Expanding the Envelope of Fiber-Optic Sensing for Reservoir Description and Dynamics

Abdulaziz Alqasim, Sharidah Alabduh, Muhannad Alabdullateef, Mutaz Alsubhi
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Abstract

Fiber-optic sensing (FOS) technology is gradually becoming a pervasive tool in the monitoring and surveillance toolkit for reservoir engineers. Traditionally, sensing with fiber optic technology in the form of distributed temperature sensing (DTS) or distributed acoustic sensing (DAS), and most recently distributed strain sensing (DSS), distributed flow sensing (DFS) and distributed pressure sensing (DPS) were done with the fiber being permanently clamped either behind the casing or production tubing. Distributed chemical sensing (DCS) is still in the development phase. The emergence of the composite carbon-rod (CCR) system that can be easily deployed in and out of a well, similar to wireline logging, has opened up a vista of possibilities to obtain many FOS measurements in any well without prior fiber-optic installation. Currently, combinations of distributed FOS data are being used for injection management, well integrity monitoring, well stimulation and production performance optimization, thermal recovery management, etc. Is it possible to integrate many of the distributed FOS measurements in the CCR or a hybrid combination with wireline to obtain multiple measurements with one FOS cable? Each one of FOS has its own use to get certain data, or combination of FOS can be used to make a further interpretation. This paper reviews the state of the art of the FOS technology and the gamut of current different applications of FOS data in the oil and gas (upstream) industry. We present some results of traditional FOS measurements for well integrity monitoring, assessing production and injection flow profile, cross flow behind casing, etc. We propose some nontraditional applications of the technology and suggest a few ways through. Which the technology can be deployed for obtaining some key reservoir description and dynamics data for reservoir performance optimization.
扩大光纤传感在油藏描述和动态中的应用范围
光纤传感(FOS)技术正逐渐成为油藏工程师监测和监视工具中的一种普遍工具。传统上,光纤传感技术以分布式温度传感(DTS)或分布式声学传感(DAS)的形式进行,而最近的分布式应变传感(DSS)、分布式流量传感(DFS)和分布式压力传感(DPS)是通过将光纤永久夹在套管或生产油管后面来完成的。分布式化学传感(DCS)仍处于发展阶段。复合碳棒(CCR)系统的出现,可以很容易地部署在井内和井外,类似于电缆测井,为在任何井中获得许多FOS测量提供了可能性,而无需事先安装光纤。目前,分布式FOS数据组合已被用于注入管理、油井完整性监测、油井增产和生产性能优化、热采管理等方面。是否有可能在CCR中集成许多分布式FOS测量或与电缆的混合组合,从而通过一根FOS电缆获得多个测量?每一种FOS都有自己的用途来获得某些数据,或者可以使用FOS的组合来进行进一步的解释。本文回顾了FOS技术的最新进展,以及目前FOS数据在油气(上游)行业的不同应用范围。介绍了传统的FOS测量方法在井完整性监测、生产和注入流剖面评估、套管后横流等方面的一些结果。我们提出了该技术的一些非传统应用,并提出了一些途径。该技术可用于获取关键的储层描述和动态数据,为储层动态优化提供依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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