原位润湿性的磁共振限制扩散测定

Azzan Al Yaarubi, Chanh Cao Minh, Nate Bachman, A. Valori, Suryanarayana Guntupalli, Khalsa Al Hadidi
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引用次数: 0

摘要

润湿性是一个重要的储层和岩石物性评价参数,但往往被忽略。为了简单起见,这两门学科通常都假设地层是水湿的,因为岩心的润湿性测量通常具有很高的不确定性。随着非常规碳酸盐岩储层开发的扩大和对提高采收率(EOR)的兴趣,了解天然状态下的润湿性及其随不同注入流体的变化变得至关重要。为了实际目的,需要一种快速准确的测定方法,理想情况下是在原位条件下。人们普遍认为核磁共振(NMR)对流体-岩石相互作用的强度非常敏感,因此长期以来一直被认为是测定润湿性的良好候选者。核磁共振方法首次应用于实验室,使用T2弛豫测量。例如,在油湿体系中,样品的润湿性可以从油峰值的位移推断为较短的T2值,而不是活体油的总体T2响应。基于T2位移的润湿性评价的适用性的主要实际限制是T2谱中油和水峰的分离通常很差。此外,必须测量活性油的体积T2,并且必须对岩心样品进行完全清洗,以量化核磁共振表面弛豫效应。最近,一种基于核磁共振扩散与T2的二维映射的方法被开发出来,并通过amot - harvey和USBM实验室测量进行了验证。这种方法有两个优点。首先,与一维T2相比,油水信号的分离度大大提高。其次,利用限制扩散模型可以从二维核磁共振图中推断出关键属性,如弯曲度(由电胶结因子m表示)和有效表面弛豫度。然后可以根据有效表面松弛度估算润湿性指数。岩心的实验室结果表明,利用井下核磁共振测量可以获得储层润湿性。这需要高分辨率、高信噪比(SNR)的数据和改进的处理技术来分离油水信号。我们利用在一口塑料套管完井的观测井中收集的测井数据,检验了核磁共振限制扩散润湿性技术。该井用于监测EOR试验中不同阶段的原油脱饱和度,包括水、碱性表面活性剂(ASP)和聚合物驱。井下核磁共振工具可以同时记录T1、T2和多重探测深度(DOI)下的扩散。该装置允许定期收集高质量的核磁共振数据,信噪比高于50。目标储层为含烃的砂岩,黏度为90 cP。在选定的深度和分析的时间间隔内,计算的润湿性一致显示为轻度油湿状态。
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In-Situ Wettability Determination Using Magnetic Resonance Restricted Diffusion
Wettability is a critical reservoir and petrophysical evaluation parameter that is often ignored. Both disciplines often assume the formations are water-wet for simplicity and because wettability measurement on cores often carries a high degree of uncertainty. With the expansion of unconventional carbonate reservoirs development and interest in enhanced oil recovery (EOR), the importance of understanding wettability at the native state and its variability with various injection fluids is becoming critical. For practical purposes, a fast and accurate determination method, ideally at in-situ conditions, is desired. It is widely recognized that nuclear magnetic resonance (NMR) is very sensitive to the strength of the fluid-rock interactions, and therefore, has been long considered as a good candidate for wettability determination. The NMR methodology was first applied in the laboratory using T2 relaxation measurements. For instance, sample wettability is inferred from a shift of the oil peak to shorter T2 values compared with the bulk T2 response of a live oil in the case of oil-wet system. The main practical limitation to the applicability of the T2 shift-based evaluation of wettability is the usually poor separation of oil and water peaks in the T2 spectrum. Furthermore, the bulk T2 of live oils must be measured and the core sample must be perfectly cleaned to quantify the NMR surface relaxation effect. Recently, a method based on two-dimensional mapping of NMR diffusion versus T2 was developed and validated with Amott-Harvey and USBM lab measurements. This method has two advantages. First, separation between the oil and water signals is greatly improved compared with the one-dimensional T2. Second, key properties such as tortuosity, represented by the electrical cementation factor m, and effective surface relaxivity can be inferred from the two-dimensional NMR maps using the restricted-diffusion model. The wettability index can then be estimated from the effective surface relaxivities. The laboratory results on cores suggest that it is possible to obtain reservoir wettability using downhole NMR measurements. This requires high-resolution, high signal-to-noise ratio (SNR) data and improved processing techniques to separate oil and water signals. We examined the NMR restricted-diffusion wettability technique utilizing log data collected in an observation well completed with plastic casing. This well is used to monitor oil desaturation during different phases of an EOR pilot consisting of water, alkaline surfactant (ASP), and polymer floods. A downhole NMR tool that simultaneously records T1, T2 and diffusion at multiple depth of investigation (DOI) was used. This device allowed to periodically collect high-quality NMR data with SNR higher than 50. The targeted reservoir is a sandstone containing hydrocarbon with viscosity of 90 cP. The computed wettability consistently showed mildly oil-wet condition at the selected depth and over the analyzed time intervals.
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