Evaluation of the Potential for Reduction of CO2 Emissions at the Secondary Metallurgy

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@article{8b40540ba84c47ab8082a4890dbef435,
title = "Evaluation of the Potential for Reduction of CO2 Emissions at the Secondary Metallurgy",
abstract = "Policies all over the world encourage the high energy efficiency of processes and the reduction of greenhouse gas (GHG) emissions, classified as direct and indirect. Iron and steelmaking is energy intensive industry, which also contributes 30% of the direct global CO2 emissions (2007), triggered through the industrial processes [1]. This article focuses on the verification of the CO2 emissions distribution for the secondary steelmaking.The potential for reduction of these emissions depends on the following key factors of ladle logistics and temperature losses under consideration of the steel contact time, additions during tapping, treatment at the ladle furnace to compensate temperature losses, and ladle preheating.",
keywords = "Secondary Metallurgy, CO2 Emission Reduction, ladle logistics, alloying concepts, CO2-Reduction, Secondary metallurgy, emission",
author = "Andrey Gerasev and Philip Bundschuh and Johannes Schenk and Andreas Viertauer and Bernd Trummer and Gregor Arth and Roman R{\"o}ssler and Peter Reisinger",
year = "2016",
month = nov,
day = "1",
language = "English",
volume = "2016",
pages = "28--34",
journal = "RHI bulletin : the journal of refractory innovations",
number = "1",

}

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TY - JOUR

T1 - Evaluation of the Potential for Reduction of CO2 Emissions at the Secondary Metallurgy

AU - Gerasev, Andrey

AU - Bundschuh, Philip

AU - Schenk, Johannes

AU - Viertauer, Andreas

AU - Trummer, Bernd

AU - Arth, Gregor

AU - Rössler, Roman

AU - Reisinger, Peter

PY - 2016/11/1

Y1 - 2016/11/1

N2 - Policies all over the world encourage the high energy efficiency of processes and the reduction of greenhouse gas (GHG) emissions, classified as direct and indirect. Iron and steelmaking is energy intensive industry, which also contributes 30% of the direct global CO2 emissions (2007), triggered through the industrial processes [1]. This article focuses on the verification of the CO2 emissions distribution for the secondary steelmaking.The potential for reduction of these emissions depends on the following key factors of ladle logistics and temperature losses under consideration of the steel contact time, additions during tapping, treatment at the ladle furnace to compensate temperature losses, and ladle preheating.

AB - Policies all over the world encourage the high energy efficiency of processes and the reduction of greenhouse gas (GHG) emissions, classified as direct and indirect. Iron and steelmaking is energy intensive industry, which also contributes 30% of the direct global CO2 emissions (2007), triggered through the industrial processes [1]. This article focuses on the verification of the CO2 emissions distribution for the secondary steelmaking.The potential for reduction of these emissions depends on the following key factors of ladle logistics and temperature losses under consideration of the steel contact time, additions during tapping, treatment at the ladle furnace to compensate temperature losses, and ladle preheating.

KW - Secondary Metallurgy

KW - CO2 Emission Reduction

KW - ladle logistics

KW - alloying concepts

KW - CO2-Reduction

KW - Secondary metallurgy

KW - emission

M3 - Article

VL - 2016

SP - 28

EP - 34

JO - RHI bulletin : the journal of refractory innovations

JF - RHI bulletin : the journal of refractory innovations

IS - 1

ER -