Study Effect of Antiturbulence Additives on Hydraulic Efficiency in Oil Pipelines by Disk Turborheometer

AbstractTo determine the efficiency of additives Necadd-447, M-FLOWTREAT, FLO-XL, and FLO-MXA, a method for conducting experiments and processing the obtained results is proposed in this paper. The hydraulic efficiency for all additives is found to be within the Reynolds number range of 140,000–240,...

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Veröffentlicht in:	Journal of pipeline systems 2021-11, Vol.12 (4)
Hauptverfasser:	Nechval, Andrey M, Muratova, Vera I, Valeev, Anvar R, Yang, Chen, Tashbulatov, Radmir R
Format:	Artikel
Sprache:	eng
Schlagworte:	Additives Attenuation Efficiency Fluid dynamics Fluid flow Hydraulics Petroleum Petroleum pipelines Petroleum products Pipelines Polymers Reynolds number Rotating disks Submarine pipelines Technical Papers Toms effect
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creator	Nechval, Andrey M Muratova, Vera I Valeev, Anvar R Yang, Chen Tashbulatov, Radmir R
description	AbstractTo determine the efficiency of additives Necadd-447, M-FLOWTREAT, FLO-XL, and FLO-MXA, a method for conducting experiments and processing the obtained results is proposed in this paper. The hydraulic efficiency for all additives is found to be within the Reynolds number range of 140,000–240,000; the efficiency is maximum for Reynolds numbers of 600,000 to 700,000. Increase in additive concentration to 20–40 ppm increases hydraulic efficiency. Any further increase in concentration decreases effectiveness; this is due to turbulent behavior in the flow induced by a rotating disk and the attenuation of the Toms effect caused by an increase in the intermolecular interaction of polymer tangles. The highest hydraulic efficiency is observed at Reynolds numbers between 500,000 and 700,000. An empirical dependence is proposed to predict the effectiveness of antiturbulence additives in oil and petroleum products in trunk pipelines.
doi_str_mv	10.1061/(ASCE)PS.1949-1204.0000610
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subjects	Additives Attenuation Efficiency Fluid dynamics Fluid flow Hydraulics Petroleum Petroleum pipelines Petroleum products Pipelines Polymers Reynolds number Rotating disks Submarine pipelines Technical Papers Toms effect
title	Study Effect of Antiturbulence Additives on Hydraulic Efficiency in Oil Pipelines by Disk Turborheometer
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