A procedure to compute flutter boundaries of rotating blades is presented; a) Navier-Stokes equations. b) Frequency domain method compatible with industry practice. Procedure is initially validated: a) Unsteady loads with flapping wing experiment. b) Flutter boundary with fixed wing experiment. Large scale flutter computation is demonstrated for rotating blade: a) Single job submission script. b) Flutter boundary in 24 hour wall clock time with 100 cores. c) Linearly scalable with number of cores. Tested with 1000 cores that produced data in 25 hrs for 10 flutter boundaries. Further wall-clock speed-up is possible by performing parallel computations within each case
An analysis and a numerical lifting surface method are developed for predicting the unsteady airload...
A fast-running unsteady aerodynamics code, LINFLUX, was previously developed for predicting turbomac...
An existing capability developed to conduct modal flutter analysis of tuned bladed-shrouded discs in...
A time-marching aeroelastic method developed for the study of propeller flutter is presented and val...
A time-marching aeroelastic method developed for the study of propeller flutter is presented and va...
An experimental forward-swept fan encountered flutter at part-speed conditions during wind tunnel te...
Two methods for calculating linear frequency domain aerodynamic coefficients from a time marching Fu...
The objective of this paper is to describe an accurate and efficient reduced order modeling method f...
The NASA Lewis aeroelastic research program is focused on unstalled and stalled flutter, forced resp...
This report presents, in two parts, a dynamic aeroelastic stability (flutter) analysis of a cascade ...
Modifications to an existing three-dimensional, implicit, upwind Euler/Navier-Stokes code (CFL3D Ver...
The LINFLUX-AE computer code predicts flutter and forced responses of blades and vanes in turbomachi...
A solution procedure was developed to investigate the two-dimensional, one- or two-dimensional flutt...
An experimental setup has been designed to examine rotor blade stall flutter. The blade had to be de...
The development of advanced-design ultrahigh bypass ratio engines has led to renewed interest in the...
An analysis and a numerical lifting surface method are developed for predicting the unsteady airload...
A fast-running unsteady aerodynamics code, LINFLUX, was previously developed for predicting turbomac...
An existing capability developed to conduct modal flutter analysis of tuned bladed-shrouded discs in...
A time-marching aeroelastic method developed for the study of propeller flutter is presented and val...
A time-marching aeroelastic method developed for the study of propeller flutter is presented and va...
An experimental forward-swept fan encountered flutter at part-speed conditions during wind tunnel te...
Two methods for calculating linear frequency domain aerodynamic coefficients from a time marching Fu...
The objective of this paper is to describe an accurate and efficient reduced order modeling method f...
The NASA Lewis aeroelastic research program is focused on unstalled and stalled flutter, forced resp...
This report presents, in two parts, a dynamic aeroelastic stability (flutter) analysis of a cascade ...
Modifications to an existing three-dimensional, implicit, upwind Euler/Navier-Stokes code (CFL3D Ver...
The LINFLUX-AE computer code predicts flutter and forced responses of blades and vanes in turbomachi...
A solution procedure was developed to investigate the two-dimensional, one- or two-dimensional flutt...
An experimental setup has been designed to examine rotor blade stall flutter. The blade had to be de...
The development of advanced-design ultrahigh bypass ratio engines has led to renewed interest in the...
An analysis and a numerical lifting surface method are developed for predicting the unsteady airload...
A fast-running unsteady aerodynamics code, LINFLUX, was previously developed for predicting turbomac...
An existing capability developed to conduct modal flutter analysis of tuned bladed-shrouded discs in...