A Study of Nonlinear Control for Power Generation Systems

Lu, Zongtao

12 October 2010

No description available.

Electrical Engineering

Wind Turbine

Turbine

Boiler-Turbine

An investigation into the operating characteristics of a high radius pre-swirl cooling system

New, Paul David

January 2002

No description available.

621

Turbine

Numerische Simulation des Fischdurchgangs durch Wasserturbinen

Böhm, Christian.

January 2004

München, Techn. Universiẗat, Diss., 2004.

Kaplan-Turbine

Experimental Validation of a Hot Gas Turbine Particle Deposition Facility

Smith, Christopher Stephen

25 August 2010

No description available.

Mechanical Engineering

turbine

deposition

gas turbine

turbine deposition

turbine aerodynamics

Predictions and Measurements of Film-Cooling on the Endwall of a First Stage Vane

Knost, Daniel G.

15 October 2003

In gas turbine development, the direction has been toward higher turbine inlet temperatures to increase the work output and thermal efficiency. This extreme environment can significantly impact component life. One means of preventing component burnout in the turbine is to effectively use film-cooling whereby coolant is extracted from the compressor and injected through component surfaces. One such surface is the endwall of the first stage nozzle guide vane. This thesis details the design, prediction, and testing of two endwall film-cooling hole patterns provided by leading gas turbine engine companies. In addition a flush, two-dimensional slot was included to simulate leakage flow from the combustor-turbine interface. The slot coolant was found to exit in a non-uniform manner leaving a large, uncooled ring around the vane. Film-cooling holes were effective at distributing coolant throughout much of the passage, but at low blowing rates were unable to provide any benefit to the critical vane-endwall junction both at the leading edge and along the pressure side. At high blowing ratios, the increased momentum of the jets induced separation at the leading edge and in the upstream portion of the passage along the pressure side, while the jets near the passage exit remained attached and penetrated completely to the vane surface. Computational fluid dynamics (CFD) was successful at predicting coolant trajectory, but tended to under-predict thermal spreading and jet separation. Superposition was shown to be inaccurate, over-predicting effectiveness levels and thus component life, because the flow field was altered by the coolant injection. / Master of Science

gas turbine

gas turbine heat transfer

endwall

Fatigue of an aluminium coated single crystal nickel-base Superalloy

Totemeier, Terry Craig

January 1994

No description available.

620.11223

Turbine blades

The analysis and design methods for turbomachinery flows

Tsay, W. C.

January 1989

No description available.

621.4352

Aerodynamics of turbine blades

Formation and effects of intermetallics in the rhenium-containing nickel-base superalloy CMSX-4

Proctor, Caroline Susan

January 1994

No description available.

669

Turbine blade alloys

Boundary layers on compressor blades

Dong, Yuan

January 1988

No description available.

629.1323

Turbine blade aerodynamics

Soot formation in turbulent vaporised kerosine/air jet flames at elevated pressure

Young, K. J.

January 1993

The objective of this thesis is to develop and validate a model of soot formation which is capable of being applied to a computational fluid dynamic (CFD) simulation of gas turbine combustion. The work follows previous research by Moss and Co-workers (Moss et al.1987, Syed 1990, Stewart et al.1991) The concept of the study is to generate a detailed set of experimental data in turbulent flames of kerosine in which the complicating factors of gas turbine combustion - that is 3D geometry and droplet combustion - are removed. This allows more confidence in the computational simulation of the flames and therefore more insight into the soot formation process. There are two components to the work: the experimental and theoretical studies. The first involves the compilation of an experimental dataset of key variables in ethylene and vaporised kerosine jet flames at elevated pressure, the second with the simulation of two of the experimentally studied flames using CFD methods. The main achievement of the study is the generation of a formidable and detailed experimental database for flames at a variety of pressures and conditions. The unexpected finding is the extremely large conversion of carbon to soot found in the flames even at low pressure. This results in high radiant heat losses and measurement difficulties. From the data, it is possible to assess the pressure dependence of soot growth in kerosine flames. Although, at the higher pressures, high soot levels created uncertainties in the measurements, in absolute terms growth rate is shown to be independent of pressure up to 6atm pressure. Above this it increases significantly. The soot model of Moss et al.1988 - originally developed in laminar e~hylene flames - was shown to give excellent agreement in turbulent situations. However, owing to the large radiant heat loss and soot levels, its application to the kerosine flames was more problematic since the assumptions that soot is a perturbation to the gaseous field and that temperature may be accurately described by a single perturbed flamelet were no longer valid. Further models to deal with such situations are proposed and tested. Aside from the obvious relevance of this study to the field of gas turbine combustion, the large radiant heat loss and high soot levels observed in the flames studied here imply a further significance for the study of fire hazards. That a laboratory scale flame maybe made to behave in a similar manner to a much larger pool fire flame is a very useful finding.

621.43

Gas turbine combustion