Pressure Losses on Realistic Geometry of Tracheobronchial Tree
Authors: Michaela Chovancova, Jakub Elcner
Abstract:
Real bronchial tree is very complicated piping system. Analysis of flow and pressure losses in this system is very difficult. Due to the complex geometry and the very small size in the lower generations is examination by CFD possible only in the central part of bronchial tree. For specify the pressure losses of lower generations is necessary to provide a mathematical equation. Determination of mathematical formulas for calculation of pressure losses in the real lungs is time consuming and inefficient process due to its complexity and diversity. For these calculations is necessary to slightly simplify the geometry of lungs (same cross-section over the length of individual generation) or use one of the idealized models of lungs (Horsfield, Weibel). The article compares the values of pressure losses obtained from CFD simulation of air flow in the central part of the real bronchial tree with the values calculated in a slightly simplified real lungs by using a mathematical relationship derived from the Bernoulli and continuity equations. The aim of the article is to analyse the accuracy of the analytical method and its possibility of use for the calculation of pressure losses in lower generations, which is difficult to solve by numerical method due to the small geometry.
Keywords: Pressure gradient, airways resistance, real geometry of bronchial tree, breathing.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1100432
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[1] J. B. West, “Respiratory physiology: The essentials,” Lippincott Williams and Wilkins, Philadalphia, 2008.
[2] R. M. Schwartzstein, M. J. Parker, “Respiratory physiology: A clinical approach,” Lippincott Williams and Wilkins, Philadalphia, 2006.
[3] Schmidt A., Zidowitz S., Kriete A., Denhard T., Krass S., Peitgen H.O. (2004) A digital reference model of the human bronchial tree, Computerized Medical Imaging and Graphics, vol. 28, 203-211
[4] Menter, F. R., Langtry, R. B., Likki, S. R., Suzen, Y. B., Huang, P. G., &Völker, S. (2006). A Correlation-Based Transition Model Using Local Variables—Part I: Model Formulation. Journal of Turbomachinery, 128(3), 413. doi:10.1115/1.2184352
[5] Tan, F. P. P., Soloperto, G., Bashford, S., Wood, N. B., Thom, S., Hughes, A., &Xu, X. Y. (2008). Analysis of flow disturbance in a stenosed carotid artery bifurcation using two-equation transitional and turbulence models. Journal of Biomechanical Engineering, 130(6), 061008. doi:10.1115/1.2978992
[6] W. O. Feen, H. Rahn, “Handbook of Physiology: Respiration,” American Physiological Society, Washington, D.C., 1964.
[7] R. A. Rhoades, D. R. Bell, “Medical Physiology,” Lippincott Williams and Wilkins, Philadalphia, 2008
[8] F. G. Hoppin Jr., J. Hildebrandt, “Mechanical properties of the Lung,” In West, J.B. (Ed.), New York, 1977.
[9] K. Horsfield, G. Cumming “Morphology of the bronchial tree in man,” Journal of applied physiology, page 373, 1968.