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51314-4057-Modelling of Top of Line Corrosion with Organic Acid and Glycol

Picture for Modelling of Top of Line Corrosion with Organic Acid and Glycol
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Product Number: 51314-4057-SG
ISBN: 4057 2014 CP
Author: Gaute Svenningsen
Publication Date: 2014
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Many approaches have been used for modelling Top of Line Corrosion (TLC). One common principle is that TLC is limited by the amount of iron that can be transported with the condensed water. This means that the TLC rate is proportional to the condensation rate and proportional to the solubility of iron in the condensing phase. Therefore TLC rate modelling typically involves a combination of condensation rate calculations and chemical equilibrium calculations. The presence of organic acid will reduce the pH and increase the iron solubility in the condensing water. It is therefore important that the chemical equilibrium calculations also include the effect of organic acids. Condensation of pure water is well understood and calculation of condensation rates has been implemented in several multiphase flow software on the market.Glycol injection is applied to many gas transport pipelines to avoid hydrate formation. Mono Ethylene Glycol (MEG) is commonly used for this purpose typically about 80 wt.% MEG is injected and the aqueous phase at the end of the pipeline contains about 40 wt.% MEG. The effect of MEG on internal condensation in pipelines has been less investigated. When MEG is present it will reduce the water vapour pressure but at the same time slight amount of MEG will evaporate and be present in the gas phase. If the chemical calculations are based on condensing the the gas phase components without resupply to maintain the chemical equilibrium (e.g. due to slow kinetics) the condensing phase will be water with small amounts of MEG. If complete chemical equilibrium is assumed the condensing phase will contain much more MEG in principle it will have the same MEG content as the aqueous phase in the bottom of line.This paper discusses how TLC rates are affected by how MEG and acetic acid is included in chemical equilibrium calculations and in condensation rate calculations. 
Many approaches have been used for modelling Top of Line Corrosion (TLC). One common principle is that TLC is limited by the amount of iron that can be transported with the condensed water. This means that the TLC rate is proportional to the condensation rate and proportional to the solubility of iron in the condensing phase. Therefore TLC rate modelling typically involves a combination of condensation rate calculations and chemical equilibrium calculations. The presence of organic acid will reduce the pH and increase the iron solubility in the condensing water. It is therefore important that the chemical equilibrium calculations also include the effect of organic acids. Condensation of pure water is well understood and calculation of condensation rates has been implemented in several multiphase flow software on the market.Glycol injection is applied to many gas transport pipelines to avoid hydrate formation. Mono Ethylene Glycol (MEG) is commonly used for this purpose typically about 80 wt.% MEG is injected and the aqueous phase at the end of the pipeline contains about 40 wt.% MEG. The effect of MEG on internal condensation in pipelines has been less investigated. When MEG is present it will reduce the water vapour pressure but at the same time slight amount of MEG will evaporate and be present in the gas phase. If the chemical calculations are based on condensing the the gas phase components without resupply to maintain the chemical equilibrium (e.g. due to slow kinetics) the condensing phase will be water with small amounts of MEG. If complete chemical equilibrium is assumed the condensing phase will contain much more MEG in principle it will have the same MEG content as the aqueous phase in the bottom of line.This paper discusses how TLC rates are affected by how MEG and acetic acid is included in chemical equilibrium calculations and in condensation rate calculations. 
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Picture for Top of Line Corrosion- Impact of MEG and Organic Acid in the Gas Phase
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51314-4382-Top of Line Corrosion- Impact of MEG and Organic Acid in the Gas Phase

Product Number: 51314-4382-SG
ISBN: 4382 2014 CP
Author: Arne Dugstad
Publication Date: 2014
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Picture for Top of Line Corrosion with High CO2 and Organic Acid
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51313-02591-Top of Line Corrosion with High CO2 and Organic Acid

Product Number: 51313-02591-SG
ISBN: 02591 2013 CP
Author: Gaute Svenningsen
Publication Date: 2013
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Picture for 02294 ORGANIC ACID CORROSION IN OIL AND...
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02294 ORGANIC ACID CORROSION IN OIL AND GAS PRODUCTION

Product Number: 51300-02294-SG
ISBN: 02294 2002 CP
Author: Michael W. Joosten, Juri Kolts, Justin W. Hembree, and Mohsen Achour
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