Menu

Discussion Forum

New Discussion
フィルター

Discussion Closed This discussion was created more than 6 months ago and has been closed. To start a new discussion with a link back to this one, click here.

bubbly flow: udrift in laminar flow...

Posted 2012/12/04 4:35 GMT-5 Computational Fluid Dynamics (CFD) 1 Reply

Patrick Namy Certified Consultant
Send Private Message Flag post as spam

Please login with a confirmed email address before reporting spam

Hi,

I am currently working with the bubbly flow application mode in a laminar flow.

The gaz velocity, ug, is computed thanks:
ug=ug+uslip+udrift

In the help, is it said that the drift velocity is computed only in a turbulent flow. However, in the laminar flow, we can see that this dift velocity is non equal to zero. Does anyone know if, from a physical point of view, if this velocity should be equal to zero in a laminar flow?

thanks a lot!

Patrick

PS: in version 3.5, the drift velocity was equal to zero in a laminar flow
1 Reply Last Post 2013/01/25 10:59 GMT-5
COMSOL Moderator

Hello Patrick Namy

Your Discussion has gone 30 days without a reply. If you still need help with COMSOL and have an on-subscription license, please visit our Support Center for help.

If you do not hold an on-subscription license, you may find an answer in another Discussion or in the Knowledge Base.

Fabrice Schlegel COMSOL Employee

Please login with a confirmed email address before reporting spam

Posted: 1 decade ago 2013/01/25 10:59 GMT-5
Hi Patrick,

For more information on the bubbly flow physics, please refer to the "Theory for the bubbly flow interface" section in the CFD user guide, or to the following references:

1. A. Sokolichin, G. Eigenberger, and A. Lapin, “Simulations of Buoyancy Driven
Bubbly Flow: Established Simplifications and Open Questions,” AIChE Journal,
vol. 50, no. 1, pp. 24–49, 2004.

2. D. Kuzmin and S. Turek, Efficient Numerical Techniques for Flow Simulation in
Bubble Column Reactors, Institute of Applied Mathematics, University of Dortmund,
2000.

3. D. Kuzmin, S. Turek, and H. Haario, Finite Element Simulation of Turbulent
Bubbly Flows in Gas-liquid Reactors, Ergebnisberichte Angew, Math, 298, University
of Dortmund, 2005.

4. M.P. Schwarz and W.J. Turner, “Applicability of the Standard k-e Turbulence Model
to Gas-stirred Baths,” Applied Mathematical Modelling, vol. 12, pp. 273–279, 1988.

5. C. Crowe, M. Sommerfeld, and Y. Tsuji, Multiphase Flows with Droplets and
Particles, CRC Press, 1998.

Best,
Fabrice
Hi Patrick, For more information on the bubbly flow physics, please refer to the "Theory for the bubbly flow interface" section in the CFD user guide, or to the following references: 1. A. Sokolichin, G. Eigenberger, and A. Lapin, “Simulations of Buoyancy Driven Bubbly Flow: Established Simplifications and Open Questions,” AIChE Journal, vol. 50, no. 1, pp. 24–49, 2004. 2. D. Kuzmin and S. Turek, Efficient Numerical Techniques for Flow Simulation in Bubble Column Reactors, Institute of Applied Mathematics, University of Dortmund, 2000. 3. D. Kuzmin, S. Turek, and H. Haario, Finite Element Simulation of Turbulent Bubbly Flows in Gas-liquid Reactors, Ergebnisberichte Angew, Math, 298, University of Dortmund, 2005. 4. M.P. Schwarz and W.J. Turner, “Applicability of the Standard k-e Turbulence Model to Gas-stirred Baths,” Applied Mathematical Modelling, vol. 12, pp. 273–279, 1988. 5. C. Crowe, M. Sommerfeld, and Y. Tsuji, Multiphase Flows with Droplets and Particles, CRC Press, 1998. Best, Fabrice

Note that while COMSOL employees may participate in the discussion forum, COMSOL® software users who are on-subscription should submit their questions via the Support Center for a more comprehensive response from the Technical Support team.

Suggested Content