Use of Geological Constraints in Multi-Mineral Modeling for Unconventional Reservoirs

Z. Hao, A. Nora, Mendez Freddy, Hanif Amer
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引用次数: 1

Abstract

Determination of mineral rock composition is an important part of unconventional reservoir formation evaluation because the mineral composition affects hydraulic fracture generation and propagation. Two types of models are usually used for mineralogy modeling—deterministic and stochastic. Both models apply mathematical representations of the logging tool responses; however, stochastic modeling has become more popular due to its consideration of random distributions in the predictor and target variables. Stochastic mineralogy modeling algorithms usually produce solutions by minimizing a function reflecting the differences between the measured and modeled responses. However, due to the non-uniqueness inherent in inversion methods, the solution may not provide petrophysically meaningful results. To avoid producing compromised results, the use of geological constraints is proposed to represent the geological relations between the unknown parameters (inversion variables), leading to a more meaningful mineralogy model. The proposed algorithm incorporates probability functions to generate mineralogical solutions representing geologically and petrophysically sound results. The weight assigned to the penalties in the cost function depends on the probability function assigned to the constraints. Two models are presented using the proposed algorithm: a pyrite-anhydrite constraint based on the iron and sulfur ratio, and a K-feldspar-albite constraint based on the thorium and potassium ratio. Data sets from several different shale plays, from across North America, are processed using the proposed algorithm. The mineral sets are complex and vary from one play to another. The results show excellent agreement with the available core X-ray diffraction measurements. The study demonstrates that the proposed constraints provide an effective improvement, in integrated formation evaluation, especially in unconventional reservoirs with highly complex mineralogy.
地质约束在非常规储层多矿物建模中的应用
矿物岩石成分的确定是非常规储层评价的重要组成部分,因为矿物成分影响水力裂缝的产生和扩展。矿物学建模通常采用两种模型——确定性模型和随机模型。两种模型都应用了测井工具响应的数学表示;然而,随机建模由于考虑了预测变量和目标变量的随机分布而变得越来越流行。随机矿物学建模算法通常通过最小化反映测量和模拟响应之间差异的函数来产生解决方案。然而,由于反演方法固有的非唯一性,该解决方案可能无法提供有岩石物理意义的结果。为了避免产生折衷的结果,建议使用地质约束来表示未知参数(反演变量)之间的地质关系,从而产生更有意义的矿物学模型。所提出的算法结合概率函数来生成代表地质和岩石物理结果的矿物学解。代价函数中惩罚的权重取决于约束的概率函数。利用该算法提出了两个模型:基于铁硫比的黄铁矿-硬石膏约束模型和基于钍钾比的钾长石-钠长石约束模型。来自北美几个不同页岩区的数据集使用所提出的算法进行处理。矿物集是复杂的,从一个到另一个变化。结果与现有的岩心x射线衍射测量结果非常吻合。研究表明,所提出的约束条件对地层综合评价,特别是对矿物学高度复杂的非常规储层,提供了有效的改进。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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