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Computational fluid dynamics

At the Unit of Processes, we use computational fluid dynamics to simulate steelmaking processes. We then use water modelling to test the simulations and work with industry partners to bring our innovations to full deployment.

Examples:

  • The development of new ingot casting strategies to minimise turbulence and incorporation of oxide into the metal.
  • Scaling up of an ironmaking process that uses plasma to heat and reduce the oxide. We work to ensure good mixing even in large scales.
  • Fundamental investigations of chemical reactions in the argon axygen decarburisation (AOD) converter to maximise removal of carbon and minimise loss of other elements.
  • Simulation and experiments to understand the behaviour of bubbles in liquids to optimise stirring in steelmaking.

Contact

Mikael Ersson
Mikael Ersson
Responsible for Computational fluid dynamics
Profile
Page responsible:webmaster@mse.kth.se
Belongs to: Materials Science and Engineering
Last changed: Apr 16, 2021
Casting
Optimization of the ingot casting process by minimising macrosegregation and porosity
Avoiding cracking during casting of a duplex stainless steel
Development and Application of an Operator Vision Assistance System for Enhanced Direct Process Control in Foundries
HIYIELD - Highly Efficient Technologies for Increased Yields in Steelmaking Processes and Reduced Environmental Impact
Clean metallurgy
FerroSilva - fossil-free virgin steel from iron ore and biogenic reduction gas
Optimisation of the oxygen use in EAF steelmaking by direct process monitoring of the chemical melt reactions
Computational fluid dynamics
Variable nozzle height in AOD converter, stage 2
Control of nitrogen content in the production of stainless steel
Raw Ideas for Materials Projects
Energy and furnace technology
A multiscale and multifunction Cascade Catalytic Fast Pyrolysis of lignocellulose for the production of gasoline- diesel range fuel for transportation section
Sustainable technology for the staged recovery of an agricultural water from high moisture fermentation products
Recycling plastic wastes to valuable chemicals of monoaromatics and metals through catalytic-pyrolysis
Optimized biofuel-production via two-step upgrading via catalytic pyrolysis and hydrotreatment
Electrified-Catalytic Reforming using 3D printed catalysts for Biomethane production from biomass pyrolysis
Gradient control in thin film solar cells
Flexible Ladle Preheating Procedures using Plasma Heated Refractory
Control of Metallurgical Processes with indirect measurements and Machine Learning
Optimization and Performance Improving in Metal Industry by Digital Technologies
BLast furnace stack density Estimation through on-line Muons ABsorption measurements
INEVITABLE
High-temperature experimental kinetics
Powder metallurgy
Digitalisation of Atomisation
Direct reduction of alloy metals
Advanced design, monitoring , development and validation of novel HIgh PERformance MATerials and components