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Drag prediction method of powered-on civil aircraft based on thrust drag bookkeeping 被引量:13
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作者 Zhang Yufei Chen Haixin +2 位作者 Fu Song Zhang Miao Zhang Meihong 《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2015年第4期1023-1033,共11页
A drag prediction method based on thrust drag bookkeeping(TDB) is introduced for civil jet propulsion/airframe integration performance analysis.The method is derived from the control volume theory of a powered-on na... A drag prediction method based on thrust drag bookkeeping(TDB) is introduced for civil jet propulsion/airframe integration performance analysis.The method is derived from the control volume theory of a powered-on nacelle.Key problem of the TDB is identified to be accurate prediction of velocity coefficient of the powered-on nacelle.Accuracy of CFD solver is validated by test cases of the first AIAA Propulsion Aerodynamics Workshop.Then the TDB method is applied to thrust and drag decomposing of a realistic aircraft.A linear relation between the computations assumed free stream Mach number and the velocity coefficient result is revealed.The thrust losses caused by nozzle internal drag and pylon scrubbing are obtained by the isolated nacelle and mapped on to the in-flight whole configuration analysis.Effects of the powered-on condition are investigated by comparing through-flow configuration with powered-on configuration.The variance on aerodynamic coefficients and pressure distribution is numerically studied. 展开更多
关键词 Discharge coefficient drag prediction Powered-on configuration Thrust drag bookkeeping Velocity coefficient
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A Structured Mesh Euler and Interactive Boundary Layer Method for Wing/Body Configurations
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作者 李杰 周洲 《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2008年第1期19-27,共9页
To compute transonic flows over a complex 3D aircraft configuration, a viscous/inviscid interaction method is developed by coupling an integral boundary-layer solver with an Eluer solver in a "semi-inverse" manner. ... To compute transonic flows over a complex 3D aircraft configuration, a viscous/inviscid interaction method is developed by coupling an integral boundary-layer solver with an Eluer solver in a "semi-inverse" manner. For the turbulent boundary-layer, an integral method using Green's lag equation is coupled with the outer inviscid flow. A blowing velocity approach is used to simulate the displacement effects of the boundary layer. To predict the aerodynamic drag, it is developed a numerical technique called far-field method that is based on the momentum theorem, in which the total drag is divided into three component drags, i.e. viscous, induced and wave-formed. Consequently, it can provide more physical insight into the drag sources than the often-used surface integral technique. The drag decomposition can be achieved with help of the second law of thermodynamics, which implies that entropy increases and total pressure decreases only across shock wave along a streamline of an inviscid non-isentropic flow. This method has been applied to the DLR-F4 wing/body configuration showing results in good agreement with the wind tunnel data. 展开更多
关键词 viscous/inviscid interaction far-field drag prediction transonic flow wing/body configuration
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