Abstract
The performance of gas turbine engines can be improved by increasing the inlet gas temperature. Turbine blades can be damaged by high gas temperature, unless additional cooling mechanisms are incorporated to maintain the blades below an acceptable temperature limit. Film cooling techniques are often used to cool the blades to avoid damages. The performance of film cooling depends on several parameters, however. In this paper past research on film cooling is reviewed and areas in need of further investigation are identified. Computational fluid dynamics (CFD) simulations are then conducted on the widely-used single-hole film cooling arrangements in which coolant jets are injected into air flows inside a straight channel before issuing onto the blades. Cooling pipe-blade configurations and flow conditions are varied and the resulting flow hydrodynamics are examined. Counter rotating vortex pairs (CRVPs) formed in the flow strongly influence the film cooling performance. Small coolant inclination angles, exit holes enlargement in span wise direction, higher injected fluid density, and higher injectedambient fluid velocity ratios are all found to maintain the CRVPs away from each other and close to wall - both of which promote cooling. Pipe curvature can be used for enhancing cooling by exploiting the centrifugal force effect.
Highlights
High gas inlet temperature is one of the major parameters that can increase the power output and cycle efficiency of gas turbine engines
The average film cooling effectiveness for all parametric cases are reported on Table 2
The jet maximum velocity is higher for those lower density ratio (DR) cases, and the jet penetrates deeper into the mainstream boundary layer leading to decreased film cooling effectiveness
Summary
High gas inlet temperature is one of the major parameters that can increase the power output and cycle efficiency of gas turbine engines. The inclination angle, pipe curvature, exit hole size and shape, fluid density and velocity ratios are varied parametrically to elucidate their influence on the hydrodynamics and film cooling effectiveness. Based on a literature survey, a set of coolant geometric features, such as pipe inclination angle, exit hole size and shape, pipe curvature, fluid density ratio, and velocity ratio are expected to influence the gas turbine film cooling effectiveness.
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