Evolution of Casedhole Nuclear Surveillance Logging Through Time

Petrophysics – The SPWLA Journal of Formation Evaluation and Reservoir Description Pub Date : 2023-08-01 DOI:10.30632/pjv64n4-2023a1

D. Fitz

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Abstract

Nuclear logging techniques have played a critical role in the evaluation and surveillance of hydrocarbon reservoirs since the introduction of the gamma ray log in 1939. This paper reviews the history of key developments in nuclear logging that led to improved methods to identify gas-oil (GOC), gas-water (GWC), and oil-water (OWC) contacts in steel-cased wells, as well as methods to identify gas, steam, and waterflood front encroachment, calculate their saturations, and recognize problems in efficient reservoir depletion. This paper will focus solely on nuclear methods used to directly identify fluids behind pipe using natural gamma radiation, neutron-induced gamma radiation, and neutron flux measurements. This includes gamma ray, spectral gamma ray, single- and dual-detector neutron measurements, pulsed-neutron capture, (), and pulsed-neutron spectroscopy (carbon/oxygen or C/O) methods. It will not cover other methods of identifying fluids behind pipe, such as borehole gravity and deep electromagnetic (EM) methods using wired pipe. It also will not cover indirect methods to infer fluid types in reservoirs, such as nuclear production logging using gamma density and pulsed-neutron measurements.

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套管核监测测井随时间的演变

自1939年引入伽马测井以来，核测井技术在油气藏评价和监测中发挥了关键作用。本文回顾了核测井的重要发展历史，这些发展改进了识别钢套井中油气(GOC)、气水(GWC)和油水(OWC)接触面的方法，以及识别气、蒸汽和水驱前缘侵入、计算其饱和度和识别储层有效衰竭问题的方法。本文将只关注使用自然伽马辐射、中子诱导伽马辐射和中子通量测量直接识别管道后流体的核方法。这包括伽马射线，谱伽马射线，单探测器和双探测器中子测量，脉冲中子捕获，()和脉冲中子光谱(碳/氧或C/O)方法。它不包括其他识别管道后流体的方法，例如使用有线管道的井眼重力和深电磁(EM)方法。它也不包括推断储层流体类型的间接方法，例如使用伽马密度和脉冲中子测量的核生产测井。

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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Petrophysics – The SPWLA Journal of Formation Evaluation and Reservoir Description

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