论文信息 - Thermal cycle analysis of turboelectric distributed propulsion system with boundary layer ingestion

Thermal cycle analysis of turboelectric distributed propulsion system with boundary layer ingestion

Abstract A fundamental shift in propulsion system design was needed to satisfy future aircraftsʼ strict emission and fuel consumption requirements. The turboelectric distributed propulsion system (TeDP) uses electricity to transmit power from the core turbine to number of fans. This novel concept can dramatically increase bypass ratio to achieve lower fuel consumption and noise. This paper put forward a method to design a TeDP system on hybrid wing body airframe. An examination of the system thermodynamic performance for a range of fan pressure ratio (FPR) was made and FPR 1.3 was chosen for a detailed analysis. Finally, a comparison with results from the NASA N + 3 technical reports on TeDP system has been performed. The new model returned similar results but estimated the new system has lower specific fuel consumption at cruise for the same thrust level.

[1] Hyun Dae Kim,et al. Low Noise Cruise Efficient Short Take-Off and Landing Transport Vehicle Study , 2006 .

[2] L. M. Randall,et al. Importance of Air Induction System Design to Supersonic Aircraft , 1962 .

[3] Gerald V. Brown,et al. Weights and Efficiencies of Electric Components of a Turboelectric Aircraft Propulsion System , 2011 .

[4] Mark Drela,et al. Airframe Design for "Silent Aircraft" , 2007 .

[5] Daniel Crichton,et al. Engine And Installation Configurations For A Silent Aircraft , 2005 .

[6] Gerald V. Brown,et al. An Examination of the Effect of Boundary Layer Ingestion on Turboelectric Distributed Propulsion Systems , 2011 .

[7] Cesare A. Hall,et al. Challenges in the silent aircraft engine design , 2007 .

[8] S. Lieblein,et al. Empirical expressions for estimating length and weight of axial-flow components of VTOL powerplants , 1971 .

[9] John K. Lytle. The Numerical Propulsion System Simulation: An Overview , 2000 .

[10] James L. Felder,et al. Distributed Turboelectric Propulsion for Hybrid Wing Body Aircraft , 2008 .

[11] Ronald T. Kawai. Acoustic Prediction Methodology and Test Validation for an Efficient Low-Noise Hybrid Wing Body Subsonic Transport , 2011 .

[12] Gerald V. Brown,et al. Turboelectric Distributed Propulsion Engine Cycle Analysis for Hybrid-Wing-Body Aircraft , 2009 .