颗粒形状和充填结构对砂岩原生孔隙度的影响:数值模拟的启示

IF 2.6 2区地球科学 Q1 GEOLOGY

Sedimentology Pub Date : 2023-04-11 DOI:10.1111/sed.13098

Yiming Yan, Liqiang Zhang, Xiaorong Luo, Keyu Liu, Tongye Jia, Yanjun Lu

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引用次数: 1

摘要

砂岩是地下油气的重要载体和二氧化碳的地质封存。原生孔隙度是预测储层质量的重要参数，受颗粒形状、粒度分布和颗粒充填结构的影响。然而，很少有研究关注于建立砂岩的粒度、粒度分布和颗粒堆积结构的多元方程来预测砂岩的原生孔隙度。采用离散元法对砂岩的自然沉积过程进行了设计和模拟。结果表明:原始孔隙率受圆度、平整度、伸长率、晶粒尺寸分布和晶粒堆积织构的影响;其中，平均粒度对砂岩原生孔隙度的影响较小。基于193个单组分颗粒充填结构的砂岩模拟样品，建立了考虑圆度、平整度、伸长率、颗粒充填结构和粒度分布的数学模型。最大误差、平均绝对误差和均方根误差分别为0.71、0.26和0.32。模拟结果与数学预测结果的相关系数为0.94。在相同颗粒形状但不同峰度的砂岩中，原生孔隙度与粒度分布峰度呈正相关。原生孔隙度与平均晶粒尺寸无关，主要受晶粒堆积织构的影响。验证了作者在前人研究中提出的基于颗粒堆积结构的不同粒度分布曲线砂岩孔隙度初步预测模型，模拟结果与预测结果的相关系数>0.92。本文提出的数学模型是对以往不同粒度分布曲线和颗粒充填结构砂岩孔隙度初步预测模型中关键参数获取的有益补充。考虑圆度、平坦度、伸长率、颗粒堆积结构和粒度分布的数学模型对储层质量预测和成岩作用定量评价具有重要意义。

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Influence of the grain shape and packing texture on the primary porosity of sandstone: Insights from a numerical simulation

Sandstone is an important carrier of underground hydrocarbon and the geological sequestration of carbon dioxide. Primary porosity is an important parameter used to predict reservoir quality, and it is influenced by the grain shape, grain‐size distribution and grain packing texture. However, few studies have focused on deriving multivariate equations of the grain size, grain‐size distribution and grain packing texture to predict the primary porosity of sandstone. The natural sedimentary process of sandstones was designed and simulated using a discrete element method. The results confirmed that the primary porosity is influenced by roundness, flatness, elongation, grain‐size distribution and grain packing texture; of the attributes, the mean grain size contributes less to the primary porosity of sandstone. Based on 193 simulated sandstone samples with a one‐component grain packing texture, a mathematical model considering roundness, flatness, elongation, grain packing texture and grain‐size distribution was proposed. The maximum, mean absolute and root mean square errors were 0.71, 0.26 and 0.32, respectively. The correlation coefficient between the simulated results and mathematical predicted results was 0.94. Furthermore, the primary porosity was positively correlated with the kurtosis of the grain‐size distribution in sandstone with the same grain shape but different kurtosis. The primary porosity was found to be independent of the mean grain size and mainly affected by the grain packing texture. Moreover, the primary porosity prediction model for sandstones with different grain‐size distribution curves based on the grain packing texture, which was proposed by the author in a previous study, was verified, and the correlation coefficient between the simulated results and predicted results was >0.92. The new mathematical model proposed in this study is a useful supplement for key parameter acquisition in the previous primary porosity prediction model of sandstone with different grain‐size distribution curves and grain packing texture. A mathematical model considering roundness, flatness, elongation, grain packing texture and grain‐size distribution is of great significance for reservoir quality prediction and conducting a quantitative evaluation of the diagenesis.

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来源期刊

Sedimentology 地学-地质学

CiteScore

8.20

自引率

11.40%

发文量

审稿时长

6-12 weeks

期刊介绍： The international leader in its field, Sedimentology publishes ground-breaking research from across the spectrum of sedimentology, sedimentary geology and sedimentary geochemistry. Areas covered include: experimental and theoretical grain transport; sediment fluxes; modern and ancient sedimentary environments; sequence stratigraphy sediment-organism interaction; palaeosoils; diagenesis; stable isotope geochemistry; environmental sedimentology