Abstract
Primary aluminium production is energy- and GHG-intensive in which electrolysis is by far the most energy- and GHG-intensive process. This paper’s aim is to study the effects on (1) primary energy use, (2) GHG emissions and (3) energy and CO2 costs when energy end-use efficiency measures are implemented in the electrolysis. Significant savings in final and primary energy use, GHG emissions and energy and CO2 costs can be achieved by implementing the studied measures. Vertical electrode cells and the combination of inert anodes and wettable cathodes are among the measures with the highest savings in all three areas (primary energy use, GHG emissions and energy and CO2 costs). Direct carbothermic reduction is one of the measures with the highest savings in primary energy use and energy and CO2 costs. For GHG emissions, direct carbothermic reduction is the more beneficial choice in regions with a high proportion of coal power, while inert anodes are the more beneficial choice in regions with a high proportion of low-carbon electricity. Although a company potentially can save more money by implementing the direct carbothermic reduction, the company should consider implementing the vertical electrode cells together with other energy-saving technologies since this would yield the largest GHG emission savings while providing similar cost savings as the direct carbothermic reduction. It may be necessary to impose a price on GHG emissions in order to make inert anodes cost-effective on their own, although further evaluations are needed in this regard. There is a potential to achieve carbon-neutrality in the reduction of aluminium oxide to pure aluminium.
Highlights
Political goals have been formulated at international (UN 2015; UNDP 2015), European (European Comission n.d.) and national (Sweden) (Swedish Energy Agency 2019; Government Offices of Sweden 2017) levels regarding improved energy efficiency, reduced environmental impact, increased share of renewables and increased sustainability
The aim of this paper is to study the effects on (1) primary energy use, (2) GHG emissions and (3) energy and CO2 costs when energy end-use efficiency measures are implemented in the electrolysis process in primary aluminium production
Vertical electrode cells and the combination of inert anodes and wettable cathodes are among the measures with the highest savings in all three areas
Summary
Political goals have been formulated at international (UN 2015; UNDP 2015), European (European Comission n.d.) and national (Sweden) (Swedish Energy Agency 2019; Government Offices of Sweden 2017) levels regarding improved energy efficiency, reduced environmental impact, increased share of renewables and increased sustainability. The industrial sector accounted for 37% of global final energy use and 24% of global direct CO2 emissions (including both energyand process-related emissions) in 2017 (International Energy Agency 2019a). The electrolysis process utilises the electrolytic reduction of aluminium oxide to produce pure aluminium, with electricity as the main energy carrier (Haraldsson and Johansson 2018). There are so-called anode effects, which are disturbances to the process in which an insufficient amount of aluminium oxide is dissolved in the electrolyte bath, resulting in the emission of the perfluorocarbons (PFCs) CF4 and C2F6 (International Aluminium Institute 2019a), which are two GHGs with a high global warming potential. A similar technology is expected to produce aluminium at 11.5–11.8 MWh/tonne Al and a pilot test was initiated in 2018 (Svendsen 2018)
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