Mechanical Integrity of Gas Turbines

Core content

The course includes detailed coverage of the following topics:

How the Loads Arise

The origin of loads in a gas turbine engine is discussed. The major loads covered are those due to the engine cycle, rotational inertia, flight manoeuvre, precession, pressure, thermal gradient, torsion, seizure and blade release. Engine Mounting and bearing loads are also included.

Failure Criteria

At this stage the iterative loop load-geometry-stress-failure-redesign is completed by defining the various ways in which a material may fail and its strength defined. Monotonic properties,proof, ultimate etc. Creep properties, Larson-Miller, cumulative effects. Fatigue properties, SN and RM diagrams, influences such as stress concentration, mean stress etc. Cumulative fatigue, LCF, double-Goodman diagram technique, lifing rules, Neuber, “Rainflow” cycle counting. Fracture, LEFM, stress intensity factors, lifing from the Paris curve, damage tolerance, “retirement for cause” etc.

Applications

At this point methods for the design of specific components such as discs and blades are introduced: Axial flow discs, stressing by means of a discretised hand-technique which illustrates the distribution and relative magnitude of stresses within a conventional disc. Discussion of blade attachments. Axial flow blades: illustration of magnitude and distribution of stresses in a conventional axial flow blade by means of simple desk top methods, blade leaning etc. Flanges and bolted structures: design of flanged/bolted structures to resist leakage and failure from fatigue, bolt pitching rules etc.

Vibration

In this section the main processes carried out by the vibration engineer are described. Determination of the natural frequencies of components such as blades, disc etc. both experimentally and from simple analytical techniques. In particular a reasonably accurate method for the determination of low-order natural frequencies of turbomachine blades are developed. Sources of excitation: stationary flow disturbances etc. Derivation of a figure which resonances may be identified, named variously the Campbell diagram, interference diagram, spoke diagram etc. Allowance for temperature, pre-twist and centrifugal stiffness. A methodology for dealing with resonances. Shaft Dynamics: critical speeds, squeeze-film dampers.

Gas Turbine Materials

Gas Turbine materials are required to withstand extreme stresses sometimes at temperatures in excess of their melting point. An overview of the latest materials technology for both hot and cold components is provided. The lectures cover advances in compressor blade materials, the technologies used in the manufacture of high temperature turbine blades and materials coating technologies.