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Investigating the suitability of Subcoal® as an alternative blast furnace reductant. / FAWAZ OJOBOWALE

Swansea University Author: FAWAZ OJOBOWALE

  • E-Thesis – open access under embargo until: 9th April 2029

DOI (Published version): 10.23889/SUThesis.66937

Abstract

The blast furnace is the most widely used means to producing pig iron for steel production. In the blast furnace, iron oxide is reduced to metallic iron using carbonaceous materials usually from fossil sources. The steel industry aims to reduce coke consumption and minimise CO2 emissions by improvin...

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Published: Swansea, Wales, UK 2024
Institution: Swansea University
Degree level: Doctoral
Degree name: Ph.D
Supervisor: Holliman, P. and Greenslade, M.
URI: https://cronfa.swan.ac.uk/Record/cronfa66937
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spelling v2 66937 2024-07-04 Investigating the suitability of Subcoal® as an alternative blast furnace reductant. ea910fda5a9a790bf75f8ea454888b31 FAWAZ OJOBOWALE FAWAZ OJOBOWALE true false 2024-07-04 The blast furnace is the most widely used means to producing pig iron for steel production. In the blast furnace, iron oxide is reduced to metallic iron using carbonaceous materials usually from fossil sources. The steel industry aims to reduce coke consumption and minimise CO2 emissions by improving the energy efficiency of the process and by investigating the use of carbon-neutral materials. Climate change is being driven by increases in greenhouse gases which absorb heat radiation in the atmosphere which is changing global temperatures and weather patterns. The most abundant greenhouse gas is carbon dioxide which is produced by combustion of fossil fuels such as coal, oil and natural gas. Fossil fuels are widely used in energy intensive industries such as the steel industry. This thesis, which is co-sponsored by the EPSRC and Tata Steel – Port Talbot, reports studies of alternatives to fossil fuels which have the potential to replace them particularly in blast furnace ironmaking. The alternative carbon source studied has been Subcoal® which is a refuse-derived fuel (RDF) produced by N&P Ltd. Subcoal® consists of non-recyclable carbon-based waste (mainly paper and plastic) which would otherwise be landfilled. Instead, this material is processed by sorting and heating before being extruded into pellets which was the main material supplied for this thesis work. The thesis describes an initial characterisation of Subcoal® to understand the key components. Then the thermal chemistry of Subcoal® has been studied using TGA in different gaseous environments (N2, air and CO2) to understand the kinetics of how this material might behave if injected at the bottom of a blast furnace. The data has been compared with coals supplied by Tata Steel. Then blends of Subcoal® and coal have been produced to study the thermal chemistry of mixtures of fossil fuel coal and non-fossil fuel Subcoal® and to understand if these sub-components react synergistically or antagonistically. As part of this work, the devolatilisation of coal was compared using drop tube furnace versus a horizontal tube furnace. The drop tube furnace closely mimicks the conditions in the raceway of a blast furnace. Finally, the thesis reports studies of the torrefaction or hydrothermal carbonisation of Subcoal® as potential methods to upgrade this material in terms of its potential use in ironmaking. This was the first time thermal treatment was done on Subcoal® samples. Thermal treatment was found to increase the reactivity of Subcoal® E-Thesis Swansea, Wales, UK thermogravimetric analysis, non-fossil fuels, torrefaction, kinetic analysis 9 4 2024 2024-04-09 10.23889/SUThesis.66937 COLLEGE NANME COLLEGE CODE Swansea University Holliman, P. and Greenslade, M. Doctoral Ph.D EPSRC doctoral training grant EPSRC doctoral training grant 2024-08-05T13:48:16.2106509 2024-07-04T11:40:25.9669945 Faculty of Science and Engineering School of Engineering and Applied Sciences - Materials Science and Engineering FAWAZ OJOBOWALE 1 Under embargo Under embargo 2024-07-04T11:45:34.5072650 Output 43547371 application/pdf E-Thesis – open access true 2029-04-09T00:00:00.0000000 Copyright: The Author, Fawaz Ojobowale, 2023 true eng
title Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
spellingShingle Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
FAWAZ OJOBOWALE
title_short Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
title_full Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
title_fullStr Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
title_full_unstemmed Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
title_sort Investigating the suitability of Subcoal® as an alternative blast furnace reductant.
author_id_str_mv ea910fda5a9a790bf75f8ea454888b31
author_id_fullname_str_mv ea910fda5a9a790bf75f8ea454888b31_***_FAWAZ OJOBOWALE
author FAWAZ OJOBOWALE
author2 FAWAZ OJOBOWALE
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institution Swansea University
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hierarchy_top_title Faculty of Science and Engineering
hierarchy_parent_id facultyofscienceandengineering
hierarchy_parent_title Faculty of Science and Engineering
department_str School of Engineering and Applied Sciences - Materials Science and Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Materials Science and Engineering
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description The blast furnace is the most widely used means to producing pig iron for steel production. In the blast furnace, iron oxide is reduced to metallic iron using carbonaceous materials usually from fossil sources. The steel industry aims to reduce coke consumption and minimise CO2 emissions by improving the energy efficiency of the process and by investigating the use of carbon-neutral materials. Climate change is being driven by increases in greenhouse gases which absorb heat radiation in the atmosphere which is changing global temperatures and weather patterns. The most abundant greenhouse gas is carbon dioxide which is produced by combustion of fossil fuels such as coal, oil and natural gas. Fossil fuels are widely used in energy intensive industries such as the steel industry. This thesis, which is co-sponsored by the EPSRC and Tata Steel – Port Talbot, reports studies of alternatives to fossil fuels which have the potential to replace them particularly in blast furnace ironmaking. The alternative carbon source studied has been Subcoal® which is a refuse-derived fuel (RDF) produced by N&P Ltd. Subcoal® consists of non-recyclable carbon-based waste (mainly paper and plastic) which would otherwise be landfilled. Instead, this material is processed by sorting and heating before being extruded into pellets which was the main material supplied for this thesis work. The thesis describes an initial characterisation of Subcoal® to understand the key components. Then the thermal chemistry of Subcoal® has been studied using TGA in different gaseous environments (N2, air and CO2) to understand the kinetics of how this material might behave if injected at the bottom of a blast furnace. The data has been compared with coals supplied by Tata Steel. Then blends of Subcoal® and coal have been produced to study the thermal chemistry of mixtures of fossil fuel coal and non-fossil fuel Subcoal® and to understand if these sub-components react synergistically or antagonistically. As part of this work, the devolatilisation of coal was compared using drop tube furnace versus a horizontal tube furnace. The drop tube furnace closely mimicks the conditions in the raceway of a blast furnace. Finally, the thesis reports studies of the torrefaction or hydrothermal carbonisation of Subcoal® as potential methods to upgrade this material in terms of its potential use in ironmaking. This was the first time thermal treatment was done on Subcoal® samples. Thermal treatment was found to increase the reactivity of Subcoal®
published_date 2024-04-09T13:48:18Z
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