What Shall We Do with Steel Mill Off-Gas: Polygeneration Systems Minimizing Greenhouse Gas Emissions

Abstract: Both the global steel and chemical industries contribute largely to industrial greenhouse gas (GHG) emissions. For both industries, GHG emissions are strongly related to the consumption of fossil resources. While the chemical industry often releases GHGs as direct process emissions, steel mills globally produce 1.78 Gt of off-gases each year, which are currently combusted for subsequent heat and electricity generation. However, these steel mill off-gases consist of high value compounds, which also can be utili… Show more

“…Several promising alternative pathways for syngas have been developed in recent years: bio-based production, CO 2 -based production via carbon capture and utilization (CCU), and steel mill off-gas (mill gas) separation. These three alternative pathways can reduce syngas’ GHG emissions compared to their fossil-based counterparts. − However, these GHG reductions depend on several factors, such as the carbon intensity of electricity and heat, and each syngas technology shows its own characteristics.…”

“…Instead, mill gases can be separated and used as feedstock for chemicals. Thereby, mill gases can reduce life-cycle GHG emissions of products since valuable chemical intermediates are recovered. , Some mill gases are particularly suited for chemical production since they contain large amounts of H 2 or CO . However, the environmental benefits of mill gas use depend on the composition of the mill gases and the efforts for separation.…”

“…However, the environmental benefits of mill gas use depend on the composition of the mill gases and the efforts for separation. Furthermore, the internal heat and electricity supply currently covered by mill gas treatment must then be covered by other energy sources …”

“…The maximum amount of mill gas per 1 kg syngas is 1.1 kg of COG with a heating value of 38.5 MJ/kg and 1.9 kg of BOFG with a heating value of 5.4 MJ/kg. We adopt the power plants’ electric efficiency of 34% and the thermal efficiency of 15% from Ecoinvent 3.5 (details are given in the Supporting Information), resulting in reference flows of 7.5 MJ heat and 17.7 MJ electricity. , …”

“…Furthermore, the internal heat and electricity supply currently covered by mill gas treatment must then be covered by other energy sources. 9 Due to the multitude of options, industry and policymakers can choose between alternative syngas pathways. Current decision-making primarily relies on economic aspects and regional feedstock availability.…”

Syngas from What? Comparative Life-Cycle Assessment for Syngas Production from Biomass, CO₂, and Steel Mill Off-Gases

“…Several promising alternative pathways for syngas have been developed in recent years: bio-based production, CO 2 -based production via carbon capture and utilization (CCU), and steel mill off-gas (mill gas) separation. These three alternative pathways can reduce syngas’ GHG emissions compared to their fossil-based counterparts. − However, these GHG reductions depend on several factors, such as the carbon intensity of electricity and heat, and each syngas technology shows its own characteristics.…”

“…Instead, mill gases can be separated and used as feedstock for chemicals. Thereby, mill gases can reduce life-cycle GHG emissions of products since valuable chemical intermediates are recovered. , Some mill gases are particularly suited for chemical production since they contain large amounts of H 2 or CO . However, the environmental benefits of mill gas use depend on the composition of the mill gases and the efforts for separation.…”

“…However, the environmental benefits of mill gas use depend on the composition of the mill gases and the efforts for separation. Furthermore, the internal heat and electricity supply currently covered by mill gas treatment must then be covered by other energy sources …”

“…The maximum amount of mill gas per 1 kg syngas is 1.1 kg of COG with a heating value of 38.5 MJ/kg and 1.9 kg of BOFG with a heating value of 5.4 MJ/kg. We adopt the power plants’ electric efficiency of 34% and the thermal efficiency of 15% from Ecoinvent 3.5 (details are given in the Supporting Information), resulting in reference flows of 7.5 MJ heat and 17.7 MJ electricity. , …”

“…Furthermore, the internal heat and electricity supply currently covered by mill gas treatment must then be covered by other energy sources. 9 Due to the multitude of options, industry and policymakers can choose between alternative syngas pathways. Current decision-making primarily relies on economic aspects and regional feedstock availability.…”

Syngas from What? Comparative Life-Cycle Assessment for Syngas Production from Biomass, CO₂, and Steel Mill Off-Gases

Integrated Phosgene and Steel Production: Combining Process Optimization and Life Cycle Assessment to Minimize Greenhouse Gas Emissions

Mathematical Modelling of Reactors Used for Syngas Fermentation—Contemporary Practices and Challenges