Optimization of a Separationless Three-Phase Oil–Water–Gas Flowmeter of Horizontal Orientation with Dual-Isotope Gamma Densitometers

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Abstract

Information on the characteristics of separationless three-phase oil–water–gas flowmeters of horizontal orientation is presented, probably, for the first time; it is related to the optimization of their design based on experimental studies of single-isotope and dual-isotope gamma densitometers (GD) and a combined conical narrowing device (ND), which consists of two sequentially installed cones of various dimensions. The experiments were carried out on both real oil–gas–salt water mixtures at a TUV SUD NEL test bench (Glasgow) and with model exxsol–gas–fresh water flows at the GET195-2011 standard of multiphase flows at the All-Russia Research Institute for Flow Metering (Kazan) using typical flowmeters with a nominal diameter of DN 100. It is shown that it is advisable to install a γ-densitometer in a cross section with an intermediate diameter of D = 70 mm, use a cone of 70/50 mm as the measuring ND, and use a cone of 100/70 mm to preaccelerate the flow in order to reduce the variety of flow regimes of two-phase and three-phase flows in the measuring ND and in the flow part of the γ-densitometer. This significantly improves the characteristics of the prototype flowmeter. Some of the obtained characteristics are compared with those of the well-known Vx Schlumberger vertical analogue, and designs of variants of an advanced horizontal three-phase flowmeter are presented, which also make it possible to increase its service life and raise the operating pressure.

About the authors

A. Yu. Filippov

National Research University Moscow Power Engineering Institute

Email: forsc2231@gmail.com
111250, Moscow, Russia

Yu. P. Filippov

Joint Institute for Nuclear Research

Email: fyp@dubna.ru
141980, Dubna, Moscow oblast, Russia

A. M. Kovrizhnykh

Joint Institute for Nuclear Research

Author for correspondence.
Email: fyp@dubna.ru
141980, Dubna, Moscow oblast, Russia

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Copyright (c) 2023 А.Ю. Филиппов, Ю.П. Филиппов, А.М. Коврижных