Low Energy Technology for Leachate Valorisation
Landfills present long-term threats to soil, air, groundwater and surface water due to the formation of greenhouse gases (methane gas and carbon dioxide) and leachate from decomposing garbage. The composition of leachate differs from site to site and also within the landfill. The leachates alter with time (from weeks to years) since the landfilled waste is biologically highly active and their composition varies. Mainly, the composition of the leachate depends on factors such as characteristics of the waste, the moisture content, climatic conditions, degree of compaction and the age of the landfill. Therefore, the leachate composition cannot be generalized and the traditional treatment models should be adapted in each case. Although leachate composition is highly variable, what different leachates have in common is hazardous constituents and their potential eco-toxicological effects on human health and on terrestrial ecosystems. Since leachate has distinct compositions, each landfill or dumping site would represent a different type of risk on its environment. Nevertheless, leachates consist always of high organic concentration, conductivity, heavy metals and ammonia nitrogen. Leachate could affect the current and future quality of water bodies due to uncontrolled infiltrations. Therefore, control and treatment of leachate is one of the biggest issues in urban solid waste treatment plants and landfills design and management. This work presents a treatment model that will be carried out "in-situ" using a cost-effective novel technology that combines solar evaporation/condensation plus forward osmosis. The plant is powered by renewable energies (solar energy, biomass and residual heat), which will minimize the carbon footprint of the process. The final effluent quality is very high, allowing reuse (preferred) or discharge into watercourses. In the particular case of this work, the final effluents will be reused for cleaning and gardening purposes. A minority semi-solid residual stream is also generated in the process. Due to its special composition (rich in metals and inorganic elements), this stream will be valorized in ceramic industries to improve the final products characteristics.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1131321Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 775
 Eur-lex: Communication from the commission to the European parliament, the council, the European economic and social committee and the committee of the regions. Roadmap to a Resource Efficient Europe (Online document). 2011 (Belgium) (Consultation: 01-09-2014). Available on web: http://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX:52011DC0571, Accessed on 20/03/2017.
 Johannessen, L. M. (1999). Guidance note on leachate management for municipal solid waste landfills. World Bank.
 Petrović, M., Gonzalez, S., & Barceló, D. (2003). Analysis and removal of emerging contaminants in wastewater and drinking water. TrAC Trends in Analytical Chemistry, 22(10), 685-696.
 Stegmann, R., Heyer, K. U., & Cossu, R. (2005, October). Leachate treatment. In Proceedings Sardinia (Vol. 10).
 Wiszniowski, J., Robert, D., Surmacz-Gorska, J., Miksch, K., & Weber, J. V. (2006). Landfill leachate treatment methods: A review. Environmental Chemistry Letters, 4(1), 51-61.
 Giraldo, E. (2001). Tratamiento de lixiviados de rellenos sanitarios: avances recientes. Revista de ingeniería, (14), 44-55.