盐浓度对具有复杂孔隙结构的碳酸盐岩中介电常数和界面极化的影响

IF 3.2 3区 工程技术 Q1 ENGINEERING, PETROLEUM
SPE Journal Pub Date : 2024-03-01 DOI:10.2118/210315-pa
Zulkuf Azizoglu, Z. Heidari
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引用次数: 0

摘要

宽带介质色散测量是评估充水孔隙度的极具吸引力的方法。介电常数受盐度以及其他岩石/流体性质的影响。然而,在具有复杂孔隙结构的岩石样本中,盐度对 Maxwell-Wagner 极化(即界面极化)和介电常数的影响还需要进一步研究。这项工作的目标是:(a)对不同盐浓度水平下的三维孔隙尺度岩石样品进行频域介电常数数值模拟;(b)量化盐度在 20 MHz 至 5 GHz 频率范围内对介电常数和界面极化的影响;以及(c)量化临界频率(即相对介电常数变得与频率无关的频率)。我们首先在具有复杂孔隙结构的完全水饱和碳酸盐样品中进行孔隙尺度频域介电常数模拟,以获得 0.01-5 GHz 频率范围和不同盐度水平下的复介电常数。接下来,我们用数值方法创建了部分水/碳氢化合物饱和的水湿样品,并在不同盐度和水饱和度水平下进行模拟,以研究盐度和水饱和度对介电常数的综合影响。最后,我们研究了复杂折射率模型 (CRIM) 和 Hanai-Bruggeman (HB) 等传统混合模型在评估不同盐度水平下水饱和度时的可靠性。我们使用了具有复杂孔隙结构的三维孔隙尺度岩石样本,这些样本来自奥斯汀白垩系、埃斯塔亚德斯灰岩和快乐斯普拉贝里地层。盐度从千分之二增加到千分之五十(PPT)时,20 MHz 的相对介电常数增加了 18%。同样,盐度从千分之 2 增加到千分之 50,在 20 MHz 时,电导率增加了 15 倍。然而,在 5 GHz 频率下,不同盐度下样品的相对介电常数之间的差异可以忽略不计。我们证明临界频率高于 1 GHz。因此,如果使用 1 GHz 时的复介电常数,则在解释碳酸盐岩层中的常规介电混合物模型时需要准确的盐度假设。最后,我们观察到,在所有相关频率上应用 CRIM 和 HB 模型时,水饱和度量化的平均相对误差分别为 52% 和 42%。结果还表明,在低频盐度不确定的情况下,不应使用传统模型。这项工作的结果量化了充水孔隙体积而非麦克斯韦-瓦格纳极化控制盐水盐度范围较宽的饱和岩石样本相对介电常数的频率。此外,研究结果表明,即使在 1 GHz 频率下,具有复杂孔隙结构的岩石样本的相对介电常数仍会受到界面极化的显著影响。此外,研究结果表明,传统的混合物方法无法可靠地考虑地层水的盐浓度,这会导致储量评估出现重大误差。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Effect of Salt Concentration on Dielectric Permittivity and Interfacial Polarization in Carbonate Rocks with Complex Pore Structure
Broadband dielectric dispersion measurements are attractive options for the assessment of water-filled porosity. Dielectric permittivity is influenced by salinity as well as other rock/fluid properties. However, the effect of salinity on Maxwell-Wagner polarization (i.e., interfacial polarization) and dielectric permittivity in rock samples with complex pore structures requires further investigation. The objectives of this work are (a) to perform frequency-domain dielectric permittivity numerical simulations on 3D pore-scale rock samples at different salt concentration levels, (b) to quantify the effect of salinity on dielectric permittivity and interfacial polarization in the frequency range between 20 MHz and 5 GHz, and (c) to quantify the critical frequency (i.e., the frequency at which the relative permittivity becomes frequency-independent). We first perform pore-scale frequency domain dielectric permittivity simulations in fully water-saturated carbonate samples with complex pore structures to obtain the complex dielectric permittivity in the frequency range of 0.01–5 GHz and at different salinity levels. Next, we numerically create partially water/hydrocarbon-saturated water-wet samples and perform simulations at different salinity and water saturation levels to investigate the combined effect of salinity and water saturation on dielectric permittivity. Finally, we investigate how reliable conventional mixing models, such as the complex refractive index model (CRIM) and Hanai-Bruggeman (HB), are in the assessment of water saturation at different salinity levels. We used 3D pore-scale rock samples with complex pore structures from Austin Chalk, Estaillades Limestone, and Happy Spraberry formations. The increase in salinity from 2 to 50 parts per thousand (PPT) resulted in the relative permittivity to increase by 18% at 20 MHz. Similarly, an increase in salinity from 2 PPT to 50 PPT resulted in electrical conductivity to increase by 15 times at 20 MHz. However, at 5 GHz, the difference between the relative permittivity of the samples at different salinities was negligible. We demonstrated that the critical frequency was above 1 GHz. Thus, if complex dielectric permittivity at 1 GHz is being used, an accurate salinity assumption is required in the interpretation of conventional dielectric mixture models in carbonate formations. Finally, we observed 52% and 42% average relative errors in water saturation quantification when applying CRIM and HB models at all the frequencies of interest, respectively. The results also indicated that conventional models should not be used in the presence of uncertainty in salinity at lower frequencies. The results of this work quantified the frequency at which the water-filled pore volume rather than the Maxwell-Wagner polarization controls the relative permittivity of rock samples saturated with a wide range of brine salinity. Moreover, the results demonstrated that the relative permittivity of the rock samples with complex pore structures may still be significantly affected by the interfacial polarization even at 1 GHz. Moreover, the results suggested that the conventional mixture methods cannot reliably take into account the salt concentration of formation water, and this can lead to significant errors in reserves assessment.
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来源期刊
SPE Journal
SPE Journal 工程技术-工程:石油
CiteScore
7.20
自引率
11.10%
发文量
229
审稿时长
4.5 months
期刊介绍: Covers theories and emerging concepts spanning all aspects of engineering for oil and gas exploration and production, including reservoir characterization, multiphase flow, drilling dynamics, well architecture, gas well deliverability, numerical simulation, enhanced oil recovery, CO2 sequestration, and benchmarking and performance indicators.
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