Stall inception in axial compressors

McDougall, Neil Malcolm

January 1988

No description available.

532

Gas turbine compressor flow

Surface coatings on titanium alloys to limit oxygen ingress

Deakin, M. J.

January 1995

No description available.

669

Gas turbine coatings; Electroplating

Discharge coefficient of film cooling holes with rounded entries or exits

Khaldi, A.

January 1987

No description available.

629.1323

Gas turbine blade crossflow

The aerodynamic effects of nozzle guide vane shock wave and wake on a transonic turbine rotor

Johnson, A. B.

January 1988

No description available.

621.4352

Gas turbine flow efficiency

Film-cooling in the presence of mainstream pressure gradients and foreign gas injection

Teekaram, Arnold J. H.

January 1989

No description available.

536.7

Gas turbine aero-engines

Heat transfer on nozzle guide vane end walls

Harvey, Neil William

January 1991

No description available.

536.7

Gas turbine heat transfer

Blade surface pressure measurements on the rotor of a model turbine stage in a transient flow facility

Dietz, Anthony John

January 1990

No description available.

532

Flow in a gas turbine engine

Compressible flow pressure losses in branched ducts

Abou-Haidar, Nabil Ibrahim

January 1989

No description available.

532

Gas turbine flow paths

Stability of split flow fans

Tzannatos, E.

January 1986

The performance requirements of turbofan engines demands a stability and transient capability beyond that associated with the past generations of gas turbine engines. The axial flow fan unit is most vulnerable to loading limitations due to the primary problems associated with the compression process, its sensitivity to inlet distortion and the difficulty to design for an overall optimum blade duty in a machine of wide radial blade loading distribution. The development of mathematical models with some capability of predicting the stable operating range of an axial flow fan has to overcome the difficulties associated with the modelling of the radially distinct flow regions and their dynamic interaction. ' The current investigation combined the available knowledge of one-dimensional models (based on the principles of conservation of mass, linear momentum and energy) with the assumptions of the parallel compressor theory, in order to develop a linearized system of equations for stability analysis (surge prediction). The stability conditions which emerged from this approach were applied on the experimentally derived characteristics of a low hub to tip ratio split flow fan in a manner which involved the modelling of the dynamic interaction of the inner and outer flow region of the fan. The development of the governing equations was achieved by applying one-dimensional flow analysis to the inner and outer section of the fan. Their interaction was modelled on the experimentally obtained radial movement of the splitter streamline and the discharge ,static pressure 'radial distribution. The inner and outer region were treated as a lumped volume element search operating on a local masflow averaged total pressure rise characteristic and alternatively acting in conjunction with a common nozzle and separate nozzles. The experimental investigation was carried out on a low hub totipratio two-stage split flow fan(with the facility of independent bypass and core throttles)in order to examine the localised and overall performance of such a fan(and the staling processes involved)and to enable the application of the stability analysis. The influence of reducing the distance between the fan flow spliter and the last bladerowasal so investigated, «The mathematical mode1s predicted the point of dynamic instability within 4.52 of the experimental observed mas flow rate and pressure is value.

621.4352

Gas turbine engine performance

Study of gas turbine ingress using computational fluid dynamics

Wang, Le

January 2013

The ingestion of hot mainstream gas into the wheel-space between the rotor and staler discs is one of the most important internal cooling problems for gas turbine designers. To solve this problem, engineers design a rim seal at the periphery of wheel-space and direct a sealing flow from the internal cooling system to prevent ingress. The main aim of this thesis is to build a simple computational model to predict the scaling effectiveness of externally-induced ingress for engine designers. The axisymmetric model represents a gas turbine wheel-space and provides useful information related to the fluid dynamics and heat transfer in the wheel-space. At the same time, this model saves much computation time and cost for engine designers who currently use complex and time-consuming 3D models. The- computational model in this -thesis is called the prescribed ingestion model. Steady simulations are carried out using the commercial CFD code, ANSYS CFX with meshes built using ICEM CFD. Boundary conditions are applied at the ingress inlet of the model using experimental measurements and a mass-based averaging procedure. Computational parameters such as rotational Reynolds number, non-dimensional sealing flow rate and thermal conditions on the rotor are selected to investigate the fluid dynamics and heat transfer at typical experimental rig operating conditions. Different rim seal geometries arc investigated and results are compared with experimental data. In addition to the prescribed ingestion model, two typical axisymmetric rotor-stator system models without ingress arc established. The aim of these rotor-stator models is to investigate the fluid dynamics and heat transfer of the wheel-space in the situation without ingress. The effects of geometry and turbulence model also arc studied in these simulations. Most results from these simulations are in good agreement with experimental data from the literature, which enhances confidence in the prescribed Ingestion model.

621.433

CFD ; gas turbine ; ingress