玛湖凹陷风城组薄互层分层压裂优化方法

doi:10.7657/XJPG20220214

摘要/Abstract

摘要：

玛湖凹陷石油地质储量大,二叠系风城组储集层厚度大,油气显示佳,但薄互层岩性组合复杂,地应力变化大,需要精细分层压裂实现储量充分动用。基于数值模拟方法,研究多段储集层合压时压裂裂缝扩展的影响因素,为储集层压裂方案的选择提供依据。结果表明：储集层应力差对压裂裂缝扩展的影响最大,压裂液排量和黏度次之,储集层厚度比影响最小。基于BP神经网络算法,对数值模拟结果开展机器学习,建立了综合考虑地质和工程因素的多因素精细分压决策模型。采用该决策模型在玛南斜坡风城组开展了6井次的合分压预判与施工参数优化,实现压裂改造后试产普遍自喷,部分井日产油10.34~32.37 t,单井平均产量较采用传统压裂工艺提升近50%,可供同类油藏开发参考。

关键词: 玛湖凹陷, 风城组, 薄互层, 分层压裂, 裂缝扩展, BP神经网络, 决策模型

Abstract:

In Mahu sag, where there is abundant oil in place, the reservoirs in Permian Fengcheng formation are thick and have revealed good oil/gas show. However, the thin interbeds are complex in lithological assemblages and greatly variable in in-situ stress, so fine separate-layer fracturing must be done to recover the reserves. Based on the numerical simulation method, the factors influencing fracture propagation during multi-layer fracturing were analyzed, providing a basis for rational selection of layers for multi-layer or separate-layer fracturing. The results show that the reservoir stress difference influences fracture propagation the most, followed by fracturing fluid displacement and viscosity, and the reservoir thickness ratio influences the least. Based on the BP neural network algorithm, machine learning was carried out on the numerical simulation results, and a multi-factor fine separate-layer fracturing decision-making model that considers both geological and engineering factors was established. Using this decision-making model, multi-layer or separate-layer fracturing prediction and fracturing parameter optimization were made for 6 wells in the Fengcheng formation on the Manan slope. Post-frac flowing production tests demonstrated that the daily oil production of some wells reached 10.34-32.37 t, and the average single-well production was increased by nearly 50% compared with the traditional fracturing process. The study results can provide effective guidance for the optimization of the fracturing process of thin interbeds in the Mahu sag.

Key words: Mahu sag, Fengcheng formation, thin interbed, separate-layer fracturing, fracture propagation, BP neural network, decision-making model

中图分类号:

TE357.1

潘丽燕, 阮东, 惠峰, 刘凯新, 张敏, 彭岩. 玛湖凹陷风城组薄互层分层压裂优化方法[J]. 新疆石油地质, 2022, 43(2): 221-226.

PAN Liyan, RUAN Dong, HUI Feng, LIU Kaixin, ZHANG Min, PENG Yan. Methods for Separate-Layer Fracturing Optimization of Thin Interbeds in Fengcheng Formation, Mahu Sag[J]. Xinjiang Petroleum Geology, 2022, 43(2): 221-226.

图/表 5

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