| Title | Environmental impact assessment of steel reinforcing bar manufacturing process from scrap materials using life cycle assessment method: a case study on the Ethiopian metal industries |
|---|---|
| ID_Doc | 14775 |
| Authors | Fente, TE; Tsegaw, AA |
| Title | Environmental impact assessment of steel reinforcing bar manufacturing process from scrap materials using life cycle assessment method: a case study on the Ethiopian metal industries |
| Year | 2024 |
| Published | Discover Applied Sciences, 6, 2 |
| Abstract | A clear understanding of the major environmental impacts of steelmaking from scraps, as well as potential solutions involving a circular economy paradigm, is essential. This study is conducted to pave the way for using life cycle assessment (LCA) to have sustainable development and effective resource management by evaluating the environmental impacts of the steel rebar manufacturing process using secondary resources. It is a cradle-to-gate LCA that includes scrap collection and sorting, transportation, melting, continuous casting, billet reheating, and reinforcing bar rolling. Inventory data were acquired as primary data from the factory and secondary data from ecoinvent v3.8, 2021 version integrated with SimaPro 9.4.0.2 faculty version. All of the analyses in this LCA were conducted using the Recipe 2016 Midpoint (H)V1.00 and Endpoint (I)V1.00 impact assessment techniques taking one-ton reinforcing bar production as reference flow. This LCA study shows that using renewable energy and bulk transport systems has a significant advantage in reducing the environmental impact created during steel production processes. Because of this, the global warming potential created during the rebar manufacturing process is 467 kgCO2 eq as taken from the environmental impact calculation report. By charging hot billet from the continuous casting machine (CCM) to the rolling mill and using an efficient transportation system, the environmental impact of GWP can be reduced by 50%. Literature related to life cycle assessment in steel production was reviewed. The inventory analysis of inputs, outputs, and flows were quantified and the environmental impact of the product system was evaluated using Recipe Midpoint and Endpoint methods. Comparative analysis between the two production processes was done to minimize the environmental impact created during steel production. |
| https://link.springer.com/content/pdf/10.1007/s42452-024-05709-4.pdf |
Similar Articles
| ID | Score | Article |
|---|---|---|
1892
|
Broadbent, C Steel's recyclability: demonstrating the benefits of recycling steel to achieve a circular economy(2016)International Journal Of Life Cycle Assessment, 21, 11 | |
| 17940
|
Abdullah, ZT Quantitative sustainability assessment of remanufacturing waste reinforcing steel(2023)Environmental Quality Management, 32, 4 | |
| 23129
|
Casazza, M; Barone, F Relevance of Environmental Factors in the Steel Life Cycle for a Transition toward Circular Sustainable Production and Consumption Systems: A Joint Bibliometric and Bibliographic Analysis(2023)Metals, 13, 3 | |
| 13149
|
Renzulli, PA; Notarnicola, B; Tassielli, G; Arcese, G; Di Capua, R Life Cycle Assessment of Steel Produced in an Italian Integrated Steel Mill(2016)Sustainability, 8, 8 | |
| 2028
|
Walker, S; Coleman, N; Hodgson, P; Collins, N; Brimacombe, L Evaluating the Environmental Dimension of Material Efficiency Strategies Relating to the Circular Economy(2018)Sustainability, 10, 3 | |
| 28147
|
Roy, K; Dani, AA; Say, V; Fang, ZY; Lim, JBP The Circular Economy of Steel Roofing and Cladding and Its Environmental Impacts-A Case Study for New Zealand(2022)Sustainability, 14.0, 24 | |
| 26184
|
Giama, E; Papadopoulos, AM Benchmarking carbon footprint and circularity in production processes: The case of stonewool and extruded polysterene(2020) | |
| 16562
|
Hagedorn, W; Greiff, K; Pauliuk, S An environmental assessment framework for circular steel products(2024) | |
| 3525
|
Simoes, F; Rios-Davila, FJ; Paiva, H; Maljaee, H; Morais, M; Ferreira, VM Sustainability Evaluation Using a Life Cycle and Circular Economy Approach in Precast Concrete with Waste Incorporation(2021)Applied Sciences-Basel, 11, 24 | |
| 28658
|
Joachimiak-Lechman, K; Garstecki, D; Konopczynski, M; Lewandowska, A Implementation of Life Cycle Based Tools in the Circular Economy Context-Case Study of Plastic Waste(2020)Sustainability, 12.0, 23 |