Application of LCA and LCC in the early stages of wastewater treatment design: A multiple case study of brine effluents
Autor: | Frederik Tegstedt, Joan Berzosa Corberá, Jose Jorge Espí Gallart, Steve Harris, George Tsalidis |
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Jazyk: | angličtina |
Předmět: |
By-product recovery
Circular economy 020209 energy Strategy and Management 02 engineering and technology Wastewater treatment Reuse 7. Clean energy Industrial and Manufacturing Engineering 12. Responsible consumption Industrial wastewater treatment Life cycle costing 0202 electrical engineering electronic engineering information engineering Life-cycle assessment 0505 law General Environmental Science Prospective life cycle assessment Waste management Renewable Energy Sustainability and the Environment business.industry 05 social sciences Energy consumption 6. Clean water Renewable energy Wastewater 13. Climate action 050501 criminology Environmental science Sewage treatment business |
Zdroj: | Journal of Cleaner Production Journal of Cleaner Production, 307 |
ISSN: | 0959-6526 |
DOI: | 10.1016/j.jclepro.2021.127298 |
Popis: | Technological developments are opening new avenues to facilitate the circular economy through resource recovery from industrial wastewater. This paper presents the use of Life Cycle Assessment (LCA) and Life Cycle Costing (LCC) in the development of technology solutions for the treatment of brine wastewater and recovery of by-products. Four industrial case studies are assessed that apply different innovative technology configurations, to treat the brines and recover the water, salts and mineral compounds. The assessment focusses on identifying hotspots and potential design improvements for the four case studies. In addition, the development of a unified approach for prospective LCA and LCC is illustrated to promote robustness and consistency in the analysis of the four systems. The analysis reveals that the impact and cost of treatment is highly dependent on the wastewater composition. Critically, whether the recovery of compounds and deionised water can counteract the impact and cost of the treatment systems. The early analysis suggests that this is possible for two of the cases studies. Estimates of the GHG emissions for the initial system analysis, range from 10 to 17 kg CO2e/m3, whilst costs range from €10/m3 to €25/m3. However, both are expected to decrease at full scale and are sensitive to costs of energy, chemicals and revenue from recovered by-products. The LCA's highlight chemical and energy consumption as critical hotspots. Design considerations therefore focus on the reduction of chemicals, reuse or switching to lower impact chemicals, and maximising by-product recovery, and using renewable energy. |
Databáze: | OpenAIRE |
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