Product details:
| ISBN13: | 9780443337321 |
| ISBN10: | 0443337322 |
| Binding: | Hardback |
| No. of pages: | 600 pages |
| Size: | 276x215 mm |
| Language: | English |
| 700 |
Category:
Treatise on Process Metallurgy
Volume 5: Energy, Environment, and Future Aspects of Process Metallurgy
Publisher: Elsevier
Date of Publication: 1 June 2025
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Long description:
Treatise on Process Metallurgy: Volume 5: Energy, Environment, and Future Aspects of Process Metallurgy, Second Edition is divided into two parts, with the first covering sustainable development as it pertains to process metallurgy, addressing issues arising from sustained economic growth, long-term mineral and metal supply, and energy requirements in metallurgical industries. It also examines energy resources, including fossil and renewable sources, and discusses the resource efficiency of the circular economy through simulation-based analyses. The second part delves into the future of metals production globally, with a focus on raw material and energy availability. It presents current CO2 emissions and future projections, with emphasis on reducing CO2 generation in steelmaking technologies. Additional topics discussed include flash smelting, FINEX process outlook, the rotary hearth furnace, and an extensive coverage of hydrogen steelmaking.
Table of Contents:
1. Environmental Aspects
1.1 Sustainability and the role of process metallurgy
1.2 Energy Resources, Role of energy and Use in Metallurgical Industries, fossil and renewable energy sources
1.3.1 Life Cycle Assessment and Related Methodologies
1.3.2 Material Flow Analysis
1.3.3 Simulation-based analysis of the resource efficiency of the circular economy - the enabling role of metallurgical infrastructure
1.4.1 Ironmaking and Steelmaking Slags
1.4.2 Ironmaking and Steelmaking Dusts
1.4.3 Steel scraps
1.5 Total recycling of dross from aluminium remelting
2. Future of Process Metallurgy
2.1 Global outlook-raw materials
2.2.1 Challenges towards a Low-Carbon Sintering Process of Iron Ores
2.2.2 Iron Blast Furnace Process
2.3.1. COURSE50”-CO2 Ultimate Reduction in Steelmaking process by innovative technology for cool Earth 50: CO2 emission reduction technology in Japan
2.3.2 Flash Ironmaking Technology: A new ironmaking technology with greatly reduced CO2 emissions and energy consumption
2.3.3 FINEX? Process - Process of Promise
2.3.4 Rotary Hearth Furnace Process
2.3.5. Hydrogen steelmaking
1.1 Sustainability and the role of process metallurgy
1.2 Energy Resources, Role of energy and Use in Metallurgical Industries, fossil and renewable energy sources
1.3.1 Life Cycle Assessment and Related Methodologies
1.3.2 Material Flow Analysis
1.3.3 Simulation-based analysis of the resource efficiency of the circular economy - the enabling role of metallurgical infrastructure
1.4.1 Ironmaking and Steelmaking Slags
1.4.2 Ironmaking and Steelmaking Dusts
1.4.3 Steel scraps
1.5 Total recycling of dross from aluminium remelting
2. Future of Process Metallurgy
2.1 Global outlook-raw materials
2.2.1 Challenges towards a Low-Carbon Sintering Process of Iron Ores
2.2.2 Iron Blast Furnace Process
2.3.1. COURSE50”-CO2 Ultimate Reduction in Steelmaking process by innovative technology for cool Earth 50: CO2 emission reduction technology in Japan
2.3.2 Flash Ironmaking Technology: A new ironmaking technology with greatly reduced CO2 emissions and energy consumption
2.3.3 FINEX? Process - Process of Promise
2.3.4 Rotary Hearth Furnace Process
2.3.5. Hydrogen steelmaking
