Time- and component-resolved energy system model of an electric steel mill

Research output: Contribution to journalArticleResearchpeer-review

Standard

Time- and component-resolved energy system model of an electric steel mill. / Dock, Johannes; Janz, Daniel; Weiss, Jakob et al.
In: Cleaner Engineering and Technology, Vol. 4.2021, No. October, 100223, 24.07.2021.

Research output: Contribution to journalArticleResearchpeer-review

Vancouver

Dock J, Janz D, Weiss J, Marschnig A, Kienberger T. Time- and component-resolved energy system model of an electric steel mill. Cleaner Engineering and Technology. 2021 Jul 24;4.2021(October):100223. doi: 10.1016/j.clet.2021.100223

Author

Bibtex - Download

@article{45eda8ec64be4cf5a953ca2e3ed264f2,
title = "Time- and component-resolved energy system model of an electric steel mill",
abstract = "Steel production is a highly energy- and emission-intensive process. Compared to the production via the integrated route, the melting of recycled steel scrap and directly reduced iron in an electric arc furnace operated on green power constitutes a way to reduce energy consumption and CO2-emissions. However, there is still potential to reduce energy consumption and CO2-emissions in electric arc furnace steel production by introducing new sub-processes, optimal operational design, and integration of renewable energy sources. For complex industrial processes, this potential can only be determined using models of the entire system. The batch operation, changing process parameters, and strongly fluctuating energy consumption require a holistic, temporally, and technologically resolved model. Within the scope of this paper, we describe an energy system model of an electric arc furnace steel mill. It allows assessing the optimal implementation of novel technologies and system integration of renewable energy sources using a reduced set of input parameters. The modular design facilitates the extension of the model, and the option of specifying several input parameters enables the model to be adopted for other electric steel mills.",
author = "Johannes Dock and Daniel Janz and Jakob Weiss and Aaron Marschnig and Thomas Kienberger",
year = "2021",
month = jul,
day = "24",
doi = "10.1016/j.clet.2021.100223",
language = "English",
volume = "4.2021",
journal = "Cleaner Engineering and Technology",
issn = "2666-7908",
publisher = "Elsevier",
number = "October",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Time- and component-resolved energy system model of an electric steel mill

AU - Dock, Johannes

AU - Janz, Daniel

AU - Weiss, Jakob

AU - Marschnig, Aaron

AU - Kienberger, Thomas

PY - 2021/7/24

Y1 - 2021/7/24

N2 - Steel production is a highly energy- and emission-intensive process. Compared to the production via the integrated route, the melting of recycled steel scrap and directly reduced iron in an electric arc furnace operated on green power constitutes a way to reduce energy consumption and CO2-emissions. However, there is still potential to reduce energy consumption and CO2-emissions in electric arc furnace steel production by introducing new sub-processes, optimal operational design, and integration of renewable energy sources. For complex industrial processes, this potential can only be determined using models of the entire system. The batch operation, changing process parameters, and strongly fluctuating energy consumption require a holistic, temporally, and technologically resolved model. Within the scope of this paper, we describe an energy system model of an electric arc furnace steel mill. It allows assessing the optimal implementation of novel technologies and system integration of renewable energy sources using a reduced set of input parameters. The modular design facilitates the extension of the model, and the option of specifying several input parameters enables the model to be adopted for other electric steel mills.

AB - Steel production is a highly energy- and emission-intensive process. Compared to the production via the integrated route, the melting of recycled steel scrap and directly reduced iron in an electric arc furnace operated on green power constitutes a way to reduce energy consumption and CO2-emissions. However, there is still potential to reduce energy consumption and CO2-emissions in electric arc furnace steel production by introducing new sub-processes, optimal operational design, and integration of renewable energy sources. For complex industrial processes, this potential can only be determined using models of the entire system. The batch operation, changing process parameters, and strongly fluctuating energy consumption require a holistic, temporally, and technologically resolved model. Within the scope of this paper, we describe an energy system model of an electric arc furnace steel mill. It allows assessing the optimal implementation of novel technologies and system integration of renewable energy sources using a reduced set of input parameters. The modular design facilitates the extension of the model, and the option of specifying several input parameters enables the model to be adopted for other electric steel mills.

U2 - 10.1016/j.clet.2021.100223

DO - 10.1016/j.clet.2021.100223

M3 - Article

VL - 4.2021

JO - Cleaner Engineering and Technology

JF - Cleaner Engineering and Technology

SN - 2666-7908

IS - October

M1 - 100223

ER -