuanghai area,Zhanhua sag

图10 沾化凹陷埕岛—桩海地区Z181井三台组不稳定成分弱溶蚀相储集层对应测井曲线特征与微观特征

Fig.10 Logging response and microscopic characteristics of unstable component weak dissolution facies reservoir of Well Z181 in Chengdao-Zhuanghai area,Zhanhua sag

图11 沾化凹陷埕岛—桩海地区三台组储集层有监督学习方法成岩相预测结果 a—随机森林成岩相测井识别结果; b—XGboost成岩相测井识别结果; c—BP神经网络成岩相测井识别结果

Fig.11 Prediction result of diagenetic facies by supervised learning method of the Santai Formation in Chengdao-Zhuanghai area,Zhanhua sag

图12 K-means聚类算法原理(据张浩,2023;修改)

Fig.12 Principle of K-means clustering algorithm(modified from Zhang,2023)

图13 测井相划分原理

Fig.13 Principle of logging phase division

图14 利用GR-AC、DEN-RD交会图合并相近种类示意图 a—各分类GR-AC、DEN-RD交会图(图中数值均为标准化以后的数值);b—将聚类相近种类合并后交会图(图中数值均为标准化以后的数值)

Fig.14 Schematic diagrams of using GR-AC and DEN-RD crossplots to merge similar types

图15 分类合并方法示意图

Fig.15 Schematic diagram of classification merging method

表3 沾化凹陷埕岛—桩海地区三台组储集层测井曲线特征与成岩相标定关系

Table3 Relationship between logging curve characteristics and diagenetic facies of the Santai Formation reservoir in Chengdao-Zhuanghai area,Zhanhua sag

测井曲线特征				成岩相类型
GR	AC	DEN	RD	成岩相类型
中高	中低	3种等级均有分布	3种等级均有分布	致密压实相
中低	中低	中高	中高	碳酸盐胶结相
低	中高	中	3种等级均有分布	不稳定成分弱溶蚀相
中低	中低	中低	3种等级均有分布	溶蚀与裂缝相

图16 沾化凹陷埕岛—桩海地区三台组储集层单因素约束的无监督学习方法预测结果

Fig.16 Reservoir prediction result of unsupervised learning method with single factor constraint of the Santai Formation in Chengdao-Zhuanghai area,Zhanhua sag

图17 沾化凹陷埕岛—桩海地区CB306井成岩相测井识别结果对比

Fig.17 Comparison of logging identification results of diagenetic facies in Well CB306 in Chengdao-Zhuanghai area,Zhanhua sag

图18 沾化凹陷埕岛—桩海地区Z181井成岩相测井识别结果对比

Fig.18 Comparison of logging identification results of diagenetic facies in Well Z181 in Chengdao-Zhuanghai area,Zhanhua sag

图19 沾化凹陷埕岛—桩海地区CBG7井成岩相测井识别结果对比

Fig.19 Comparison of logging identification results of diagenetic facies in Well CBG7 in Chengdao-Zhuanghai area,Zhanhua sag

图20 沾化凹陷埕岛—桩海地区CBG7井成岩相孔隙度和渗透率交会图

Fig.20 Crossplot of porosity and permeability of diagenetic facies in Well CBG7 in Chengdao-Zhuanghai area,Zhanhua sag

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