Compact Viscosity Sensors for Downhole Enhanced Oil Recovery Polymer Fluid Degradation Monitoring

IF 3.2 3区 工程技术 Q1 ENGINEERING, PETROLEUM
SPE Journal Pub Date : 2024-03-01 DOI:10.2118/209430-pa
Miguel Gonzalez, Subhash Ayirala, Lyla Maskeen, Abdulkareem AlSofi
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引用次数: 0

Abstract

There are currently no technologies available to measure polymer solution viscosities at realistic downhole conditions in a well during enhanced oil recovery (EOR). In this paper, custom-made probes using quartz tuning fork (QTF) resonators are demonstrated for measurements of viscosity of polymer fluids in the laboratory. The electromechanical response of the resonators was calibrated in simple Newtonian fluids and in non-Newtonian polymer fluids at different concentrations. The responses were then used to measure field-collected samples of polymer injection fluids. In the polymer fluids, the measured viscosity values by tuning forks were lower than those measured by the conventional rheometer at 6.8 s−1, closer to the solvent viscosity values. However, the predicted rheometer viscosity vs. QTF-measured viscosity showed a distinct exponential correlation (R2=0.9997), allowing for an empirical calibration between the two viscometers for fluids having the same solvent and polymer compositions. The QTF sensors produced acceptable viscosity measurements of polymer fluids within the required polymer concentration ranges used in the field and predicted field sample viscosities with less than 1–2 cp (or 10–20%) error from the rheometer data. Results were validated based on separate independent tests where the devices were used to measure the viscosity of Newtonian fluids and non-Newtonian polymer fluids in a series of consecutive dip tests, simulating more realistic usage. These devices can be used to measure either the “relative” viscosity changes from a polymer solution prior and post-injection or to measure a “calibrated” viscosity via empirical exponential correlation. The compact QTF sensors developed in this study can be easily integrated into portable systems for laboratory or wellsite deployment as well as logging tools for downhole deployment. This work also demonstrates the ability of these QTF devices to make sensitive viscosity measurements at high-frequencies, opening opportunities for their use in high-frequency rheology studies of EOR fluids.
用于井下强化采油聚合物流体降解监测的紧凑型粘度传感器
目前还没有任何技术可以测量强化采油(EOR)过程中油井在实际井下条件下的聚合物溶液粘度。本文展示了使用石英音叉(QTF)谐振器定制的探头,用于在实验室测量聚合物溶液的粘度。在简单牛顿流体和不同浓度的非牛顿聚合物流体中校准了谐振器的机电响应。然后利用这些响应测量现场采集的聚合物注射流体样本。在聚合物流体中,调谐叉测得的粘度值低于传统流变仪测得的 6.8 s-1,更接近溶剂粘度值。然而,预测的流变仪粘度与 QTF 测量的粘度之间呈现出明显的指数相关性(R2=0.9997),因此,对于具有相同溶剂和聚合物成分的流体,两种粘度计之间可以进行经验校准。在现场使用的聚合物浓度范围内,QTF 传感器对聚合物流体进行了可接受的粘度测量,预测的现场样品粘度与流变仪数据的误差小于 1-2cp(或 10-20%)。在一系列连续的浸渍试验中,这些设备被用来测量牛顿流体和非牛顿聚合物流体的粘度,模拟更真实的使用情况。这些装置既可用于测量聚合物溶液在注入前后的 "相对 "粘度变化,也可通过经验指数相关性测量 "校准 "粘度。本研究开发的 QTF 传感器结构紧凑,可轻松集成到便携式系统中,用于实验室或井场部署,也可集成到测井工具中,用于井下部署。这项工作还展示了这些 QTF 设备在高频率下进行灵敏粘度测量的能力,为它们在 EOR 流体的高频流变学研究中的应用提供了机会。
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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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