Thermo-mechanical behaviour of pearlitic railway steels
Doktorsavhandling, 2024
Railway operations and maintenance activities typically involve high levels of localised stresses and temperatures. The material behaviour of common pearlitic railway steels has previously been studied under thermal and different mechanical loadings, respectively. However, in service the material occasionally experiences these loads simultaneously, which results in a complex thermo-mechanical loading. This thesis attempts to characterise the material behaviour of rail and railway wheel steel when exposed to thermo-mechanical loads. The effect of localised heating events is studied, and the influence of process parameters are investigated.
This thesis work encompasses both slow and rapid local heating events, with the objective of investigating changes in the mechanical behaviour, microstructure and residual stress states. A slow heating cycle was employed to simulate severe block braking on railway wheel material. This was studied through thermo-mechanical cycling to peak temperatures varying between 300 °C and 650 °C, while the thermal dilatation was restricted to different degrees between free expansion and full restriction. Rapid heating and cooling events were studied by using laser heating. Laser sources from PBF-LB additive manufacturing equipment and laser welding equipment were used to simulate local heating events.
It was seen that thermo-mechanical loads result in strongly temperature-dependent material behaviour; however, the effect most notable is the resulting residual stress state in the material after testing. For the slow thermal cycles, as experienced during severe block braking, it can be concluded that overheating of the wheel rim does not have severe consequences for the mechanical properties of the wheel. Quantification of spheroidisation in the wheel rim showed that increased loads at these high temperatures could have a beneficial effect on the material properties. This thesis work made use of novel approaches, such as the laser heating experiments, that can be useful to simulate also other local heating events and thereby characterise the material behaviour.
The findings presented in this thesis provide insight into the material behaviour of railway steels during local heating events under conditions similar to those observed in practice. These insights can be used to inform railway wheel design, rail and wheel maintenance procedures, and component replacement limits. Furthermore, the work has been implemented and used for verification of simulations in parallel activities and provide an experimental basis for the further development of predictive models.
This thesis work encompasses both slow and rapid local heating events, with the objective of investigating changes in the mechanical behaviour, microstructure and residual stress states. A slow heating cycle was employed to simulate severe block braking on railway wheel material. This was studied through thermo-mechanical cycling to peak temperatures varying between 300 °C and 650 °C, while the thermal dilatation was restricted to different degrees between free expansion and full restriction. Rapid heating and cooling events were studied by using laser heating. Laser sources from PBF-LB additive manufacturing equipment and laser welding equipment were used to simulate local heating events.
It was seen that thermo-mechanical loads result in strongly temperature-dependent material behaviour; however, the effect most notable is the resulting residual stress state in the material after testing. For the slow thermal cycles, as experienced during severe block braking, it can be concluded that overheating of the wheel rim does not have severe consequences for the mechanical properties of the wheel. Quantification of spheroidisation in the wheel rim showed that increased loads at these high temperatures could have a beneficial effect on the material properties. This thesis work made use of novel approaches, such as the laser heating experiments, that can be useful to simulate also other local heating events and thereby characterise the material behaviour.
The findings presented in this thesis provide insight into the material behaviour of railway steels during local heating events under conditions similar to those observed in practice. These insights can be used to inform railway wheel design, rail and wheel maintenance procedures, and component replacement limits. Furthermore, the work has been implemented and used for verification of simulations in parallel activities and provide an experimental basis for the further development of predictive models.
laser heating
thermo-mechanical behaviour
residual stress
railway wheel steel
martensite
spheroidisation
pearlitic microstructure
Virtual Development Laboratory (VDL), Chalmers Tvärgata 4C
Opponent: Dr Klaus Six, Virtual Vehicle, Austria
Författare
Erika Steyn
Chalmers, Industri- och materialvetenskap, Konstruktionsmaterial
E. Steyn, J. Ahlström. Thermo-mechanical response of near-pearlitic steel heated under restriction of thermal expansion
E. Steyn, J. Ahlström. The effect of thermo-mechanical loading on the microstructure evolution in near-pearlitic steel
Thermomechanical testing and modelling of railway wheel steel
International Journal of Fatigue,; Vol. 168(2023)
Artikel i vetenskaplig tidskrift
E. Steyn, B. Andersson, J. Ahlström. Thermal pulses on pearlitic steels: Influence of laser scanning parameters on surface layers transforming to martensite
E.Steyn, J. Ahlström. Martensite formation due to thermal loading during rail grinding on pearlitic rail steel
Rail machining - current practices and potential for optimisation
Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit,; Vol. 238(2024)p. 196-205
Artikel i vetenskaplig tidskrift
With the global focus on sustainability, the European Union is committed to reducing greenhouse gases and carbon emissions by 90% over the next two decades. The transport sector is responsible for almost a third of greenhouse gas emissions in Europe, with rail transport being the lowest contributor. To reach this goal, the plan is to develop a sustainable trans-European rail network where high-speed traffic will be tripled, and rail freight traffic doubled. It's important to understand how common railway steels behave and what affects them during manufacturing, operation and maintenance of the tracks and wheels to make sure the railway network runs safely and smoothly.
Imagine the weight of 5 large cars, concentrated on each contact surface between wheels and rails as small as a coin. You probably also know that rubbing two surfaces together will generate heat. If the weight of the railway wagon is 100 metric tonnes, it can get really hot in the eight tiny contact surfaces on braking or accelerating. Now you can imagine the stress the wheel and rail surfaces are experiencing in service. The combination of high stress and high temperature is affecting the steel in the wheel in various ways, which we need to know about for clever railway operation. In this project, I describe the way that the material behaves under these conditions during laboratory testing, and by studying the stress remaining in the sample after testing.
Better understanding the material behaviour during operations or maintenance helps us to improve maintenance processes and strategies. This will contribute to reaching the sustainability goals, but also to getting you to your destination on time.
Imagine the weight of 5 large cars, concentrated on each contact surface between wheels and rails as small as a coin. You probably also know that rubbing two surfaces together will generate heat. If the weight of the railway wagon is 100 metric tonnes, it can get really hot in the eight tiny contact surfaces on braking or accelerating. Now you can imagine the stress the wheel and rail surfaces are experiencing in service. The combination of high stress and high temperature is affecting the steel in the wheel in various ways, which we need to know about for clever railway operation. In this project, I describe the way that the material behaves under these conditions during laboratory testing, and by studying the stress remaining in the sample after testing.
Better understanding the material behaviour during operations or maintenance helps us to improve maintenance processes and strategies. This will contribute to reaching the sustainability goals, but also to getting you to your destination on time.
Materialkarakteristik vid svetsning och annan lokal upphettning (CHARMEC MU36)
Chalmers järnvägsmekanik (CHARMEC) (MU36), 2019-06-10 -- 2024-06-09.
Europeiska kommissionen (EU), 2019-06-10 -- 2024-06-09.
Drivkrafter
Hållbar utveckling
Styrkeområden
Transport
Materialvetenskap
Ämneskategorier
Teknisk mekanik
Metallurgi och metalliska material
Fundament
Grundläggande vetenskaper
ISBN
978-91-8103-045-7
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5503
Utgivare
Chalmers
Virtual Development Laboratory (VDL), Chalmers Tvärgata 4C
Opponent: Dr Klaus Six, Virtual Vehicle, Austria