High-Temperature Structural Degradation and Finite Element Modelling

Module overview

This Level 7 module provides advanced theoretical understanding and computational modelling skills to assess high-temperature structural degradation in aerospace, power generation, and automotive engineering. Students will learn the theory and underlying mathematical frameworks used to describe key mechanisms such as creep deformation, thermo-mechanical fracture and fatigue, oxidation, and hot corrosion, and will examine how these processes influence component integrity in demanding service environments. The analytical content is integrated with finite-element simulations in ABAQUS, enabling students to build, apply, and interpret computational models of high-temperature behaviour in real-life engineering components such as aeroengine turbine blades, rocket engine nozzles, and nuclear reactor structures. By the end of the module, students will be able to diagnose dominant high-temperature failure modes, apply appropriate constitutive and fracture models, and use simulation tools to support design and failure analysis in engineering.

Syllabus

Introduction to high-temperature structural degradation Overview of structural integrity at elevated temperatures; relevance of high-temperature component failures in aeroengines, rocket engines, and nuclear reactors; role of materials, loading, and environment in failure mechanisms. Creep deformation and time-dependent behaviour Primary, secondary, and tertiary creep; Norton’s law and power-law creep; multiaxial creep; creep strain accumulation; Larson–Miller parameter and life prediction methods. Thermo-mechanical fatigue (TMF) and creep-fatigue interaction In-phase vs out-of-phase loading; low-cycle fatigue (LCF) at high temperature; hold-time effects; interaction of creep and fatigue; empirical and mechanistic models. Fracture mechanics at elevated temperature Time-dependent fracture, C* and Ct parameters, creep crack growth; J-integral and CTOD concepts for high-temperature applications; damage accumulation and continuum damage mechanics. Oxidation and hot corrosion effects High-temperature oxidation kinetics, scale formation and spallation; hot corrosion in gas-turbine and boiler environments; coupling of environmental effects with mechanical degradation. Constitutive modelling and mathematical frameworks Creep constitutive models; damage mechanics equations; mathematical formulation of high-temperature behaviour. Case studies: Finite-element modelling Lab using ABAQUS Simulation of creep and high-temperature fracture; 2D/3D component modelling; case studies on real-life engineering components such as turbine blades, rocket nozzles, and nuclear reactor structures; interpretation of stress, strain, and damage outputs. • ABAQUS lab: creep deformation of a pressurized cylinder or turbine blade section. • ABAQUS lab: high-temperature fracture simulation. • Data interpretation: comparison of simulation results with analytical or experimental creep/failure data.

Module overview

Aims and Objectives

Learning Outcomes

Syllabus

Learning and Teaching

Teaching and learning methods

Assessment

Repeat Information