3 research outputs found
Charcoal as an alternative reductant in ferroalloy production: A review
This paper provides a fundamental and critical review of biomass application as renewable reductant in integrated ferroalloy reduction process. The basis for the review is based on the current process and product quality requirement that bio-based reductants must fulfill. The characteristics of different feedstocks and suitable pre-treatment and post-treatment technologies for their upgrading are evaluated. The existing literature concerning biomass application in ferroalloy industries is reviewed to fill out the research gaps related to charcoal properties provided by current production technologies and the integration of renewable reductants in the existing industrial infrastructure. This review also provides insights and recommendations to the unresolved challenges related to the
charcoal process economics. Several possibilities to integrate the production of bio-based reductants with bio-refineries to lower the cost and increase the total efficiency are given. A comparison of challenges related to energy efficient charcoal production and formation of emissions in classical kiln technologies are discussed to underline the potential of bio-based reductant usage in ferroalloy reduction process
Life cycle assessment of renewable reductants in the ferromanganese alloy production: a review
This study examined the literature on life cycle assessment on the ferromanganese alloy
production route. The environmental impacts of raw material acquisition through the production of
carbon reductants to the production of ferromanganese alloys were examined and compared. The
transition from the current fossil fuel-based production to a more sustainable production route was
reviewed. Besides the environmental impact, policy and socioeconomic impacts were considered
due to evaluation course of differences in the production routes. Charcoal has the potential to
substantially replace fossil fuel reductants in the upcoming decades. The environmental impact
from current ferromanganese alloy production can be reduced by ≥20% by the charcoal produced
in slow pyrolysis kilns, which can be further reduced by ≥50% for a sustainable production in
high-efficient retorts. Certificated biomass can ensure a sustainable growth to avoid deforestation
and acidification of the environment. Although greenhouse gas emissions from transport are low
for the ferromanganese alloy production, they may increase due to the low bulk density of charcoal
and the decentralized production of biomass. However, centralized charcoal retorts can provide
additional by-products or biofuel and ensure better product quality for the industrial application.
Further upgrading of charcoal can finally result in a CO2 neutral ferromanganese alloy production
for the renewable power supply
Life cycle based climate emissions of charcoal conditioning routes for the use in the ferro-alloy production
Renewable reductants are intended to significantly reduce CO2 emissions from ferro-alloy production, e.g., by up to 80% in 2050 in Norway. However, charcoals provide inferior properties compared to fossil fuel-based reductants, which can hamper large replacement ratios. Therefore, conditioning routes from coal beneficiation was investigated to improve the inferior properties of charcoal, such as mechanical strength, volatile matter, CO2 reactivity and mineral matter content.To evaluate the global warming potential of renewable reductants, the CO2 emissions of upgraded charcoal were estimated by using a simplified life cycle assessment, focusing on the additional emissions by the energy demand, required chemicals and mass loss for each process stage. The combination of ash removal, briquetting and high-temperature treatment can provide a renewable coke with superior properties compared to charcoal, but concomitantly decrease the available biomass potential by up to 40%, increasing the CO2-based global warming potential of industrial produced charcoal to ≈500 kg CO2-eq. t−1 FC. Based on our assumptions, CO2 emissions from fossil fuel-based reductants can be reduced by up to 85%. A key to minimizing energy or material losses is to combine the pyrolysis and post-treatment processes of renewable reductants to upgrade industrial charcoal on-site at the metallurgical plant. Briquetting showed the largest additional global warming potential from the investigated process routes, whereas the high temperature treatment requires a renewable energy source to be sustainable.</p