The objective of the project PURESCRAP is to increase the use of low-quality scrap grades (post-consumer scrap) by deploying and applying best available technologies to reduce impurities. This is achieved through novel sensor combinations and analysis supported by artificial intelligence. A key part is the connection between scrap sorter and the steel industry which are the consumers of the scrap. This ensures that there is a demand for the enhanced purification and valorisation methods. The steel industry also enables the industrial scale verification of the PURESCRAP methods, where sorted scrap is used for steelmaking in semi-industrial and industrial scale. The shredding process is identified as the most promising method leading to impurity liberation and later removal, for which the site of the Swedish scrap supplier STENA is chosen for demonstration. With a better analysis of the scrap material after the sorting and preparation chain, appropriate material handling can be optimised for desired outputs. During the project, sensor stations will be integrated in the two separate processing chains for heavy (cut) and shredded scrap. The proposed innovation of PURESCRAP has the ambition to go far beyond industrial state-of-the-art to achieve a higher recycling rate of post-consumer scrap (increased share of low-quality scrap over the total scrap input by at least 40% or more) compared to the usual practice for a specific steel quality, whereas realistic grades are e.g., rail steel R260 (1.0623; EN13674) and engineering steel 42CrMo4 (1.7225; DIN EN10083). This clearly contributes to the Strategic Research and Innovation Agenda (SRIA ) of the Clean Steel Partnership, and to the achievement of the European Green Deal goals regarding circular economy as well as to the reduction of CO2 emissions. The outstanding performance of the proposed PURESCRAP sensor stations will be demonstrated through the implementation at industrial scale at a scrap supplier site.

The FReSMe project, From Residual Steel gases to Methanol, will produce a methanol that will be demonstrated in ship transportation. This green fuel will be produced from CO2, recovered from an industrial Blast Furnace, and H2 recovered both from the blast furnace gas itself, as well as H2 produced by electrolysis. The two different sources of H2 will enable (i) maximum use of the current residual energy content of blast furnace gas, while at the same time (ii) demonstrating a forward technology path where low carbon or renewable H2 become more ubiquitous. The project will make use of the existing equipment from two pilot plants, one for the energy efficient separation of H2 and CO2 from blast furnace gas, and one for the production of methanol from a CO2-H2 syngas stream. This can be realised with a small amount of extra equipment, including supplemental H2 production from an electrolyser and a H2/N2 separation unit from commercially available equipment. Methanol is a high volume platform chemical of universal use in chemical industry as well as applicable for fuelling internal combustion engines. As such it provides a promising pathway for the large scale re-use of CO2 to decarbonize the transportation and chemical sectors in Europe and decrease the dependence on fossil fuel imports. Production of methanol from CO2 offers the unique combination of scale, efficiency and economic value necessary to achieve large scale carbon reduction targets. The pilot plant will run for a total of three months divided over three different runs with a nominal production rate of up to 50 kg/hr from an input of 800 m3/hr blast furnace gas. This size is commensurate with operation at TRL6, where all the essential steps in the process must be joined together in an industrial environment. The project will address the new integration options that this technology has within the Iron and Steel industry and contains supplementary and supporting research of underlying phenomena.

INITIATE proposes a novel symbiotic process to produce urea from steel residual gases. The project will demonstrate a reduction in; primary energy intensity of 30%; carbon footprint of 95%; the raw material intensity of 40%; and waste production of 90%. Additional to this level of reduction, the concept represents a positive business case. INITIATE will demonstrate operating reliability and technology-based innovations in a real industrial setting at TRL7 by producing urea NH3 from steel residual gases as part of three test campaigns spanning six weeks each. The reduction in primary energy intensity, carbon footprint, raw material intensity and waste production will be assessed and verified on a regional and European level by advanced dynamic modelling and Life Cycle Assessment commiserated with ISO 14404 guidelines. The project will develop a commercial implementation roadmap for immediate deployment of INITIATE after project conclusion and for ensuring roll-out of INITIATE and similar symbiotic systems. Designing a robust and bankable first-of-a-kind commercial plant to produce urea from residual steel gases will allow implementation after project conclusion. Long term roll-out will be enabled by defining collaborative strategy for stakeholders alignment to implement INITIATE and similar symbiotic systems. Finally, effective and inclusive communication and dissemination of project results are maximized by organizing summer schools and creation of Massive Open Online Course. INITIATE will take advantage of a consortium spanning the full value chain, including major steel and urea industrial players (Arcelor Mittal, SSAB, Stamicarbon, NextChem), functional material suppliers (Johnson Matthey, Kisuma Chemicals), multi-disciplinary researchers (TNO, POLIMI, Radboud University) and experienced promoters of CCUS, circularity and symbiosis topics to public (CO2 Value Europe).

Currently, NG is normally substituted by hydrogen in upstream processes (both blast furnace and DRI), or limited application in finishing lines. Current downstream processes totally rely on NG burning as thermal source. Therefore, the massive usage of hydrogen in steel industry, as envisioned in the Carbon Direct Avoidance pathway of the ESTEP/EUROFER masterplan, requires a transformation of entire steelmaking process from liquid production process (UPSTREAM) to the rolling and finishing line (DOWNSTREAM). This research project is aimed at adopting hybrid heating technology (based on NG with progressive and increasing H2 utilization) in downstream processes. Thermal treatment and reheating processes, which are common to both BF and EAF route have a significant NG demand (about 50 Nm3/t of produced steel). also utilization for ladle preheating has a relevant NG demand (in the range 5-15 Nm3/t). In order to allow the shift from NG to H2 and consequently to reduce the environmental impact by using innovative combustion technologies (like flameless and oxyfuel combustion), impacts on steel quality, refractory and furnace must be assessed at high TRL (7). The general objective of this project is to exploit the hybrid heating technologies by evaluating the effects of the steel products, on the refractories and also on the combustion systems. Three Demo cases testing innovative multifuel burner and testing the limit of current systems at TRL 7 will facilitate the hydrogen transition of the steel sector. Achieved results will bring to a CO2 saving in the range 7.5-25Mt/year. Regarding the steel quality, the project activities will individuate the optimum processing parameters to ensure that primary scale and associated scale defects do not persist through to the final product.

STEPWISE is a solid sorption technology for CO2 capture from fuel gases in combination with water-gas shift and acid gas removal. The main objectives of the proposed STEPWISE project is to scale up the technology for the CO2 capture from Blast Furnace Gases (BFG) with three overall demonstration goals in comparison to state-of-the-art amine-based technologies: • Higher carbon capture rate – i.e. lower carbon intensity, 85% reduction • Higher energy efficiency – i.e. lower energy consumption for capture (SPECCA ), 60% reduction • Better economy – i.e. lower cost of CO2 avoided, 25% reduction The STEPWISE project will achieve this by the construction and the operation of a pilot test installation at a blast furnace site enabling the technology to reach TRL6 as the next step in the research, development and demonstration trajectory. Hence further reducing the risk of scaling up the technology. The STEPWISE project has the potential to decrease CO2 emissions worldwide by 2.1Gt/yr based on current emission levels. The conservative estimate is that by 2050, a potential cost saving of 750 times the research costs for this project will be realized each year every year, with a much larger potential. The overall objective is to secure jobs in the highly competitive European steel industry, a sector employing 360 thousand skilled people with an annual turnover of €170 billion.