2016
DOI: 10.1016/j.ces.2016.07.046
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Experimental study of the formation and deposition of gas hydrates in non-emulsifying oil and condensate systems

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Cited by 39 publications
(30 citation statements)
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“…Although hydrate management can substantially reduce the CAPEX and OPEX, there is still a significant lack of fundamental understanding in the growth and agglomeration phenomena of hydrates in multiphase systems. Different experimental apparatus, e.g., flowloops, , batch reactors, and rocking cells, , give different growth kinetic rates (i.e., amount of gas consumed over time) and plugging tendencies (i.e., pressure drop and volumetric flow rate oscillations) even when similar gases (often methane or synthetic natural gas) and oils are used. Therefore, the literature still presents a process of trial and error in understanding both phenomena (growth kinetics and agglomeration) for the use of different gases, oils, and additives in different conditions of water cut, mixture flow rate, and presence of salt.…”
Section: Introductionmentioning
confidence: 99%
“…Although hydrate management can substantially reduce the CAPEX and OPEX, there is still a significant lack of fundamental understanding in the growth and agglomeration phenomena of hydrates in multiphase systems. Different experimental apparatus, e.g., flowloops, , batch reactors, and rocking cells, , give different growth kinetic rates (i.e., amount of gas consumed over time) and plugging tendencies (i.e., pressure drop and volumetric flow rate oscillations) even when similar gases (often methane or synthetic natural gas) and oils are used. Therefore, the literature still presents a process of trial and error in understanding both phenomena (growth kinetics and agglomeration) for the use of different gases, oils, and additives in different conditions of water cut, mixture flow rate, and presence of salt.…”
Section: Introductionmentioning
confidence: 99%
“…The role of KHIs is to delay the nucleation or growth of hydrate crystallization while AAs allow the hydrate formation but help to disperse hydrate particles finely in production fluids, in other words, preventing hydrate agglomeration and plugs. Recently, AAs are widely used [3][4][5] due to their ability to avoid hydrate accumulation and plugging and their role as hydrate KHIs.…”
Section: Introductionmentioning
confidence: 99%
“…It is, however, not suitable to achieve proper dispersion of phases that simulates the multiphase flow conditions in flowlines . A rocking cell with a rolling ball is also widely used for laboratory studies because it can simply generate the flow by rocking. , Phases in the rocking cell are better dispersed, but the flow is still relatively stagnant, and the rolling ball actually causes more disturbances to the flow, resulting in a nonspecific flow regime and dispersion of the phases. Table lists the characteristics for each experimental system.…”
Section: Introductionmentioning
confidence: 99%