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3 - 1-D Flow and Network Modeling

Published online by Cambridge University Press:  25 September 2018

Bijay Sultanian
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Type
Chapter
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Gas Turbines
Internal Flow Systems Modeling
 , pp. 143 - 181
Publisher: Cambridge University Press
Print publication year: 2018

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References

References

Benedict, R. P. 1980. Fundamentals of Pipe Flow. New York: John Wiley & Sons.Google Scholar
Buckingham, E. 1932. Notes on the orifice meter; the expansion factor for gases. J. Res. Natl. Bur. Stand. 9. p. 61.Google Scholar
Carnahan, B., Luther, H. A., and Wilkes, J. O.. 1969. Applied Numerical Methods. New York: John Wiley & Sons.Google Scholar
Idris, A., and Pullen, K.R.. 2005. Correlations for the discharge coefficient of rotating orifices based on the incidence angle. Proc. IMechE Part A: J Power Energy. 219: 333352.CrossRefGoogle Scholar
McGreehan, W. F., and Schotsch, M. J.. 1988. Flow characteristics of long orifices with rotation and corner radiusing. ASME J. Turbomach. 110: 213217.CrossRefGoogle Scholar
Nash, S. G., and Sofer, A.. 1996. Linear and Nonlinear Programming. New York: McGraw-Hill.Google Scholar
Parker, D. M., and Kercher, D. M.. 1991. Enhanced method to compute the compressible discharge coefficient of thin and long orifices with inlet corner radiusing. Heat Transfer in Gas Turbine Engines. HTD-Vol. 188, ed. E. Elovic. pp. 53–63. New York: ASME.Google Scholar
Perry, J. A. 1949. Critical flow through sharp-edged orifices. Trans. ASME. 71(10):757764.Google Scholar
Stolz, J. 1975. An approach towards a general correlation of discharge coefficients of orifice plate meters. Paper K-1, Conference on Fluid Flow in the Mid 1970’s, 5–10 April 1975, East Kilbride, Glasgow.Google Scholar
Sultanian, B.K. 1980. HOME – A program package on Householder reflection method for linear least-squares data fitting. J. Institution of Engineers (I). 60(pt Et. 3):7175.Google Scholar
Sultanian, B. K. 2015. Fluid Mechanics: An Intermediate Approach. Boca Raton, FL: Taylor & Francis.Google Scholar

Bibliography

Alexiou, A., and Mathioudakis, K.. 2009. Secondary air system component modeling for engine performance simulations. ASME J. Engrg. Gas Turbine Power. 131(3). pp.31202.1–9.Google Scholar
Blevin, R. D. 2003. Applied Fluid Dynamics Handbook. Malabar: Krieger Publishing Company.Google Scholar
Bragg, S. L. 1960. Effect of compressibility on the discharge coefficient of orifices and convergent nozzles. J. Mechanical Engineering Science. 2(1): 3544.CrossRefGoogle Scholar
Cunningham, R. G. 1951. Orifice meters with supercritical compressible flow. Trans. ASME. 73: 625638.Google Scholar
Debler, W. R. 1990. Fluid Mechanics Fundamentals, 1st edn. Englewood Cliffs, NJ: Prentice Hall.Google Scholar
Deckker, B. E. L., and Chang, Y. F.. 1965–1966. An investigation of steady compressible flow through thick orifices. Proc. IMechE. 180 (Part 3F):132.Google Scholar
Dittmann, M., Dullenkopf, K., and Wittig, S.. 2003. Discharge coefficients of rotating short orifices with radiused and chamfered inlets. ASME Paper No. GT2003–38314.Google Scholar
Gritsch, M., Schulz, A., and Wittig, S.. 2001. Effect of crossflows on the discharge coefficient of film cooling holes with varying angles of inclination and orientation. ASME Paper No. 2001-GT-0134.CrossRefGoogle Scholar
Hay, N., Lamperd, D., and Benmansour, S.. 1983. Effect of crossflows on the discharge coefficient of film cooling holes. Trans. ASME J. Eng Power.105: 243248.Google Scholar
Huening, M. 2008. Comparison of discharge coefficient measurements and correlations for several orifice designs with cross-flow and rotation around several axes. ASME Paper No. GT2008–50976.Google Scholar
Huening, M. 2010. Comparison of discharge coefficient measurements and correlations for orifices with cross-flow and rotation. ASME J. Turbomach. 132(3): 031017.1031017.10.Google Scholar
Idelchik, I. E. 2005. Handbook of Hydraulic Resistance, 3rd edn. Delhi: Jaico Publishing House.Google Scholar
Idris, A., Pullen, K., Barnes, D.. 2004. An investigation into the flow within inclined and rotating orifices and the influence of incidence angle on the discharge coefficient. Proc IMechE Part A: J. Power Energy. 218: 5569.CrossRefGoogle Scholar
Idris, A., Pullen, K. R., and Read, R.. 2004. The influence of incidence angle on the discharge coefficient for rotating radial orifices. ASME Paper No. GT2004–53237.CrossRefGoogle Scholar
Jeppson, R. W. 1976. Analysis of Flow in Pipe Networks. Ann Arbor: Ann Arbor Science Publishers Inc.Google Scholar
Miller, D. S. 1990. Internal Flow Systems, 2nd edn. Houston: Gulf Publishing CompanyGoogle Scholar
Miller, R. W. 1996. Flow Measurement Engineering Handbook, 3rd edn. New York: McGraw-Hill.Google Scholar
Mott, R. L. 2006. Applied Fluid Mechanics, 6th edn. New Jersey: Pearson Prentice Hall.Google Scholar
Hay, N., and Lampard, D.. 1998. Discharge coefficient of turbine cooling holes: a review. ASME J. Turbomach. 120. pp. 314319.Google Scholar
Rohde, J. E., Richard, H. T., and Metzger, G. W.. 1969. Discharge coefficients of thick plate orifices with approach flow perpendicular and inclined to the orifice axis. NASA TN D-5467.Google Scholar
Shapiro, A. H. 1953. The Dynamics and Thermodynamics of Compressible Fluid Flow, Vol. 1. New York: John Wiley & Sons.Google Scholar
Sousek, J. 2010. Experimental study of discharge coefficients of radial orifices in high-speed rotating shafts. ASME Paper No. GT2010–22691.CrossRefGoogle Scholar

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