Evaluation of Different Hydrate Prediction Software and Impact of Different MEG Products on Gas Hydrate Formation and Inhibition

AlHarooni, Khalifa; Barifcani, Ahmed; Pack, David J.; Iglauer, Stefan

doi:10.4043/26768-ms

Cited by 3 publications

(3 citation statements)

References 11 publications

(11 reference statements)

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“…A full description of the gas hydrate test procedure is given elsewhere. , Prior to starting an experiment, the cell was pressurized with methane gas and vacuumed twice. Then, 7 mL of the solution was injected into the sapphire cell.…”

Section: Methodsmentioning

confidence: 99%

Analytical Techniques for Analyzing Thermally Degraded Monoethylene Glycol with Methyl Diethanolamine and Film Formation Corrosion Inhibitor

AlHarooni¹,

Pack²,

Iglauer³

et al. 2016

Energy Fuels

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Gas hydrate formation and corrosion within gas pipelines are two major flow assurance problems. Various chemical inhibitors are used to overcome these problems, such as monoethylene glycol (MEG) for gas hydrate control and methyl diethanolamine (MDEA) and film formation corrosion inhibitor (FFCI) for corrosion control. As an economical solution, MEG is regenerated due to the large volume required in the field. MEG regeneration involves thermal exposure by traditional distillation to purify the MEG. During this process, MEG is subjected to thermal exposure and so might be degraded. This study focuses on evaluating six analytical techniques for analyzing the degradation level of various MEG solutions consisting of MDEA and FFCI that were thermally exposed to 135 °C, 165 °C, 185 °C, and 200 °C. The analytical techniques evaluated are pH measurement, electrical conductivity, change in physical characteristics, ion chromatography (IC), high performance liquid chromatography–mass spectroscopy (HPLC-MS), and gas hydrate inhibition performance (using 20 wt % MEG solutions with methane gas at pressure from 50 to 300 bar). Most of the analytical techniques showed good capability, while electrical conductivity showed a poor result for solution without MDEA and IC showed poor results for solution exposed to 135 and 165 °C. The primary aim of this paper is thus to provide the industry with a realistic evaluation of various analytical techniques for the evaluation of degraded MEG solutions and to draw attention to the impact of degraded MEG on gas hydrate and corrosion inhibition as a result of the lack of quality control.

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Section: Methodsmentioning

confidence: 99%

Analytical Techniques for Analyzing Thermally Degraded Monoethylene Glycol with Methyl Diethanolamine and Film Formation Corrosion Inhibitor

AlHarooni¹,

Pack²,

Iglauer³

et al. 2016

Energy Fuels

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“…Gas hydrate equilibrium measurements were carried out in a transparent cryogenic sapphire cell unit (Figure ), 60 cm 3 volume, high operating pressure (maximum 500 bar), and a built-in variable speed magnetic stirrer (operated at 530 rpm) to agitate the solution for effective mixing. This will accelerate the rate of mass transfer and reduce the time needed to reach equilibrium. , The cell chamber temperature (range +60 to −160 °C) was controlled using an electric heater and refrigeration system, enhanced with a supply of chilled water.…”

Section: Methodsmentioning

confidence: 99%

Influence of Regenerated Monoethylene Glycol on Natural Gas Hydrate Formation

et al. 2017

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The key objective of this study is to investigate the efficiency of thermodynamic hydrate inhibition of monoethylene glycol (MEG) solutions collected from a MEG regeneration/reclamation pilot plant, simulating six scenarios of the start-up and clean-up phases of a typical gas field. The scenarios contain complex solutions of condensates, drilling muds/well completion fluids with high concentrations of divalent–monovalent ions, particulates, and various production chemicals, which can result in various system upsets in a MEG plant. MEG was regenerated and reclaimed at a recently constructed closed-loop MEG pilot plant that replicates a typical field plant. During MEG plant operation, feed-rich MEG is separated, cleaned, and heated so that water in it is evaporated and purified for reuse. In this study, equilibrium conditions of natural gas hydrates in the presence of 20 wt % of regenerated and reclaimed MEG solution at a pressure range of 65–125 bar were reported. The equilibrium data were measured in a PVT sapphire cell unit using an isochoric temperature search method. The measured data were compared with the literature and theoretical predictions to investigate the influence of regenerated/reclaimed MEG on gas hydrate inhibition performance. A better understanding of the efficiency of regenerated complex MEG solutions on hydrate phase equilibria forms a basis for improved system design, operations, and calculating required MEG dosages for hydrate inhibition.

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“…To operate in the dense phase region, the minimum operating pressure in the pipeline must be greater than the cricondenbaric point, defined as the maximum pressure at which both vapor and liquid exist in equilibrium for a multicomponent hydrocarbon system. hydrate plugs that might cause equipment damage, a reduction in pipe capacity and production shutdowns [9].…”

Section: Description Of the Dense Phasementioning

confidence: 99%

Gas transport at dense phase conditions for the development of deepwater fields in the Colombian Caribbean sea

Simancas

Santiago

Vera

2020

CT&F Cienc. Tecnol. Futuro

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The purpose of this article is to set out the benefits of using the dense phase gas transport in future projects in the Caribbean Sea and to verify that when operating pipelines at high pressures, more mass per unit of volume is transported, and liquid formation risks are mitigated in hostile environments and low temperatures.This study contains key data about gas production fields in deep and ultra-deep waters around the world, which serve as a basis for research and provide characteristics for each development to be contrasted with the subsea architecture proposed in this paper. Additionally, analogies are established between the target field (Gorgón-1, Kronos-1 and Purple Angel-1) and other offshore gas fields that have similar reservoir properties. Using geographic information systems, the layout of a gas pipeline and a subsea field architecture that starts in the new gas province is proposed.Finally, using a hydraulic simulation tool, the gas transport performance in dense phase is analyzed and compared with the conventional way of transporting gas by underwater pipelines, achieving up to 20 % in cost savings when dense phase is applied.

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Evaluation of Different Hydrate Prediction Software and Impact of Different MEG Products on Gas Hydrate Formation and Inhibition

Cited by 3 publications

References 11 publications

Analytical Techniques for Analyzing Thermally Degraded Monoethylene Glycol with Methyl Diethanolamine and Film Formation Corrosion Inhibitor

Analytical Techniques for Analyzing Thermally Degraded Monoethylene Glycol with Methyl Diethanolamine and Film Formation Corrosion Inhibitor

Influence of Regenerated Monoethylene Glycol on Natural Gas Hydrate Formation

Gas transport at dense phase conditions for the development of deepwater fields in the Colombian Caribbean sea

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