Detailed 3D modelling of mass transfer processes in two phase flows with dynamic interfaces

D. Darmana; W. Dijkhuizen; N.G. Deen; M. Sint Annaland, van; J.A.M. Kuipers

Detailed 3D modelling of mass transfer processes in two phase flows with dynamic interfaces

D. Darmana, W. Dijkhuizen, N.G. Deen, M. Sint Annaland, van, J.A.M. Kuipers

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

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Abstract

In this work a model is presented which allows us to a priori compute mass transfer coefficients for bubbles (droplets) rising in quiescent Newtonian fluids. Our model is based on the front tracking technique and explicitly accounts for the bubble-liquid mass transfer process. The dissolved species concentration in the liquid phase is computed from a species conservation equation while the value of the concentration at the interface is imposed via an immersed boundary technique. In the present study, simulations are carried out to demonstrate the capabilities of the model to predict bubble shape, flow field as well as transport of species from bubbles to the liquid phase for a group of twelve bubbles. It is found that bubbles rising in the wake of other bubbles will experience an increase of rise velocity, while the mass transfer rate is decreased.

Original language	English
Title of host publication	Proceedings of the 6th International Conference on Multiphase Flow (ICMF 2007), 9-13 July 2007, Leipzig, Germany
Publication status	Published - 2007

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title = "Detailed 3D modelling of mass transfer processes in two phase flows with dynamic interfaces",

abstract = "In this work a model is presented which allows us to a priori compute mass transfer coefficients for bubbles (droplets) rising in quiescent Newtonian fluids. Our model is based on the front tracking technique and explicitly accounts for the bubble-liquid mass transfer process. The dissolved species concentration in the liquid phase is computed from a species conservation equation while the value of the concentration at the interface is imposed via an immersed boundary technique. In the present study, simulations are carried out to demonstrate the capabilities of the model to predict bubble shape, flow field as well as transport of species from bubbles to the liquid phase for a group of twelve bubbles. It is found that bubbles rising in the wake of other bubbles will experience an increase of rise velocity, while the mass transfer rate is decreased.",

author = "D. Darmana and W. Dijkhuizen and N.G. Deen and {Sint Annaland, van}, M. and J.A.M. Kuipers",

year = "2007",

language = "English",

booktitle = "Proceedings of the 6th International Conference on Multiphase Flow (ICMF 2007), 9-13 July 2007, Leipzig, Germany",

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Detailed 3D modelling of mass transfer processes in two phase flows with dynamic interfaces. / Darmana, D.; Dijkhuizen, W.; Deen, N.G. et al.
Proceedings of the 6th International Conference on Multiphase Flow (ICMF 2007), 9-13 July 2007, Leipzig, Germany. 2007. paper 264.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - Detailed 3D modelling of mass transfer processes in two phase flows with dynamic interfaces

AU - Darmana, D.

AU - Dijkhuizen, W.

AU - Deen, N.G.

AU - Sint Annaland, van, M.

AU - Kuipers, J.A.M.

PY - 2007

Y1 - 2007

N2 - In this work a model is presented which allows us to a priori compute mass transfer coefficients for bubbles (droplets) rising in quiescent Newtonian fluids. Our model is based on the front tracking technique and explicitly accounts for the bubble-liquid mass transfer process. The dissolved species concentration in the liquid phase is computed from a species conservation equation while the value of the concentration at the interface is imposed via an immersed boundary technique. In the present study, simulations are carried out to demonstrate the capabilities of the model to predict bubble shape, flow field as well as transport of species from bubbles to the liquid phase for a group of twelve bubbles. It is found that bubbles rising in the wake of other bubbles will experience an increase of rise velocity, while the mass transfer rate is decreased.

AB - In this work a model is presented which allows us to a priori compute mass transfer coefficients for bubbles (droplets) rising in quiescent Newtonian fluids. Our model is based on the front tracking technique and explicitly accounts for the bubble-liquid mass transfer process. The dissolved species concentration in the liquid phase is computed from a species conservation equation while the value of the concentration at the interface is imposed via an immersed boundary technique. In the present study, simulations are carried out to demonstrate the capabilities of the model to predict bubble shape, flow field as well as transport of species from bubbles to the liquid phase for a group of twelve bubbles. It is found that bubbles rising in the wake of other bubbles will experience an increase of rise velocity, while the mass transfer rate is decreased.

M3 - Conference contribution

BT - Proceedings of the 6th International Conference on Multiphase Flow (ICMF 2007), 9-13 July 2007, Leipzig, Germany

ER -

Detailed 3D modelling of mass transfer processes in two phase flows with dynamic interfaces

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