Three-Phase Separator Online Measurement and Data Analytics for Fluid Interface and Emulsion Thickness Utilizing a Single Emulsion Watch Profiler

Jouni Hartikainen, Pekka Kaunisto, James L. Walls, A. Voutilainen, P. Laakkonen, O. Lehtikangas
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Abstract

Separators can over the length of field life be exposed to operating conditions outside the set design conditions, which can cause operating issues in terms of separator efficiency, operating expenditures and potential need for frequent maintenance and/or retrofitting new internals. In mature operations with heavy oils, there can be severe issues with Water-in-Oil and Oil-in-Water emulsion layers. In late life operations, enhanced oil recovery (EOR) efforts with polymer injection can also take place to produce more, but at the same time making the separator function in terms of phase separation even more complex. Emulsion thickness and residence time optimization in separators and tanks are key issues in the oil and gas operations. Real-time data of the full level profiling is complicated and has been based on instruments with varying reliability and performance. Operations have been relying on other process parameters and bottle tests. However, in this work, separator profiler utilizing electrical tomography was used for monitoring separator content online, especially fluid interface levels as well as emulsion and foam layer thicknesses. In addition, effect of polymer injection to the wells is investigated. From the single profiler, data for the separator fluid levels, emulsion and foam thicknesses can be derived. The profiler used is a safe-to-use non-radioactive probe-type measurement sensor which is installed through an existing separator nozzle. The actual separator profiler with dimensions 5 cm diameter and 3 m length was installed downstream of the inlet cyclones and the flow distribution baffles in the three-phase separator located at one of the production fields in the Middle East. Water-oil interface, turbulent water-in-oil dispersion band, oil-gas interface and foam layer thickness were monitored continuously for several months with varying flowrates and operation conditions. Later, effect of polymer injection was also investigated. Interface level and layer monitoring results will be given and discussed. The results show that the profiler is highly useful for monitoring the separator fluid distribution online, building a rigid data analytics model over time that can be utilized by the operations to improve and optimize the performance. This paper shares novel information on operational experience of data analytics used for three-phase separators operating in a heavy oil field with polymer injection. The sensor type used is novel to the industry with high robustness and reliability generating multiple data points per second, enabling a highly detailed analytics model generating new possibilities for operational optimization through digitalization. In addition, commissioning and monitoring of the sensor was done remotely during covid-19 shutdown without the need of external personnel entering the field demonstrating remote commissioning and digital oil field concepts.
三相分离器在线测量和数据分析流体界面和乳化液厚度利用单一乳化液观察分析器
在整个使用寿命期间,分离器可能会暴露在超出设定设计条件的操作条件下,这可能会导致分离器效率、运营支出以及可能需要频繁维护和/或改造新内部的操作问题。在含重油的成熟作业中,油包水和水包油乳化层可能存在严重问题。在后期作业中,也可以通过注入聚合物来提高采收率(EOR),以提高产量,但同时也使分离器在相分离方面的功能变得更加复杂。乳化液在分离器和储罐中的厚度和停留时间优化是油气作业中的关键问题。全液面剖面的实时数据比较复杂,采用的仪器的可靠性和性能参差不齐。操作一直依赖于其他工艺参数和瓶试。然而,在这项工作中,利用电断层成像的分离器剖面仪被用于在线监测分离器内容,特别是流体界面水平以及乳液和泡沫层厚度。此外,还研究了注聚合物对井的影响。通过单个剖面仪,可以得到分离器液面、乳液和泡沫厚度的数据。所使用的剖面仪是一种安全使用的无放射性探针型测量传感器,通过现有的分离器喷嘴安装。实际的分离器剖面器直径为5厘米,长度为3米,安装在位于中东某生产油田的三相分离器的入口旋风分离器和气流分布挡板的下游。在不同流量和操作条件下,连续数月监测了水-油界面、油包水湍流弥散带、油气界面和泡沫层厚度。随后,对聚合物注入的影响进行了研究。给出并讨论界面级和层监测结果。结果表明,该分析器对于在线监测分离器流体分布非常有用,可以建立一个严格的数据分析模型,该模型可以用于操作以改进和优化性能。本文分享了稠油油田注聚合物三相分离器数据分析的操作经验。所使用的传感器类型在行业中是新颖的,具有高鲁棒性和可靠性,每秒可生成多个数据点,使高度详细的分析模型能够通过数字化为操作优化提供新的可能性。此外,在covid-19关闭期间,无需外部人员进入现场,即可远程调试和监控传感器,演示远程调试和数字油田概念。
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