Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-28T21:24:13.978Z Has data issue: false hasContentIssue false

Flow and pressure drop in systems of repeatedly branching tubes

Published online by Cambridge University Press:  29 March 2006

T. J. Pedley
Affiliation:
Physiological Flow Studies Unit, Imperial College, London, S.W.7
R. C. Schroter
Affiliation:
Physiological Flow Studies Unit, Imperial College, London, S.W.7
M. F. Sudlow
Affiliation:
Physiological Flow Studies Unit, Imperial College, London, S.W.7

Abstract

The airways of the lung form a rapidly diverging system of branched tubes, and any discussion of their mechanics requires an understanding of the effects of the bifurcations on the flow downstream of them. Experiments have been carried out in models containing up to two generations of symmetrical junctions with fixed branching angle and diameter ratio, typical of the human lung. Flow visualization studies and velocity measurements in the daughter tubes of the first junction verified that secondary motions are set up, with peak axial velocities just outside the boundary layer on the inner wall of the junction, and that they decay slowly downstream. Axial velocity profiles were measured downstream of all junctions at a range of Reynolds numbers for which the flow was laminar.

In each case these velocity profiles were used to estimate the viscous dissipation in the daughter tubes, so that the mean pressure drop associated with each junction and its daughter tubes could be inferred. The dependence of the dissipation on the dimensional variables is expected to be the same as in the early part of a simple entrance region, because most of the dissipation will occur in the boundary layers. This is supported by the experimental results, and the ratio Z of the dissipation in a tube downstream of a bifurcation to the dissipation which would exist in the same tube if Poiseuille flow were present is given by \[ Z = (C/4\surd{2})(Re\,d/L)^{\frac{1}{2}}, \] where L and d are the length and diameter of the tube, Re is the Reynolds number in it, and the constant C (equal to one for simple entry flow) is equal to 1·85 (the average value from our experiments). In general, C is expected to depend on the branching angles and diameter ratios of the junctions used. No experiments were performed in which the flow was turbulent, but it is argued that turbulence will not greatly affect the above results at Reynolds numbers less than and of the order of 10000. Many more experiments are required to consolidate this approach, but predictions based upon it agree well with the limited number of physiological experiments available.

Type
Research Article
Copyright
© 1971 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Champagne, F. H., Sleicher, C. A. & Wehrmann, O. H. 1967 Turbulence measurements with inclined hot-wires. Part 1. Heat transfer experiments with inclined hot-wire J. Fluid Mech. 28, 153.Google Scholar
Dryden, H. L. 1936 Air flow in the boundary layer near a plate. NACA Rep. no. 562.Google Scholar
Goldstein, S. 1938 Modern Developments in Fluid Mechanics. Oxford: Clarendon Press.
Green, M. 1965 How big are the bronchioles? St Thomas's Hospital Gazette, 63, 136.Google Scholar
Gregory, N., Stuart, J. T. & Walker, W. S. 1955 On the stability of three-dimensional boundary layers with application to the flow due to a rotating disk. Phil. Trans. Roy. Soc. A 248, 155.Google Scholar
Hall, A. A. 1938 Measurements of the intensity and scale of turbulence. Aero. Res. Comm. R & M no. 1842.Google Scholar
Horsfield, K. & Cumming, G. 1968 Functional consequences of airway morphology J. appl. Physiol. 24, 384.Google Scholar
McConalogue, D. J. & Srivastava, R. S. 1968 Motion of a fluid in a curved tube. Proc. Roy. Soc. A 307, 37.Google Scholar
Macklem, P. T., Fraser, R. G. & Bates, D. V. 1963 Bronchial pressures and dimension in health and in obstructive airways disease J. appl. Physiol. 18, 699.Google Scholar
Owen, P. R. 1969 Turbulent flow and particle deposition in the trachea. In CIBA Symposium on Circulatory and Respiratory Mass Transport. London: J. and A. Churchill.
Owen, P. R. & Randall, D. G. 1953 Boundary layer transition on a swept-back wing—a further investigation. R.A.E. Tech. Rep. Memo. no. Aero. 330.Google Scholar
Patel, V. C. & Head, M. R. 1969 Some observations on skin friction and velocity profiles in fully developed pipe and channel flows J. Fluid Mech. 38, 181.Google Scholar
Pedley, T. J., Schroter, R. C. & Sudlow, M. F. 1970a Energy losses and pressure drop in models of human airways. Respir. Physiol. 9, 371.Google Scholar
Pedley, T. J., Schroter, R. C. & Sudlow, M. F. 1970b The prediction of pressure drop and variation of resistance within the human bronchial airways. Respir. Physiol. 9, 387.Google Scholar
Schlichting, H. 1960 Boundary Layer Theory, New York: McGraw-Hill.
Schroter, R. C. & Sudlow, M. F. 1969 Flow patterns in models of human bronchial airways Respir. Physiol. 7, 341.Google Scholar
Townsend, A. A. 1956 The Structure of Turbulent Shear Flow. Cambridge University Press.
Ward-Smith, A. J. 1963 Flow and pressure losses in smooth pipe bends of constant cross-section J. Roy. Aero. Soc. 67, 437.Google Scholar
Weibel, E. R. 1963 Morphometry of the Human Lung. Berlin: Springer.