Conceptual design of the inlet flow preheat system to the nozzle test equipment of a turbine engine
Subject Areas : Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering
Behrooz Shahriari
1
,
Hamid Farrokhfal
2
,
Mohammad Reza Nazari
3
1 - Faculty of Mechanics, Malek Ashtar University of Technology, Isfahan, Iran
2 - Faculty of Mechanics, Malek Ashtar University of Technology, Iran
3 - Faculty of Mechanics, Malek Ashtar University of Technology, Iran
Keywords: Turbofan engine nozzle, Nozzle ground test, Hot flow simulation, Combustion chamber design, Afterburner design,
Abstract :
To ensure the correct design and proper operation of turbine engine components, various types of ground tests must be performed, which requires the simulation of the input flow to these components. To test hot components such as nozzles, it is necessary to create a hot flow, which is done by the preheat system of the inlet flow. For the ground test of the nozzle of a turbofan engine that has an afterburner in addition to the combustion chamber, the preheat system must be able to supply air in two modes, dry mode and reheat mode. In this paper a combustion chamber with an afterburner is used to provide hot air to the nozzle. In the first step, using experimental and analytical relations, the combustion chamber is designed. The presented algorithm has the ability to calculate the diameter and reference surface of the combustion chamber, components of the combustion chamber and thermodynamic parameters. Then the obtained results are compared with the data of a similar annular combustion chamber. The comparison indicates the acceptable convergence of the design results with the experimental results. Finally, the output flow of the combustion chamber is considered as the input of the afterburner, and the temperature of the combustion flow is increased by the afterburner to the desired temperature. In addition to the ability to design a V-gutter flame keeper, the afterburner design algorithm also calculates the thermodynamic characteristics of the afterburner output stream, considering the requirements of flame stability.
[1] W. Dodds and D. Bahr. (1990). Combustion system design. Design of modern gas turbine combustors, pp.343-476.
[2] J. D. Mattingly. (2002). Aircraft engine design: AIAA.
[3] A. H. Lefebvre. (2010). Gas turbine combustion. CRC Press.
[4] M. R. J. Charest. (2006). Design methodology for a lean premixed prevaporized can combustor. MS Thesis, Library and Archives Canada,Carleton University, Department of Mechanical and Aerospace Engineering.
[5] P. J. Stuttaford and P. A. Rubini. (1996). Preliminary gas turbine combustor design using a network approach. In ASME International Gas Turbine and Aeroengine Congress and, Exhibition.
[6] P. J. Stuttaford and P. A. Rubini. (1996) Preliminary gas turbine combustor design using a network approach. in ASME International Gas Turbine and Aeroengine Congress and, Exhibition.
[7] M. J. Wankhede. (2012). Multi-fidelity strategies for lean burn combustor design. PhD Thesis, University of Southampton.
[8] Jai-Houng Leu. (2010). Design and simulation validation of LHV fuel combustor. Journal of Information and Optimization Sciences, 31:6,1321-1336.
[9] Yize Liu, Xiaoxiao Sun, Vishal Sethi, Yi-Guang Li, Devaiah Nalianda, David Abbott, Pierre Gauthier,Bairong Xiao and Lu Wang. (2021). Development and application of a preliminary design methodology for modern low emissions aero combustors. Journal of power and energy. Vol. 235(4) 783-806.
[10] J. W. Sawyer. (1966). Gas Turbine Engineering Handbook: Editor. John W. Sawyer, vol. , Gas Turbine Publications.
[11] P. P. Walsh and P. Fletcher. (2004). Gas turbine performance. John Wiley & Sons.
[12 ] R. Rezvani. (2010). A Conceptual Methodology for the Prediction of Engine Emissions. PhD Thesis, Georgia Tech. University.
[13] H. Knight and R. Walker. (1953). The component pressure losses in combustion chambers. Gt. Brit. National Gas Turbine Establishment, Farnborough, Hants, England.
[14] M. R. J. Charest. (2006). Design methodology for a lean premixed prevaporized can combustor. MSThesis, Library and Archives Canada Bibliothèque et Archives Canada, Carleton University,
Department of Mechanical and Aerospace Engineering.
[15] A. Costa Conrado, P. T. Lacava, A. C. P. Filaho, M. D. S. Sanches. (2004). Basic design principles for gas turbine combustor. Proceedings of the 10o Brazilian Congress of Thermal Sciences and Engineering.
[16] J. J. Gouws. (2008). Combining a one-dimensional empirical and network solver with computational fluid dynamics to investigate possible modifications to a commercial gas turbine combustor. MS Thesis, University of Pretoria .
[17] K. A. das Neves. (2018). Combustion analysis on a CFM56 engine. Master's Degree in Aeronautic engineering, Beira Interior University.
[18] S.Farokhi. Aircraft Propulsion. second Edition, Wiley.
[19] A.Lefebvre-D.Ballal. (1979). Weak Extinction Limits of Turbulent Flowing Mixtures. Journal of Engineering for Power.
[20] E. zukoski. (1985). Aerothermodynamics of Aircraft Engine Components. AIAA.