塔里木盆地顺北油气田断控缝洞型储集体高产井目标优选

高利君; 李海英; 龚伟; 杨威; 李弘艳

doi:10.11781/sysydz2025030479

塔里木盆地顺北油气田断控缝洞型储集体高产井目标优选

doi: 10.11781/sysydz2025030479

高利君^{1, 2,},
李海英³,
龚伟²,
杨威²,
李弘艳²

1.
中国石油大学地球科学与技术学院, 山东青岛 266580
2.
中国石化西北油田分公司勘探开发研究院, 乌鲁木齐 830011
3.
中国石化西北油田分公司, 乌鲁木齐 830011

基金项目:

中国石化科技部项目“超深—特深层碳酸盐岩圈闭识别描述与评价技术研究” P24009

详细信息

作者简介:
高利君(1988—)，男，博士，副研究员，从事碳酸盐岩断控缝洞型储层预测研究。E-mail: gaolij.xbsj@sinopec.com

中图分类号: TE321
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出版历程
- 收稿日期: 2024-10-21
- 修回日期: 2025-04-06
- 刊出日期: 2025-05-28

Optimal selection of high-production well targets for fault-controlled fractured-vuggy reservoir in Shunbei oil and gas field, Tarim Basin

1.
School of Geosciences, China University of Petroleum (East China), Qingdao, Shandong 266580, China
2.
Exploration and Development Research Institute, SINOPEC Northwest Oilfield Branch Company, Urumqi, Xinjiang 830011, China
3.
SINOPEC Northwest Oilfield Branch Company, Urumqi, Xinjiang 830011, China

摘要

摘要: 塔里木盆地顺北油气田经过多年勘探开发，形成了适用于1号带和5号带的超深断控缝洞体目标预测评价与井位设计系列技术。随着油气田勘探对象从1号和5号主干断裂带逐步转向东部北东向和西部北西向断裂带，其地下地质条件更加复杂，勘探成本大幅度提升。现有储集体描述、目标优选及井轨迹设计技术已无法满足超深断控缝洞体精细描述和高产井轨迹优化设计需求。通过对比分析不同区域、不同样式走滑断裂带内部结构特征和地震响应特征差异，结合实钻井井震标定统计和模型正演分析，建立了“通源断裂+串珠+纵深杂乱强背景”的高产稳产井地震识别模式，为储层预测和目标优选提供了依据；通过攻关形成的Q补偿地震资料解释性处理技术提高了沙漠区低信噪比资料中断控缝洞体的成像精度，在此基础上建立了以“相控反演”为核心的储集体量化雕刻和靶点空间定位技术，提高了断控储集体描述精度和靶点优选的精准性；针对顺北地区上覆地层和奥陶系目的层复杂的地质条件以及钻井过程面临的漏失、溢流和井壁垮塌等难题，建立了一套以钻井风险预测为主的地质工程一体化关键技术流程，形成井轨迹优化、井口优选、钻前地层压力预测及井壁稳定性预测方法，提高了钻井安全性和作业效率。顺北4号带和8号带钻探结果表明，断控储集体高产井目标优选设计技术能够精准预测超深非均质性缝洞体目标，指导和优化钻井轨迹设计，规避和减少钻井路径上各类工程风险，提高规模储集体钻遇率和高产井建产率。
- 地震识别模式 /
- 相控反演 /
- 地质工程一体化 /
- 断控储集体 /
- 顺北油气田 /
- 塔里木盆地
Abstract: After years of exploration and development in the Shunbei oil and gas field, Tarim Basin, a series of technologies for ultra-deep fault-controlled fractured-vuggy target prediction, evaluation, and well location design have been formed, applicable to the No.1 and No.5 fault zones. As exploration efforts shift from the main No.1 and No.5 fault zones to the northeastern and northwestern fault zones in the eastern and western regions, the underground geological conditions become more complex, and exploration costs rise significantly. Existing reservoir characterization, target selection, and well trajectory design technologies are inadequate for the precise delineation of ultra-deep fault-controlled fractured-vuggy systems and high-yield well trajectory optimization. Through comparative analysis of the internal structural characteristics and seismic response variations of different regions and different types of strike-slip fault zones, integrated with actual well seismic calibration statistics and forward modeling, this study established a robust seismic identification model for high-yield and stable production wells. This model, based on the "source-connected faults + bead-string + deep chaotic high-amplitude background", provided a systematic framework for reservoir prediction and target selection. The Q-compensation seismic data processing technology developed through research improved the imaging resolution of fault-controlled fractured-vuggy systems in low signal-to-noise ratio seismic data under desert environments. Based on this, a reservoir quantification sculpting and target spatial positioning technology, centered on "facies-constrained inversion, " was established, which improved the accuracy of fault-controlled reservoir description and the precision of target selection. In response to the complex geological conditions of the overlying strata and Ordovician target layers in the Shunbei area, as well as challenges such as loss, overflow, and wellbore collapse during drilling, a key integrated geological engineering technology process focused on drilling risk prediction was established. This process included methods for optimizing well trajectories, selecting well locations, predicting formation pressures before drilling, and predicting wellbore stability, which improved drilling safety and efficiency. Drilling results from Shunbei's No. 4 and No. 8 fault zones indicated that the target selection and design technology for fault-controlled reservoirs could accurately identify and predict ultra-deep heterogeneous fractured-vuggy body targets, guide and optimize drilling trajectory design, avoid and reduce engineering risks along the drilling path, and improve the drilling success rate and high-yield well construction rate for large-scale reservoirs.
- seismic identification mode /
- facies-constrained inversion /
- geological and engineering integration /
- fault-controlled reservoir /
- Shunbei oil and gas field /
- Tarim Basin
注释:

利益冲突声明/Conflict of Interests

所有作者声明不存在利益冲突。

All authors declare no relevant conflict of interests.

作者贡献/Authors'Contributions

本文由高利君负责写作与修改；李海英负责完成地质工程一体化效果评价工作；龚伟负责完成井轨迹优化工作；杨威负责完成Q补偿地震增强分析工作；李弘艳负责完成反演结果分析工作。所有作者均阅读并同意最终稿件的提交。

This article was written and revised by GAO Lijun. LI Haiying was responsible for the geological and engineering integration effectiveness evaluation. GONG Wei handled well trajectory optimization. YANG Wei conducted Q-compensation seismic enhancement analysis. LI Hongyan performed inversion result analysis. All authors have read the final version of the paper and consented to its submission.

HTML全文

图 1 塔里木盆地顺北地区断控储集体典型地质模型示意图

Figure 1. Geological model of fault-controlled fractured-vuggy reservoirs in Shunbei area, Tarim Basin

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图 2 Q补偿处理前后地震剖面对比

Figure 2. Comparison of pre- and post-Q-compensation seismic profiles

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图 3 塔里木盆地顺北地区断控缝洞储集体边界

Figure 3. Delineated boundaries of fault-controlled fractured-vuggy reservoirs in Shunbei area, Tarim Basin

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图 4 塔里木盆地顺北油气田断控缝洞储集体不同类型储层地震属性

Figure 4. Seismic attribute characterization of different reservoir types in fault-controlled fractured-vuggy reservoirs in Shunbei oil and gas field, Tarim Basin

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图 5 塔里木盆地顺北4号带中段由南至北过井轨迹方向连井对比

Figure 5. Well correlation profile from south to north along the well trajectories in central Shunbei Zone 4, Tarim Basin

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图 6 塔里木盆地顺北油气田断控缝洞储集体三维空间雕刻与井轨迹

Figure 6. 3D spatial sculpting of fault-controlled fractured-vuggy reservoirs with well trajectory mapping in Shunbei oil and gas field, Tarim Basin

下载: 全尺寸图片幻灯片

图 7 塔里木盆地顺北油气田上覆地层钻井风险预测与井口优化示意图

Figure 7. Drilling risk prediction and wellhead optimization in overlying strata of Shunbei oil and gas field, Tarim Basin

下载: 全尺寸图片幻灯片

图 8 塔里木盆地顺北A3井区地震剖面、相控反演剖面及三维雕刻图

Figure 8. Seismic profile, facies-constrained inversion profile, and 3D sculpting map of A3 well area in Shunbei oil and gas field, Tarim Basin

下载: 全尺寸图片幻灯片

表 1 塔里木盆地顺北地区上覆地层复杂地质因素预测吻合率统计

Table 1. Statistics on prediction matching rate of complex geological factors in overlying strata of Shunbei oil and gas field, Tarim Basin

类别	年份	预测井数	吻合井数	吻合率/%
二叠系火成岩	2023	32	25	78
二叠系火成岩	2024	27	23	85
志留系漏失	2023	32	9	28
志留系漏失	2024	27	17	63
侵入岩	2023	32	11	34
侵入岩	2024	27	17	63

下载: 导出CSV

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