Sustainability in Ironmaking: The Rise of Direct Reduction

Battle, Thomas P.

doi:10.1007/978-3-319-48234-7_25

Thomas P. Battle⁵

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Abstract

Modern-day direct reduction of iron first developed as a small-scale, low capital and operating cost alternative to the blast furnace. Since commercialization of continuous DR technology in the late 1960s, the market for the products of direct reduction has grown to more than 74 million tonnes in 2012. The initial advantages of DR plants over BF facilities have grown over the years, for several reasons, including the increased size of DR modules, lower energy and emissions (particularly CO₂), along with the flexibility to use a number of different reductants. The development of DR technology over the past forty years will be emphasized in this presentation, including recent developments that allow for even more direct sustainability comparisons with the iron blast furnace — and even combine the two technologies for improved synergies. Also briefly discussed will be the possibilities of using direct reduction for non-ferrous ores.

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Research and Development Technology Center Midrex Technologies, Pineville, North Carolina, 28134, USA
Thomas P. Battle

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Thomas P. Battle
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Curtin University, Australia
Eric J. Grimsey (emeritus professor of minerals engineering, chair of the institute’s Ethics Committee) (emeritus professor of minerals engineering, chair of the institute’s Ethics Committee)
AusIMM, Australia
Eric J. Grimsey (emeritus professor of minerals engineering, chair of the institute’s Ethics Committee) (emeritus professor of minerals engineering, chair of the institute’s Ethics Committee)
Pyrometallurgy Division, Mintek, South Africa
Rodney T. Jones
Faculty of Engineering and Industrial Sciences, High Temperature Processing research group, Swinburne University of Technology, Australia
Geoffrey A. Brooks (professor, leads) (professor, leads)

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Battle, T.P. (2014). Sustainability in Ironmaking: The Rise of Direct Reduction. In: Mackey, P.J., Grimsey, E.J., Jones, R.T., Brooks, G.A. (eds) Celebrating the Megascale. Springer, Cham. https://doi.org/10.1007/978-3-319-48234-7_25

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DOI: https://doi.org/10.1007/978-3-319-48234-7_25
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-48591-1
Online ISBN: 978-3-319-48234-7
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