Alternativas para la revalorización de los efluentes de la de la Empresa Porcina Cienfuegos
Resumen
En el trabajo se realizan mediciones del consumo de agua y de los efluentes líquidos estimándose la emisión de purín y el volumen que potencialmente puede aprovecharse. Se demuestra el sobreconsumo de agua en la limpieza de los corrales y se proponen medidas para reducirlo. Se realiza una evaluación preliminar de la revalorización de los residuos mediante la producción de biogás, abono orgánico y suplemento para la alimentación animal.Descargas
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Atiyeh, R. M., Arancon, N., Edwards, C. A., & Metzger, J. D. (2000). Influence of earthworm-processed pig manure on the growth and yield of greenhouse tomatoes. Bioresource Technology, 75(3), 175-180.
C. Saavedra Sueldo, S. Urrutia, D. Paravié, C. Rohvein, and G. Corres, “Una propuesta metodológica para la determinación de capacidades estratégicas en pymes industriales,” INGE CUC, vol. 10, no. 2, pp. 43–50, 2014.
Makara, A., & Kowalski, Z. (2015). Pig manure treatment and purification by filtration. Journal of environmental management, 161, 317-324.
Atiyeh, R. M., Edwards, C. A., Subler, S., & Metzger, J. D. (2001). Pig manure vermicompost as a component of a horticultural bedding plant medium: effects on physicochemical properties and plant growth. Bioresource technology, 78(1), 11-20.
J. C. Cabarcas Reyes, M. J. Wilches-Arango, A. F. Chaves, and S. M. Sanmiguel, “Análisis y mejoramiento de la cadena de valor de la línea de producción de láminas de una empresa del sector metalmecánico mediante la aplicación de herramientas de manufactura Lean,” INGE CUC, vol. 7, no. 1, pp. 27–42, 2011.
Eras, J. J. C., Varela, D. C., Pérez, G. D. H., Gutiérrez, A. S., Lorenzo, D. G., Vandecasteele, C., & Hens, L. (2014). Comparative study of the urban quality of life in Cuban first-level cities from an objective dimension. Environment, development and sustainability, 16(1), 195-215.
Huang, G. F., Wong, J. W. C., Wu, Q. T., & Nagar, B. B. (2004). Effect of C/N on composting of pig manure with sawdust. Waste management, 24(8), 805-813.
M. E. Spina, C. Rohvein, S. Urrutia, G. Roark, D. Paravié, and G. Corres, “Aplicación del modelo SCOR en pymes metalmecánicas de Olavarría,” INGE CUC, vol. 12, no. 2, pp. 50–57, 2016.
Hsu, J. H., & Lo, S. L. (1999). Chemical and spectroscopic analysis of organic matter transformations during composting of pig manure. Environmental Pollution, 104(2), 189-196.
Tiquia, S. M., Tam, N. F. Y., & Hodgkiss, I. J. (1996). Effects of composting on phytotoxicity of spent pig-manure sawdust litter. Environmental Pollution, 93(3), 249-256.
Astals, S., Nolla-Ardèvol, V., & Mata-Alvarez, J. (2012). Anaerobic co-digestion of pig manure and crude glycerol at mesophilic conditions: Biogas and digestate. Bioresource Technology, 110, 63-70.
Gutiérrez, A. S., Eras, J. J. C., Billen, P., & Vandecasteele, C. (2016). Environmental assessment of pig production in Cienfuegos, Cuba: alternatives for manure management. Journal of Cleaner Production, 112, 2518-2528.
C. E. Gómez Montoya, L. E. Sepúlveda Rodríguez, and C. A. Candela Uribe, “Servidor proxy caché: comprensión y asimilación tecnológica,” INGE CUC, vol. 8, no. 1, pp. 149–162, 2012.
Sengeløv, G., Agersø, Y., Halling-Sørensen, B., Baloda, S. B., Andersen, J. S., & Jensen, L. B. (2003). Bacterial antibiotic resistance levels in Danish farmland as a result of treatment with pig manure slurry. Environment international, 28(7), 587-595.
Angelidaki, I., & Ellegaard, L. (2003). Codigestion of manure and organic wastes in centralized biogas plants. Applied biochemistry and biotechnology, 109(1-3), 95.
Eras, J. J. C., Santos, V. S., Gutiérrez, A. S., Plasencia, M. Á. G., Haeseldonckx, D., & Vandecasteele, C. (2016). Tools to improve forecasting and control of the electricity consumption in hotels. Journal of Cleaner Production, 137, 803-812.
Amon, T., Amon, B., Kryvoruchko, V., Bodiroza, V., Pötsch, E., & Zollitsch, W. (2006, July). Optimising methane yield from anaerobic digestion of manure: effects of dairy systems and of glycerine supplementation. In International Congress Series (Vol. 1293, pp. 217-220). Elsevier.
Ferrer, I., Gamiz, M., Almeida, M., & Ruiz, A. (2009). Pilot project of biogas production from pig manure and urine mixture at ambient temperature in Ventanilla (Lima, Peru). Waste Management, 29(1), 168-173.
Xie, S., Lawlor, P. G., Frost, J. P., Hu, Z., & Zhan, X. (2011). Effect of pig manure to grass silage ratio on methane production in batch anaerobic co-digestion of concentrated pig manure and grass silage. Bioresource Technology, 102(10), 5728-5733.
Suárez, O. J. (2016). Aproximación al origen de la noción de objeto de aprendizaje: revisión histórico - bibliográfica. INGE CUC, 12(2), 26–40.
Páramo Bermúdez, G., & Benítez Lozano, A. (2013). Deformación incremental de lámina sin matriz (DIELESS) como alternativa viable a procesos de conformación de lámina convencionales. INGE CUC, 9(1), 115–128.
Tiquia, S. M., Tam, N. F. Y., & Hodgkiss, I. J. (1996). Microbial activities during composting of spent pig-manure sawdust litter at different moisture contents. Bioresource Technology, 55(3), 201-206.
Murto, M., Björnsson, L., & Mattiasson, B. (2004). Impact of food industrial waste on anaerobic co-digestion of sewage sludge and pig manure. Journal of environmental management, 70(2), 101-107.
Chae, K. J., Jang, A. M., Yim, S. K., & Kim, I. S. (2008). The effects of digestion temperature and temperature shock on the biogas yields from the mesophilic anaerobic digestion of swine manure. Bioresource Technology, 99(1), 1-6.
Carrère, H., Sialve, B., & Bernet, N. (2009). Improving pig manure conversion into biogas by thermal and thermo-chemical pretreatments. Bioresource Technology, 100(15), 3690-3694.
Hens, L., Cabello-Eras, J. J., Sagastume-Gutiérez, A., Garcia-Lorenzo, D., Cogollos-Martinez, J. B., & Vandecasteele, C. (2017). University–industry interaction on cleaner production. The case of the Cleaner Production Center at the University of Cienfuegos in Cuba, a country in transition. Journal of Cleaner Production, 142, 63-68.
Ye, J., Li, D., Sun, Y., Wang, G., Yuan, Z., Zhen, F., & Wang, Y. (2013). Improved biogas production from rice straw by co-digestion with kitchen waste and pig manure. Waste Management, 33(12), 2653-2658.
Wu, X., Yao, W., Zhu, J., & Miller, C. (2010). Biogas and CH 4 productivity by co-digesting swine manure with three crop residues as an external carbon source. Bioresource technology, 101(11), 4042-4047.
Møller, H. B., Sommer, S. G., & Ahring, B. K. (2004). Methane productivity of manure, straw and solid fractions of manure. Biomass and bioenergy, 26(5), 485-495.
Thu, C. T. T., Cuong, P. H., Van Chao, N., Trach, N. X., & Sommer, S. G. (2012). Manure management practices on biogas and non-biogas pig farms in developing countries–using livestock farms in Vietnam as an example. Journal of Cleaner Production, 27, 64-71.
Hansen, K. H., Angelidaki, I., & Ahring, B. K. (1998). Anaerobic digestion of swine manure: inhibition by ammonia. Water research, 32(1), 5-12.
Frandsen, T. Q., Rodhe, L., Baky, A., Edström, M., Sipilä, I., Petersen, S. L., & Tybirk, K. (2011). Best available technologies for pig manure biogas plants in the Baltic Sea Region.
Cabello, J. J., Sagastume, A., López-Bastida, E., Vandecasteele, C., & Hens, L. (2016). Water Footprint from Growing Potato Crops in Cuba. Tecnología y Ciencias del Agua, 7(1), 107-116.
Panichnumsin, P., Nopharatana, A., Ahring, B., & Chaiprasert, P. (2010). Production of methane by co-digestion of cassava pulp with various concentrations of pig manure. Biomass and Bioenergy, 34(8), 1117-1124.
Karakashev, D., Schmidt, J. E., & Angelidaki, I. (2008). Innovative process scheme for removal of organic matter, phosphorus and nitrogen from pig manure. Water Research, 42(15), 4083-4090.
Saeys, W., Mouazen, A. M., & Ramon, H. (2005). Potential for onsite and online analysis of pig manure using visible and near infrared reflectance spectroscopy. Biosystems engineering, 91(4), 393-402.
Dominguez, J., & Edwards, C. A. (1997). Effects of stocking rate and moisture content on the growth and maturation of Eisenia andrei (Oligochaeta) in pig manure. Soil biology and biochemistry, 29(3), 743-746.
Velthof, G. L., Nelemans, J. A., Oenema, O., & Kuikman, P. J. (2005). Gaseous nitrogen and carbon losses from pig manure derived from different diets. Journal of Environmental Quality, 34(2), 698-706.
Kerr, B. J., Ziemer, C. J., Trabue, S. L., Crouse, J. D., & Parkin, T. B. (2006). Manure composition of swine as affected by dietary protein and cellulose concentrations. Journal of animal science, 84(6), 1584-1592.
Tiquia, S. M., Tam, N. F. Y., & Hodgkiss, I. J. (1996). Effects of composting on phytotoxicity of spent pig-manure sawdust litter. Environmental Pollution, 93(3), 249-256.
Eras, J. J. C., Gutiérrez, A. S., Lorenzo, D. G., Martínez, J. B. C., Hens, L., & Vandecasteele, C. (2015). Bridging universities and industry through cleaner production activities. Experiences from the Cleaner Production Center at the University of Cienfuegos, Cuba. Journal of Cleaner Production, 108, 873-882.
Miller, D. N., & Varel, V. H. (2003). Swine manure composition affects the biochemical origins, composition, and accumulation of odorous compounds. Journal of animal science, 81(9), 2131-2138.
Dourmad, J. Y., & Jondreville, C. (2007). Impact of nutrition on nitrogen, phosphorus, Cu and Zn in pig manure, and on emissions of ammonia and odours. Livestock Science, 112(3), 192-198.
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