Development of a monitoring system for temperature, pressure and pH variables in an Anaerobic Biodigester
Desarrollo de un sistema de supervisión de las variables de temperatura, presión y pH en un Biodigestor Anaeróbico
Article Sidebar
PDF (Español) (Español (España))
FLIP
HTML (Español (España))
XML (Español (España))
La Revista ofrece Acceso Abierto bajo una licencia Creative Commons Attibution License
Esta obra está bajo una Licencia Creative Commons Atribución - No comercial - 4.0 Internacional.
Main Article Content
Perfil Google Scholar
Currently, it is sought that energy generation systems be friends with the environment in order to reduce the carbon footprint, alternative biomass-based energy generation systems, seek the use of pollutants in the generation of energy through of a biodigester. For the improvement of the process of obtaining energy, the system carried out the acquisition of data automatically, the detection of temperature, pressure and pH variables is proposed.
The automation of the process allows decisions to be taken in the study of the gas exploitation and extraction phase through the acquisition of data, making the most of the biosolids waste produced by agricultural activities. Our research focuses on the elaboration of a monitoring system which allows to analyze by means of a virtual instrument the variables of temperature, pressure and pH involved in the acquisition of data from the biodigester system, in order to level the organic load generated by the components of agricultural origin, the standard quality is poured directly to the causes of water and in open pit fields. The virtual instrument allows the supervision and modeling of the variables used in the study of the change of properties generating a favorable impact for the environment.
Downloads
Article Details
R. Kigozi, A. O. Aboyade, and E.Muzenda, “Sizing of an anaerobic biodigester for the organic fraction of municipal solid waste,” in Lecture Notes in Engineering and Computer Science, vol. 2, pp. 659–663,2014
H. Clemens, R. Bailis, A. Nyambane, and V. Ndung,“Energy for Sustainable Development Africa Biogas Partnership Program : A review of clean cooking implementation through market development in East Africa,” Energy Sustain. Dev., vol. 46, pp. 23–31,
Doi: https://doi.org/10.1016/j.esd.2018.05.012
M. E. Gavito et al., “Revista Mexicana de Biodiversidad Ecología , tecnología e innovación para la sustentabilidad : retos y perspectivas en México,” Enfermería Univ., vol. 88, pp. 150–160, 2017. Doi:https://doi.org/10.1016/j.rmb.2017.09.001
A. N. Matheri, C. Mbohwa, M. Belaid, and J. C. Ngila, “Design technology for bioenergy conversion of organic fraction of municipal solid waste,” Green Energy Technol., (9783319636115), pp.181–201,2018
K. Ortegon, “Life cycle engineering in an industrial engineering undergraduate program, from the classroom to the real life of students,” in Procedia CIRP, vol. 80, pp. 613–618, 2018.Doi:https://doi.org/10.1016/j.procir.2019.01.011
et al., “Influencia del pH sobre la digestión anaerobia de bio-residuos de origen municipal,” Rev. U.D.C.A Actual. Divulg. Científica, vol. 17(2), pp.553–562, 2014.
Regino, F. J., Gómez, J. A., & Jaramillo, H. Y. (2019). Development of a virtual instrument for the calculation of thermal efficiency under the assumptions of standard cold air in a 3500cc diesel engine, 2008.Doi: https://doi.org/10.1088/1742-6596/1409/1/012008
A. Chini et al., “Evaluation of deammonification reactor performance and microrganisms community during treatment of digestate from swine sludge CSTR biodigester,” Journal of Environmental Management., vol. 246, pp.19–26, 2018. Doi: https://doi.org/10.1016/j.jenvman.2019.05.113
L. F. Calza, C. B. Lima, C. E. C. Nogueira, J. A. C. Siqueira, and R. F.Santos, “Cost assessment of biodigester implementation and biogas-produced energy [Avaliação dos custos de implantação de biodigestores e da energia produzida pelo biogás],” Eng. Agric., vol. 35(6), pp. 990–997, 2015. Doi: https://doi.org/10.1590/1809-4430-Eng.Agric.v35n6p990-997/2015
X. Li, E. Mupondwa, and E. Mupondwa, “Commercial feasibility of an integrated closed-loopethanol-feedlot-biodigester system based on triticale feedstock in Canadian Prairies,” Renew. Sustain. Energy Rev., vol. 97, September, pp. 401–413, 2018.
E. C. Medrano, “Alternativas sostenibles para reducción del consumo en los servicios públicos de la vivienda rural en tunja, boyacá,” Universidad Santotomas 2017.
H. Hernández and E. Y. Ramírez, “Propuesta para el diseño de un biodigestor para el aprovechamiento de la materia orgánica generada en los frigoríficos de bogotá,” Proyecto de grado, Universidad Distrita Francisco José de Caldas, 2012.
C. A. Chavarín, S. O. Benítez, N. V Limón, and A. G. Ramírez, “Development of anaerobic biodigesters for the treatment of municipal organic waste and biogas generation for use as energy source,” in Proceedings of ANES/ASME XXX National Solar Energy Week, 2006, vol. 2006.
C. M. Plugge, “Biogas,” Microb. Biotechnol., vol. 10(5), pp. 1128–1130, 2017. Doi: https://doi.org/10.1111/1751-7915.12854
C. V. Garavito and D. R. R. Jiménez, “Diseño y construcción de un prototipo biodigestor tipo mixto para la producción y almacenamiento de gas metano.,” 2013
E. J. A. Rodríguez, J. W. M. Ocampo, and C. A. S. Ortega, “Medición de temperatura: sensores termoeléctricos,”Science & Technology , vol. 13(34), pp. 1–6, 2007
J. A. Somoza Chuay, J. E. Eirez Izquierdo, S. Pavoni Oliver, and E. Martín Rodríguez, “Construcción y caracterización de electrodos de Vidrio/ITO/PANI para la medición de pH,” RIELAC, vol. XXXV(3), p.p.33-38, 2014
F. A. Vega Reyes, “Transmisor de presión diferencial,” J. A. Somoza Chuay, J. E. Eirez Izquierdo, S. Pavoni Oliver, and E. Martín Rodríguez, “Construcción y caracterización de electrodos de Vidrio/ITO/PANI para la medición de pH,” RIELAC, vol. XXXV(3), pp.33-38, 2014, 2009.
T. Roy and P. Bhattacharjee, “A LabVIEW-based real-time modeling approach for detection of abnormalities in cancer cells,” Gene Reports, vol. 20, p.100788, Sep. 2020
E. N. Flórez-Solano, E. E. Espinel-Blanco, y J. E. Barbosa-Jaimes, “Desarrollo de un soldador por puntos para el laboratorio de proceso de manufactura de la Universidad Francisco de Paula Santander Ocaña”, Revista Ingenio, vol. 16, n.º 1, pp. 30–35, ene.2019.Doi: https://doi.org/10.22463/2011642X.2389
F. O. Díaz-Garcés y F. J. Regino-Ubarnes, “Desarrollo de una estrategia de control basado en ADRC, aplicada a un sistema de bola y viga”, Revista Ingenio, vol. 17, n.º 1, pp. 15–20, ene. 2020. Doi: https://doi.org/10.22463/2011642X.2391
