A state-of-the-art, portable dispersion characterization rig (P-DCR) is used to investigate the effect of nanoparticles (NP) on oil-water emulsion formation and stabilization. Spherical silica NP of different wettabilities were used to investigate their effect on separation kinetics of solid stabilized emulsions in terms of solid particle concentration, wettability, initial dispersion phase, water-cut, and shearing time. The main findings of the study include the following: NP, even at concentrations as low as 0.005% or 0.01% (by weight), can significantly increase separation time of oil/water emulsions from a few minutes to several hours or even days. The P-DCR is recommended as an effective inline tool to measure emulsion stability in the field.
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February 2019
Research-Article
Oil/Water Emulsions Stabilized by Nanoparticles of Different Wettabilities
Ilias Gavrielatos,
Ilias Gavrielatos
Mem. ASME
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: elias-gavrielatos@utulsa.edu
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: elias-gavrielatos@utulsa.edu
Search for other works by this author on:
Ramin Dabirian,
Ramin Dabirian
Mem. ASME
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ramin-dabirian@utulsa.edu
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ramin-dabirian@utulsa.edu
Search for other works by this author on:
Ram S. Mohan,
Ram S. Mohan
Fellow ASME
Mechanical Engineering Department,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ram-mohan@utulsa.edu
Mechanical Engineering Department,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ram-mohan@utulsa.edu
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Ovadia Shoham
Ovadia Shoham
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ovadia-shoham@utulsa.edu
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ovadia-shoham@utulsa.edu
Search for other works by this author on:
Ilias Gavrielatos
Mem. ASME
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: elias-gavrielatos@utulsa.edu
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: elias-gavrielatos@utulsa.edu
Ramin Dabirian
Mem. ASME
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ramin-dabirian@utulsa.edu
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ramin-dabirian@utulsa.edu
Ram S. Mohan
Fellow ASME
Mechanical Engineering Department,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ram-mohan@utulsa.edu
Mechanical Engineering Department,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ram-mohan@utulsa.edu
Ovadia Shoham
McDougall School of Petroleum Engineering,
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ovadia-shoham@utulsa.edu
Tulsa University Separation Technology
Projects (TUSTP),
The University of Tulsa,
Tulsa, OK 74104
e-mail: ovadia-shoham@utulsa.edu
1Corresponding author.
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received December 20, 2017; final manuscript received May 14, 2018; published online June 29, 2018. Assoc. Editor: Ning Zhang.
J. Fluids Eng. Feb 2019, 141(2): 021301 (10 pages)
Published Online: June 29, 2018
Article history
Received:
December 20, 2017
Revised:
May 14, 2018
Citation
Gavrielatos, I., Dabirian, R., Mohan, R. S., and Shoham, O. (June 29, 2018). "Oil/Water Emulsions Stabilized by Nanoparticles of Different Wettabilities." ASME. J. Fluids Eng. February 2019; 141(2): 021301. https://doi.org/10.1115/1.4040465
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