What happens to pressure when a flow enters a side branch?

F. T. SMITH; N. C. OVENDEN; P. T. FRANKE; D. J. DOORLY

doi:10.1017/S002211200200366X

Abstract

The behaviour of incompressible side-branching flows is examined theoretically at high Reynolds numbers and compared with direct numerical simulation at moderate Reynolds numbers. The theoretical model assumes the branching (daughter) tube is small compared to the main (mother) tube and that the branching angle is small. The theory is applicable to steady and unsteady flows in two or three dimensions, and to a broad range of flow splits between mother and daughter vessels. The first main result of the work is that, in the vicinity of the branch, the flow adjusts to the imposed downstream pressure in the daughter tube through a jump (a rapid change over a short length scale) in flow properties across the daughter entrance. It is shown that, for large pressure drops in the daughter tube, fluid is sucked in at high velocities from the mother and thereby provides a favourable upstream feedback. This counteracts the tendency of the flow to separate from what would otherwise be an adversely shaped upstream wall. Increased divergence of mother and daughter tubes can thus be achieved at high daughter flow rates without separation. The second main result of the work is that the direct numerical simulations confirm the very rapid variation in flow properties and show reasonable agreement with the theory at moderate Reynolds numbers.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Bowles, R.I Dennis, S.C.R Purvis, R and Smith, F.T 2005. Multi-branching flows from one mother tube to many daughters or to a network. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 363, Issue. 1830, p. 1045.

Ovenden, Nicholas C and Smith, Frank T 2005. Vortices and flow reversal due to suction slots. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 363, Issue. 1830, p. 1199.

Tadjfar, Mehran 2006. Flow into an Arterial Branch Model. Journal of Engineering Mathematics, Vol. 54, Issue. 4, p. 359.

Formaggia, Luca Lamponi, Daniele Tuveri, Massimiliano and Veneziani, Alessandro 2006. Numerical modeling of 1D arterial networks coupled with a lumped parameters description of the heart. Computer Methods in Biomechanics and Biomedical Engineering, Vol. 9, Issue. 5, p. 273.

Smith, Frank Ovenden, Nicholas and Purvis, Richard 2006. IUTAM Symposium on One Hundred Years of Boundary Layer Research. Vol. 129, Issue. , p. 291.

BOWLES, R. I. OVENDEN, N. C. and SMITH, F. T. 2008. Multi-branching three-dimensional flow with substantial changes in vessel shapes. Journal of Fluid Mechanics, Vol. 614, Issue. , p. 329.

Green, J. E. F. Smith, F. T. and Ovenden, N. C. 2009. Flow in a multi-branching vessel with compliant walls. Journal of Engineering Mathematics, Vol. 64, Issue. 4, p. 353.

Ovenden, Nick Smith, Frank and Wu, Guo Xiong 2009. The effects of nonsymmetry in a branching flow network. Journal of Engineering Mathematics, Vol. 63, Issue. 2-4, p. 213.

Liang, Fuyou Takagi, Shu Himeno, Ryutaro and Liu, Hao 2009. Multi-scale modeling of the human cardiovascular system with applications to aortic valvular and arterial stenoses. Medical & Biological Engineering & Computing, Vol. 47, Issue. 7, p. 743.

Smith, Frank T. 2012. On internal fluid dynamics. Bulletin of Mathematical Sciences, Vol. 2, Issue. 1, p. 125.

Tziannaros, M. and Smith, F. T. 2012. Numerical and Analytical Study of Bladder-Collapse Flow. International Journal of Differential Equations, Vol. 2012, Issue. , p. 1.

White, A.H. and Smith, F.T. 2013. Computational modelling of the embolization process for the treatment of arteriovenous malformations (AVMs). Mathematical and Computer Modelling, Vol. 57, Issue. 5-6, p. 1312.

Bates, A.J. Cetto, R. Doorly, D.J. Schroter, R.C. Tolley, N.S. and Comerford, A. 2016. The effects of curvature and constriction on airflow and energy loss in pathological tracheas. Respiratory Physiology & Neurobiology, Vol. 234, Issue. , p. 69.

Bates, A.J. Comerford, A. Cetto, R. Schroter, R.C. Tolley, N.S. and Doorly, D.J. 2016. Power loss mechanisms in pathological tracheas. Journal of Biomechanics, Vol. 49, Issue. 11, p. 2187.

Balta, Samire and Smith, Frank 2017. Inviscid and low-viscosity flows in multi-branching and reconnecting networks. Journal of Engineering Mathematics, Vol. 104, Issue. 1, p. 1.

OVENDEN, N. C. and SMITH, F. T. 2018. NONSYMMETRIC BRANCHING OF FLUID FLOWS IN 3D VESSELS. The ANZIAM Journal, Vol. 59, Issue. 4, p. 533.

Koeppl, Tobias Santin, Gabriele Haasdonk, Bernard and Helmig, Rainer 2018. Numerical modelling of a peripheral arterial stenosis using dimensionally reduced models and kernel methods. International Journal for Numerical Methods in Biomedical Engineering, Vol. 34, Issue. 8,

Smith, F T and Servini, P 2019. Channel Flow Past A Near-Wall Body. The Quarterly Journal of Mechanics and Applied Mathematics, Vol. 72, Issue. 3, p. 359.

Smith, Frank T. Balta, Samire Liu, Kevin and Johnson, Edward R. 2019. Mathematics Applied to Engineering, Modelling, and Social Issues. Vol. 200, Issue. , p. 45.

PALMER, R. A. and SMITH, F. T. 2020. When a small thin two-dimensional body enters a viscous wall layer. European Journal of Applied Mathematics, Vol. 31, Issue. 6, p. 1002.

Download full list

Article contents

What happens to pressure when a flow enters a side branch?

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

What happens to pressure when a flow enters a side branch?

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests