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Liquid film thickness behaviour within a large diameter vertical 180° return bend (2013)
Journal Article
Adbulkadir, M., Azzi, A., Zhao, D., Lowndes, I., & Azzopardi, B. (2014). Liquid film thickness behaviour within a large diameter vertical 180° return bend. Chemical Engineering Science, 107, 137-148. https://doi.org/10.1016/j.ces.2013.12.009

Experimental results of liquid film thickness distribution of an air-water mixture flowing through a vertical 180° return bend are reported. Measurements of liquid film thickness were achieved using flush mounted pin and parallel wire probes. The ben... Read More about Liquid film thickness behaviour within a large diameter vertical 180° return bend.

Experimental study of the hydrodynamic behaviour of slug flow in a vertical riser (2013)
Journal Article
Abdulkadir, M., Hernandez-Perez, V., Lowndes, I., Azzopardi, B. J., & Dzomeku, S. (2014). Experimental study of the hydrodynamic behaviour of slug flow in a vertical riser. Chemical Engineering Science, 106, https://doi.org/10.1016/j.ces.2013.11.021

This paper presents an investigation of the hydrodynamics of slug flow in a vertical 67 mm internal diameter riser. The slug flow regime was generated using a multiphase air–silicone oil mixture over a range of gas (0.42

Separation of oil/water emulsions in continuous flow using microwave heating (2013)
Journal Article
Binner, E., Robinson, J. P., Kingman, S., Lester, E., Azzopardi, B. J., Dimitrakis, G., & Briggs, J. (2013). Separation of oil/water emulsions in continuous flow using microwave heating. Energy and Fuels, 27(6), https://doi.org/10.1021/ef400634n

This work studies a continuous flow microwave system to enhance gravity settling of water-in-oil emulsions. Settling times were found to be dependent upon the applied power, flowrate and energy input. Power and energy input are linked to liquid flowr... Read More about Separation of oil/water emulsions in continuous flow using microwave heating.