Experimental and theoretical analysis of heat transfer on a transonic blade.

Essa, Zaahir Ahmed.

January 2008

This dissertation involves the experimental and numerical analysis of heat transfer on a transonic high turning angle gas turbine blade, which has been performed on the supersonic cascade experimental facility at the University of KwaZulu-Natal (UKZN), as part of the continuous research and development project run under ARMSCOR. Efforts have been made to keep constant maintenance on the experimental rig. This now functional rig was used to generate experimental results, which were used to validate numerical models created using the commercially available computational fluid dynamics (CFD) package of FLUENT. The facility at UKZN is a continuously running cascade system, which consists of a plenum run under vacuum pressure and houses a four-blade cascade. One of these SMR-95 turbine blades is instrumented with thin-film gauges, which allow heat transfer measurement via a heat transfer analogy through electrical circuit boards. This blade is interchangeable with an instrumented blade with pressure tappings along its span for pressure distribution tests. This facility was used to validate flow measurements, and results compared to previous test data conducted on the rig, using two pressure transducers, a scanivalve and a data acquisition system with LabView software. The method of generating heat transfer measurement results involved pre-chilling the test blade in a cooling box, before rapidly plunging it directly into a hot-air stream. Re-instrumented and more sensitive thin-film gauges would react resistively according to the temperature change. The heat transfer coefficient distribution was calculated using LabView. The turbulence intensity at the inlet of the cascade was varied using a grid of rods of varying diameter. For 15% turbulence intensity, there was a 16% overall increase in heat transfer on the pressure side, and 25% increase on the suction side. For 25.5% turbulence intensity, there was an overall increase of 23% on the pressure side and 40% on the suction side. The results compared favourably to that of previous results generated by Stieger (1998). The experimental results were used to validate and compare to the CFD model developed in FLUENT. Improvements were made with the meshes developed previously, and results obtained showed that the general trend of distribution was similar, although certain models varied in the correct prediction of magnitude. This research includes a comprehensive study of various methods of numerical heat transfer measurement techniques, which would be used to replace the current ageing electrical heat transfer analogue method used at UKZN. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2008.

Heat--Transmission.

Theses--Mechanical engineering.

An experimental investigation of the thermal conductivity of thin-wall hollow ceramic spheres

Shapiro, Michael Jay

January 1987

No description available.

Metallurgy

Radiative transfer

Heat Transmission

Heat transfer from electrically heated thin metal films in vacuo

Swank, Robert Roy

05 1900

No description available.

Metallic films

Heat Transmission

Vacuum

Heat transfer to liquid metals flowing turbulently in a pipe

Franklet, Duane LeRoy

08 1900

No description available.

Heat Transmission

Pipe Fluid dynamics

Oxygen enrichment in billet reheat furnaces

Edelblum, Lawrence Shawn

12 1900

No description available.

Metallurgical furnaces Combustion

Heat Transmission

Heat transfer to a fluid flowing turbulently in a smooth pipe with walls at constant temperature

Hefner, Robert James

05 1900

No description available.

Heat Transmission

Pipe Fluid dynamics

Momentum and heat transfer to a fluid flowing turbulently in a pipe

Hefner, Robert James

05 1900

No description available.

Heat Transmission

Pipe Fluid dynamics

A theoretical study of the condensation of pure vapors, gas-vapor mixtures, and binary vapor mixtures in laminar flow in the entrance region of a vertical tube

Burns, William Arthur

12 1900

No description available.

Condensation

Laminar flow

Heat Transmission

Heat transfer in variable density, low mach number, stagnating turbulent flows

Huval, Danny J.

05 1900

No description available.

Turbulence

Heat Transmission

Fluid dynamics

Study of the heat transfer mechanism from a submerged pulse combustor to a fluidized bed

Jeong, Hae-won

05 1900

No description available.

Chemical engineering

Combustion

Heat Transmission