Thermo-Mechanical-Metallurgical Modelling of Pearlitic Steels and Railhead Repair Welding
Doktorsavhandling, 2024
The framework consists of a material model that incorporates cyclic hardening plasticity, phase transformation kinetics, transformation-induced plasticity, multi-phase homogenisation, and recovery of the virgin material state after cyclic melting and solidification. The ability of the model to simulate intricate thermo-metallurgical-mechanical behaviour is demonstrated in quasi-static material point simulations. The material model is implemented in a finite element framework to obtain a simulation-based tool that balances computational efficiency, simulation fidelity, and engineering applicability. Several simulations demonstrate the effectiveness of this tool, including simulations of a wheel flat, laser-induced martensitic patches on the rail surface, and railhead repair welding processes. The simulation-tool is also validated against experimental data, in terms of residual material states after high-temperature processes.
The thesis provides insights into the evolution of material phases and stresses under thermal loading in high-temperature railway processes, as well as the redistribution of residual stresses during subsequent operational loading conditions. For instance, simulations of the railhead repair welding process indicate that pre-heating has a minor impact on the quality of the repair, while the welding build-up paths have a significant impact. The simulations also highlight the critical region for fatigue crack initiation by showing how residual tensile stresses are reduced near the surface of the rail or wheel and increased at some distance below during operation for the repaired rail.
Pearlitic steels
Railhead repair
Welding simulations
Phase transformations
Cyclic plasticity
Finite element analysis
Homogenisation
Författare
Björn Andersson
Chalmers, Industri- och materialvetenskap, Material- och beräkningsmekanik
This thesis presents the development of a simulation-based assessment tool that incorporates thermo-mechanical-metallurgical modelling of how railway steel behaves when subjected to repeated intense heat and mechanical load. This tool is used to simulate various scenarios such as train wheel brake lockups and railhead repair welding. By testing these simulations against real-world data, it is shown that the approach works and that it can actually help to identify where problems might occur and how they can be prevented. Put simply, the research presented in this thesis aims to make train travel smoother, more sustainable and safer for everyone.
Numerisk simulering av svetsning och andra högtemperaturprocesser (CHARMEC MU37)
Chalmers järnvägsmekanik (CHARMEC) (MU37), 2019-03-18 -- 2024-03-15.
Europeiska kommissionen (EU), 2019-03-18 -- 2024-03-15.
Drivkrafter
Hållbar utveckling
Ämneskategorier
Teknisk mekanik
Annan materialteknik
Farkostteknik
Metallurgi och metalliska material
Fundament
Grundläggande vetenskaper
Styrkeområden
Materialvetenskap
Infrastruktur
Chalmers e-Commons
ISBN
978-91-8103-017-4
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5475
Utgivare
Chalmers
Virtual Development Laboratory and online (password: 821697)
Opponent: Professor Håkan Hallberg, Solid Mechanics, Lund University, Sweden