CFD Prediction of the Round Elbow Fitting Loss Coefficient
Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33122
CFD Prediction of the Round Elbow Fitting Loss Coefficient

Authors: Ana Paula P. dos Santos, Claudia R. Andrade, Edson L. Zaparoli

Abstract:

Pressure loss in ductworks is an important factor to be considered in design of engineering systems such as power-plants, refineries, HVAC systems to reduce energy costs. Ductwork can be composed by straight ducts and different types of fittings (elbows, transitions, converging and diverging tees and wyes). Duct fittings are significant sources of pressure loss in fluid distribution systems. Fitting losses can be even more significant than equipment components such as coils, filters, and dampers. At the present work, a conventional 90o round elbow under turbulent incompressible airflow is studied. Mass, momentum, and k-e turbulence model equations are solved employing the finite volume method. The SIMPLE algorithm is used for the pressure-velocity coupling. In order to validate the numerical tool, the elbow pressure loss coefficient is determined using the same conditions to compare with ASHRAE database. Furthermore, the effect of Reynolds number variation on the elbow pressure loss coefficient is investigated. These results can be useful to perform better preliminary design of air distribution ductworks in air conditioning systems.

Keywords: Duct fitting, Pressure loss, Elbow.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092072

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 4855

References:


[1] Wang, S.K, Handbook of Air Conditioning and Refrigeration, 2nd edition, 2001.
[2] Meyer, L.A., Airflow in Ducts, indoor Environment Technicians, LAMA Books, 2004.
[3] ESDU 83037, Pressure losses in curved ducts: single bends, Endorsed by The Institution of Chemical Engineers, The Institution of Mechanical Engineers, 1983.
[4] Mcquiston, F. C.; Parker, J. D.; Spitler, J. D., Heating, Ventilating, and Air Conditioning – Analysis and Design. 5ª ed. New York, EUA, 2000.
[5] Sauer Jr., H.J, Howell, R.H. and Coad, W.J, Principles of Heating, Ventilating and Air Conditioning, ASHRAE, Atlanta, 2001.
[6] Moujaes, S.F., Deshmukh, S., Three-dimensional CFD predications and experimental comparison of pressure drop of some common pipe fittings in turbulent flow, Journal of Energy Engineering, 132, 61-66, 2006.
[7] Gallegos-Muñoz, A., Rodríguez, N.C.U., Flores, J.M.B., Hernández, V.H R. Analysis of effect caused by fitting in the measurements of flow in air conditioning system, Applied Thermal Engineering, 33-34, 227-236, 2012.
[8] Shao, L., Riffat, S.B., Accuracy of CFD for Predicting Pressure Losses in HVAC Duct Fittings, Applied Energy, 51, 233-248, 1995.
[9] Mumma, S.A., Mahank, T.A. and Ke, Yu-Pei, , Analytical determination of duct fitting loss-coefficients, Applied Energy, 61, 229-247, 1998.
[10] Wang, J., Shirazi, S.A., A CFD based correlation for mass transfer coefficient in elbows, International Journal of Heat and Mass Transfer, 44, 1817-1822, 2001.
[11] Moujaes, S.F., Aekula, S. CFD predictions and experimental comparisons of pressure drop effects of turning vanes in 90° duct elbows, Journal of Energy Engineering, 135, 119-126, 2009.
[12] ASHRAE Handbook-Fundamentals, Duct Fitting Database, 2009.
[13] Yongson, O., Badruddin, I. A., Zainal, Z.A., Narayana P.A. A., Airflow analysis in an air conditioning room, Building and Environment, 42, 1531–1537, 2007.
[14] Fluent, 12.0 version, User’s Guide Manual, 2006.
[15] Manning, A. W., J., Hanlon, N., Mikjaniec, T., Prediction of duct fitting losses using computational fluid dynamics, HVAC&R Research, 19, 400-411, 2013.