Impact of Iron Ore Pre-Reduction Degree on the Hydrogen Plasma Smelting Reduction Process

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Standard

Impact of Iron Ore Pre-Reduction Degree on the Hydrogen Plasma Smelting Reduction Process. / Ernst, Daniel; Manzoor, Ubaid; Souza Filho, Isnaldi Rodrigues et al.
in: Metals, Jahrgang 13.2023, Nr. 3, 558, 10.03.2023.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

APA

Vancouver

Ernst D, Manzoor U, Souza Filho IR, Zarl MA, Schenk J. Impact of Iron Ore Pre-Reduction Degree on the Hydrogen Plasma Smelting Reduction Process. Metals. 2023 Mär 10;13.2023(3):558. doi: 10.3390/met13030558

Author

Ernst, Daniel ; Manzoor, Ubaid ; Souza Filho, Isnaldi Rodrigues et al. / Impact of Iron Ore Pre-Reduction Degree on the Hydrogen Plasma Smelting Reduction Process. in: Metals. 2023 ; Jahrgang 13.2023, Nr. 3.

Bibtex - Download

@article{1b228fbc3f78498d841e55b5f55107af,
title = "Impact of Iron Ore Pre-Reduction Degree on the Hydrogen Plasma Smelting Reduction Process",
abstract = "To counteract the rising greenhouse gas emissions, mainly CO2, the European steel industry needs to restructure the current process route for steel production. Globally, the blast furnace and the subsequent basic oxygen furnace are used in 73% of crude steel production, with a CO2 footprint of roughly 1.8 t CO2 per ton of produced steel. Hydrogen Plasma Smelting Reduction (HPSR) utilizes excited hydrogen states with the highest reduction potentials to combine the simultaneous reduction and smelting of iron ore fines. Due to the wide range of iron ore grades available worldwide, a series of hydrogen plasma experiments were conducted to determine how pre-reduced iron ore and iron-containing residues affect reduction behavior, hydrogen consumption, overall process time, and metal phase microstructure. It was discovered that, during the pre-melting phase under pure argon, wet ore increased electrode consumption and hematite achieved higher reduction levels, due to thermal decomposition. The reduction of magnetite ore yielded the highest reduction rate and subsequent hydrogen conversion rates. Both hematite and magnetite exhibited high utilization rates at first, but hematite underwent a kinetic change at a reduction degree of 80–85%, causing the reduction rate to decrease. In comparison to fluidized bed technology, it is possible to use magnetite directly, and the final phase of the reduction can move along more quickly due to higher temperatures, which reduces the overall process time and raises the average hydrogen utilization. A combination of both technologies can be considered advantageous for exhaust gas recycling.",
keywords = "hydrogen plasma smelting reduction, hydrogen reduction, hydrogen utilization, iron ore, microstructure, plasma, reduction degree",
author = "Daniel Ernst and Ubaid Manzoor and {Souza Filho}, {Isnaldi Rodrigues} and Zarl, {Michael Andreas} and Johannes Schenk",
note = "Funding Information: The authors gratefully acknowledge the SuSteel project{\textquoteright}s funding by The Austrian Research Promotion Agency (FFG) and the funding support of K1-MET GmbH metallurgical competence center. The K1-MET competence center{\textquoteright}s research program is supported by COMET (Competence Center for Excellent Technologies), the Austrian program for competence centers. The Federal Ministry funds COMET for Climate Action, Environment, Energy, Mobility, Innovation and Technology, the Federal Ministry for Digital and Economic Affairs, the provinces of Upper Austria, Tyrol, and Styria, and the Styrian Business Promotion Agency (SFG). Funding Information: This research was funded by the COMET program Fundamentals of hydrogen reduction, K1-MET project number 12204396; Austrian Research Promotion Agency (853393) In addition, this research work is partially financed by the industrial partners voestalpine Stahl GmbH and voestalpine Stahl Donawitz GmbH and the scientific partner Montanuniversit{\"a}t Leoben. Publisher Copyright: {\textcopyright} 2023 by the authors.",
year = "2023",
month = mar,
day = "10",
doi = "10.3390/met13030558",
language = "English",
volume = "13.2023",
journal = "Metals",
issn = "2075-4701",
publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",
number = "3",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Impact of Iron Ore Pre-Reduction Degree on the Hydrogen Plasma Smelting Reduction Process

AU - Ernst, Daniel

AU - Manzoor, Ubaid

AU - Souza Filho, Isnaldi Rodrigues

AU - Zarl, Michael Andreas

AU - Schenk, Johannes

N1 - Funding Information: The authors gratefully acknowledge the SuSteel project’s funding by The Austrian Research Promotion Agency (FFG) and the funding support of K1-MET GmbH metallurgical competence center. The K1-MET competence center’s research program is supported by COMET (Competence Center for Excellent Technologies), the Austrian program for competence centers. The Federal Ministry funds COMET for Climate Action, Environment, Energy, Mobility, Innovation and Technology, the Federal Ministry for Digital and Economic Affairs, the provinces of Upper Austria, Tyrol, and Styria, and the Styrian Business Promotion Agency (SFG). Funding Information: This research was funded by the COMET program Fundamentals of hydrogen reduction, K1-MET project number 12204396; Austrian Research Promotion Agency (853393) In addition, this research work is partially financed by the industrial partners voestalpine Stahl GmbH and voestalpine Stahl Donawitz GmbH and the scientific partner Montanuniversität Leoben. Publisher Copyright: © 2023 by the authors.

PY - 2023/3/10

Y1 - 2023/3/10

N2 - To counteract the rising greenhouse gas emissions, mainly CO2, the European steel industry needs to restructure the current process route for steel production. Globally, the blast furnace and the subsequent basic oxygen furnace are used in 73% of crude steel production, with a CO2 footprint of roughly 1.8 t CO2 per ton of produced steel. Hydrogen Plasma Smelting Reduction (HPSR) utilizes excited hydrogen states with the highest reduction potentials to combine the simultaneous reduction and smelting of iron ore fines. Due to the wide range of iron ore grades available worldwide, a series of hydrogen plasma experiments were conducted to determine how pre-reduced iron ore and iron-containing residues affect reduction behavior, hydrogen consumption, overall process time, and metal phase microstructure. It was discovered that, during the pre-melting phase under pure argon, wet ore increased electrode consumption and hematite achieved higher reduction levels, due to thermal decomposition. The reduction of magnetite ore yielded the highest reduction rate and subsequent hydrogen conversion rates. Both hematite and magnetite exhibited high utilization rates at first, but hematite underwent a kinetic change at a reduction degree of 80–85%, causing the reduction rate to decrease. In comparison to fluidized bed technology, it is possible to use magnetite directly, and the final phase of the reduction can move along more quickly due to higher temperatures, which reduces the overall process time and raises the average hydrogen utilization. A combination of both technologies can be considered advantageous for exhaust gas recycling.

AB - To counteract the rising greenhouse gas emissions, mainly CO2, the European steel industry needs to restructure the current process route for steel production. Globally, the blast furnace and the subsequent basic oxygen furnace are used in 73% of crude steel production, with a CO2 footprint of roughly 1.8 t CO2 per ton of produced steel. Hydrogen Plasma Smelting Reduction (HPSR) utilizes excited hydrogen states with the highest reduction potentials to combine the simultaneous reduction and smelting of iron ore fines. Due to the wide range of iron ore grades available worldwide, a series of hydrogen plasma experiments were conducted to determine how pre-reduced iron ore and iron-containing residues affect reduction behavior, hydrogen consumption, overall process time, and metal phase microstructure. It was discovered that, during the pre-melting phase under pure argon, wet ore increased electrode consumption and hematite achieved higher reduction levels, due to thermal decomposition. The reduction of magnetite ore yielded the highest reduction rate and subsequent hydrogen conversion rates. Both hematite and magnetite exhibited high utilization rates at first, but hematite underwent a kinetic change at a reduction degree of 80–85%, causing the reduction rate to decrease. In comparison to fluidized bed technology, it is possible to use magnetite directly, and the final phase of the reduction can move along more quickly due to higher temperatures, which reduces the overall process time and raises the average hydrogen utilization. A combination of both technologies can be considered advantageous for exhaust gas recycling.

KW - hydrogen plasma smelting reduction

KW - hydrogen reduction

KW - hydrogen utilization

KW - iron ore

KW - microstructure

KW - plasma

KW - reduction degree

UR - http://www.scopus.com/inward/record.url?scp=85152655465&partnerID=8YFLogxK

U2 - 10.3390/met13030558

DO - 10.3390/met13030558

M3 - Article

AN - SCOPUS:85152655465

VL - 13.2023

JO - Metals

JF - Metals

SN - 2075-4701

IS - 3

M1 - 558

ER -