Ulrich Krupp and Alexander Gramlich at RWTH Aachen University, for example, are researching the influence of elements such as copper on the properties as well as the processability of various types of steel and are working on new approaches for tolerating higher copper concentrations.
Their research results show that copper contamination, which is unavoidable in steel recycling, has the potential to increase the hardness and strength of high-strength steels if it can be controlled during processing. If the heat treatment is adapted accordingly, the accumulation of copper can even have a positive effect on the mechanical properties.
In other research, Isnaldi R. Souza Filho, research group leader at the Max Planck Institute for Iron Research in Düsseldorf, et al. show that copper can be effectively vaporised from iron-copper-oxygen melts during hydrogen plasma-based melt reduction. Even without the presence of hydrogen, copper concentrations of 1 wt.% can be reduced to below 0.1 wt.%. The purified resulting iron-oxygen melt could be used for a subsequent reduction step. It is suggested that after reaching an acceptable copper level, the inert plasma source is replaced by a moderately reducing one to convert the oxide melt into pure iron. This reduction step could be carried out using either hydrogen or other circular carbon-based reducing agents. The result would be a melt that is free of copper impurities and suitable for further processing into high-quality iron as the basis for steel production.
4. Conclusion: Scrap as a key resource for sustainable steel production
For the green transformation of the steel industry, scrap is not just waste, but a valuable resource that paves the way for more sustainable production. Innovative projects such as Car2Car and the research work of leading experts emphasise the enormous potential of recycled material in reducing CO2 emissions and conserving primary resources.
The challenges associated with the increasing use of scrap, particularly in terms of quality and the handling of impurities, continue to require intensive research and development work. However, the efforts of steel producers, recycling companies and scientists clearly show that a circular economy in the steel sector is not only possible, but also essential for achieving global climate targets.