Buch, Englisch, 464 Seiten, Format (B × H): 170 mm x 244 mm
Pathways to Net-Zero Carbon Emissions
Buch, Englisch, 464 Seiten, Format (B × H): 170 mm x 244 mm
ISBN: 978-3-527-35315-6
Verlag: Wiley-VCH GmbH
State-of-the-art, multidisciplinary guide delivering pathways to net-zero carbon emissions in steel production and circular resource flow through the Bio Steel Cycle
Circular Steel Production introduces the concept of the Bio Steel Cycle, exploring several innovative research directions in the field of carbon avoidance, utilization, and sequestration of carbon emissions in steel manufacturing. Carbon emission avoidance and reduction processes and projects are investigated in great detail within the workings of the Bio Steel Cycle model, covering technologies such as Geomimetic, GrInHy2.0, H2Future, HYBRIT, ULCOWIN, DAC, CEPS, COREX, MIDREX, TGRBF, HISARNA, Everest, ReclaMet, Athos, HDR/HDRI, and many others.
The circular flow of various resources as one of the key elements of the Bio Steel Cycle are explained in detail, with approximately 50 different methods summarized, along with skill sets required for effective implementation of these methods. Most of the green steel projects within the EU and beyond which are currently underway are also commented upon. The opportunities for green steel (by country) are discussed in some detail, as well as the nationally determined contributions, the effects of implemented policy and decarbonisation efforts.
Written by a team of experts with many years of industry experience, Circular Steel Production provides in-depth coverage of topics including: - Raw materials including iron ore, coal, and lime, and blast furnace, oxygen furnace, and electric arc furnace operation and the level of CO2 emissions along the production pathway for each resource required for the steelmaking process
- Anaerobic digestion, sewage treatment, and geothermal units, CO2 avoidance, capture, and utilisation mechanisms, and renewable energy technology utilization
- Wind, solar, and hydro power, biogas, biomass, and hydrogen, and the opportunities of greater energy independence via sustainable steel production
- The future of green steel in various countries including the UK, the USA, Brazil, and India
- Ideal timeline of possible adoption of the Bio Steel Cycle model and strategy in the realms of politics, investments, and infrastructure
Circular Steel Production is an essential forward-thinking reference on the subject for professionals in the steel and manufacturing industries, academia, materials scientists, environmental chemists, engineers and engineering students, and metallurgists.
Autoren/Hrsg.
Fachgebiete
- Naturwissenschaften Chemie Chemie Allgemein
- Technische Wissenschaften Technik Allgemein Nachhaltigkeit, Grüne Technologien
- Technische Wissenschaften Verfahrenstechnik | Chemieingenieurwesen | Biotechnologie Chemische Verfahrenstechnik
- Technische Wissenschaften Energietechnik | Elektrotechnik Energietechnik & Elektrotechnik
- Technische Wissenschaften Maschinenbau | Werkstoffkunde Technische Mechanik | Werkstoffkunde Materialwissenschaft: Metallische Werkstoffe
- Technische Wissenschaften Verfahrenstechnik | Chemieingenieurwesen | Biotechnologie Metallurgie
Weitere Infos & Material
1: HISTORY OF STEELMAKING
1.1 How it all began
1.2 First attempts at steelmaking
1.3 Steelmaking process development
2: STEELMAKING PROCESSES
2.1 Introduction
2.2 Raw Materials
3: INTRODUCTION TO THE BIO STEEL CYCLE
3.1 Introduction
3.2 Motivation
3.3 BF/BOF route carbon capture
3.4 BF/BOF off-heat utilisation
3.5 Renewable energy technologies
3.6 DAC Woodlands
3.7 Biogas, biomass and hydrogen
3.8 CEPS
3.9 Industrial filters: Carbon capture and sequestration
3.10 Anaerobic digestion, sewage treatment and geothermal units
3.11 CAT, CCS and CCUS
4: THE KEY COMPONENTS OF THE BIO STEEL CYCLE (BiSC)
4.1 Introducing the BiSC key components for net-zero carbon steel manufacturing
4.2 BF/BOF route carbon capture
4.3 BF/BOF off-heat utilisation in iron and steelmaking
4.4 DAC Woodlands
4.5 CEPS
4.6 Geomimetic® Process
4.7 Anaerobic digestion
4.8 Sewage treatment
4.9 Biogas, biomass and hydrogen
4.10 Biogas, biomass and hydrogen
5: MULTI-CRITERIA DECISION ANALYSIS (MCDA) FOR BiSC (BIO STEEL CYCLE)
5.1 Introduction
5.2 BF/BOF route carbon capture
5.3 Renewable energy technologies
5.4 DAC Woodlands
5.5 CEPS and the Geomimetic® Process
5.6 Anaerobic digestion, sewage treatment
5.7 Biomass, biogas and hydrogen
5.8 CCUS
5.9 Validating process flowcharts and simulations
5.10 Findings
6: GREATER ENERGY INDEPENDENCE WITH SUSTAINABLE STEEL PRODUCTION
6.1 Introduction
6.2 Materials and methods
6.3 Heat loss recovery - energy and CO2 saving protocols
6.4 Retrofitting renewable energy technologies on site
6.5 Conclusions
7: TECHNOLOGICAL CHALLENGES TO AND OPPORTUNITIES OF THE BiSC CONCEPT IMPLEMENTATION
7.1 Introduction
7.2 Challenges
7.3 Opportunities
7.4 Conclusions
8: MACRO AND MICRO-ECONOMIC CHALLENGES TO IMPLEMENTATION OF THE BiSC CONCEPT
8.1 Introduction
8.2 Part I Policy and BiSC Implementation
8.3 Part II Markets analysis
8.4 PESTEL and SWOT Analysis green steel
8.5 CO2 emissions for the entire steel production process
8.6 BiSC - steel production decarbonisation model and strategy
8.7 Higher degree of energy independence
9: SKILLS SETS REQUIRED WITHIN THE DIFFERENT COMPONENTS AND SECTORS
9.1 Introduction
9.2 Solar
9.3 Wind turbines
9.4 Hydro
9.5 Geothermal
9.6 Green Hydrogen
9.7 Biomass
9.8 Biogas
9.9 Conclusion
10: THE FUTURE OF GREEN STEEL
10.1 Introduction
10.2 United Kingdom
10.3 United States of America
10.4 Brazil
10.5 Russias Federation
10.6 India
10.7 China
10.8 Australia
10.9 Canada
10.10 Norway
10.11 EU - Germany
10.12 Discussion and conclusions
11 AN IDEALISED TIMELINE OF POSSIBILITIES
11.1 Introduction
11.2 Political decision making and legislative foundations
11.3 All-encompassing industrial response
11.4 Investment in people
11.5 Infrastructural improvement
12 CONCLUDING REMARKS AND SUGGESTIONS
12.1 Discussion of Findings
