Non-intrusive microwave system for multiphase flow metering

2018 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Pub Date : 2018-05-14 DOI:10.1109/I2MTC.2018.8409765

A. Sheila-Vadde, V. Melapudi, M. Suma, K. M. M. Kumar, J. Ward

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引用次数: 5

Abstract

Accurate and reliable measurement of oil, gas and water flow rates as they flow along a pipe as a mixture continues to be a challenging problem in the oil and gas industry. Most of the solutions rely on radioactive sources. This paper explores the use of microwave sensors for flow rate measurement. Microstrip Patch sensors in transmission mode and a near field coaxial probe in reflection mode are used to estimate water fraction even in lossy (saline) medium using physics based models with minimal calibration. Reflection measurements from the Patch sensors are used to estimate gas fraction using empirical models which can enable measurement of gas in high loss cases. Gas velocity is measured from cross correlation. A low cost 5-port measuring instrument was built to do reliable reflection and transmission measurements over a wide temperature range. The microwave system was tested in in-house and external flow loops and in the field under varying temperatures and flow conditions and test results are presented in this paper.

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非侵入式微波多相流计量系统

准确可靠地测量油、气和水在管道中的混合流动速率一直是石油和天然气行业的一个挑战。大多数解决方案都依赖于放射源。本文探讨了微波传感器在流量测量中的应用。传输模式下的微带贴片传感器和反射模式下的近场同轴探头使用基于物理模型的最小校准来估计即使在有损耗(含盐)介质中的水分数。来自Patch传感器的反射测量值用于使用经验模型估计气体分数，该模型可以在高损耗情况下测量气体。气速是通过相互关系来测量的。研制了一种低成本的5端口测量仪器，可在宽温度范围内进行可靠的反射和透射测量。本文给出了微波系统在不同温度和流动条件下的内部和外部流动回路以及现场测试结果。

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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2018 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)

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