Computational Prediction of Heat Transfer to Gas Turbine Nozzle Guide Vanes With Roughened Surfaces

Abstract: The local Mach number and heat transfer coefficient over the aerofoil surfaces and endwalls of a transonic gas turbine nozzle guide vane have been calculated. The computations were performed by solving the time averaged Navier-Stokes equations using a fully three-dimensional computational code (CFDS) which is well established at Rolls-Royce. A model to predict the effects of roughness has been incorporated into CFDS and heat transfer levels have been calculated for both hydraulically smooth and … Show more

“…In 1998, Guo et al [13] used a three dimensional CFD code to predict local Mach number and heat transfer coefficients over airfoil surfaces and end-walls of a transonic gas-turbine nozzle guide vane. They modified the law of the wall for calculation on rough surfaces and their results were confirmed by the measured data.…”

Effects of surface roughness on deviation angle and performance losses in wet steam turbines

“…In 1998, Guo et al [13] used a three dimensional CFD code to predict local Mach number and heat transfer coefficients over airfoil surfaces and end-walls of a transonic gas-turbine nozzle guide vane. They modified the law of the wall for calculation on rough surfaces and their results were confirmed by the measured data.…”

Effects of surface roughness on deviation angle and performance losses in wet steam turbines

Sensitivity analysis of freestream turbulence parameters on stagnation region heat transfer using a neural network

Effects of Surface Roughness on Heat Transfer and Aerodynamic Performance of Turbine Airfoils