Abstract
The present research work carried out a design proposal for the leachate treatment plant of the Santa Rosa de Shapajilla transitory cell; for this purpose, first a location was proposed taking into account eight (8) criteria, which are the following: Identification of areas with slopes less than 15%, classification of rivers greater than 500 m, classification of rivers greater than 500 m, identification of risk areas due to geological faults, identification of population centers greater than or equal to 500 m, presentation of areas suitable for the construction of a WWTP, location of tentative areas based on the proximity of the transitional cell and selection of the best area for construction. Once the tentative area was taken into account, a series of operations necessary for leachate treatment were proposed. A 10.8 m long and 1.3 m wide sand trap was proposed as pretreatment; a 432.0 m^3 decanter was proposed as primary treatment, followed by an anaerobic biological reactor as secondary treatment, with a volume of 108.216 m^3; for tertiary treatment, a homogenization tank and a settling tank with 520.0 and 121.97 m^3 respectively were chosen. Finally, a disinfection system of 120.0 m^3 and a storage tank for treated water with a volume of 250.0 m^3 were chosen for tertiary treatment.
References
Caicedo Messa, F. (2006). Diseño, construcción y arranque de un reactor U.S.B. piloto para el tratamiento de lixiviados.
https://repositorio.unal.edu.co/handle/unal/3413
Cárdenas-Ferrer, Teresa Margarita, Santos-Herrero, Ronaldo Francisco, Contreras-Moya, Ana Margarita, Rosa-Domínguez, Elena, & Correa -Cortés, Yania. (2020). Diseño de una planta para el tratamiento del lixiviado en Vertedero de Sagua La Grande. Tecnología Química, 40(2), 413-427.. Recuperado de http://scielo.sld.cu/scielo.php?script=sci_arttext&pid=S2224-61852020000200413&lng=es&tlng=es.
Chisag, T., & Marisol, N. (2014). Diseño de una planta de tratamiento de Lixiviados para el botadero de Curgua del cantón Guaranda provincia de Bolívar. Escuela Superior Politécnica de Chimborazo.
Cifuentes, D., & Marcela, A. (2013). Estudio del sistema de tratamiento de lixiviados en el relleno sanitario de Lago Agrio. http://www.dspace.uce.edu.ec/handle/25000/1501
Guevara, A., Guanoluisa, L., & de la Torre, E. (2014). Diseño de Sistemas de Tratamiento de Lixiviados del Relleno Sanitario. Revista Politécnica, 34(1). Recuperado a partir de https://revistapolitecnica.epn.edu.ec/ojs2/index.php/revista_politecnica2/article/view/154
Hidalgo, A. M., Murcia, M. D., Gómez, M., & López, A. J. (2016). ALTERNATIVAS EN EL TRATAMIENTO DE LIXIVIADOS DE VERTEDERO. Vsf.es. Recuperado de: http://www.conama11.vsf.es/conama10/download/files/conama2016/CT%202016/1998971810.pdf
López, E. (2016). “Diseño de la Planta de Tratamiento de Lixiviados para la nueva celda de Desechos Sólidos del Relleno Sanitario del Cantón Pastaza [Tesis pregrado, Universidad Estatal Amazónica .Repositorio digital Universidad Estatal amazónica https://repositorio.uea.edu.ec/handle/123456789/402.
Lozano-Rivas, W. (2012). Diseño de Plantas de Potabilización de Agua. Material de clase. Bogotá D.C., Colombia: Disponible en: http://wlozano.blogspot.com.
MINAM. (SD). Problemática de los residuos sólidos en el Perú. https://www.minam.gob.pe/proyecolegios/Ecolegios/contenidos/biblioteca/biblioteca/m1_rrss_A1L1_Problematica_rrss_Peru.pdf.
Mishra, S., Tiwary, D., Ohri, A. (2018). Leachate characterisation and evaluation of leachate pollution potential of urban municipal landfill sites. International Journal of Environment and Waste Management. https://www.inderscience.com/info/inarticle.php?artid=93431.
Morillo León, F., y Fajardo Fajardo, E. (2005). Estudio de los reactores UASB para el tratamiento de lixiviados del relleno sanitario La Esmeralda.
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Copyright (c) 2022 Elvis Mariano Evangelista Medina , Ivet Victoria Falcón Ramírez , Dan Jarod Figueroa Valeriano (Author)