Authors
Abstract
This paper presents a methodology for the study of the increase of used tires generation and their collection. It starts from the modeling with systems dynamics to visualize the growth of the vehicle fleet and estimate the generation of used tires in the city of Bogotá. Subsequently, a Geographic Information System -GIS- was designed with the critical points of generation of used tires, where the city vehicle fleet and a collection route for this special waste were georeferenced. The GIS shows the critical points, the collection points and the potential points to expand the collection routes in different locations in the city of Bogota. Finally, the collection routes are determined in the areas where the greatest number of critical points without attention are present which are Engativá, Bosa and Barrios Unidos. In this way the intention is to contribute to the design of routes for the collection and management of used tires in Bogotá and other cities with similar problems.
References
Bosque-Sendra, J. (1997). Sistemas de información geográfica. Madrid, España: Ediciones Rialp.
Chalkias, C. and Lasaridi, K. (2011). Benefits from GIS Based Modelling for Municipal Solid Waste Management, Integrated Waste Management. Recuperado de https://www.intechopen.com/books/integrated-waste-management-volume-i/benefits-from-gis-based-modelling-for-municipal-solid-waste-management.
Che, Y. et al. (2013). Residents’ concerns and attitudes toward a municipal solid waste landfill: Integrating a questionnaire survey and GIS techniques. Environmental Monitoring and Assessment, 185(12), 10001-10013.
De Feo, G. and De Gisi, S. (2014). Using MCDA and GIS for hazardous waste landfill siting considering land scarcity for waste disposal. Waste Management, 34(11), 2225-2238.
Forrester, J. (1999). Industrial Dynamics. Waltham, USA: Pegasus Communications.
Gallardo, A. et al. (2014). Methodology to design a municipal solid waste generation and composition map: A case study. Waste Management, 34(11), 1920-1931.
Ibarra, D.W. y Redondo, J.M. (2015). Dinámica de sistemas, una herramienta para la educación ambiental en ingeniería. Revista Luna Azul, 41, 152-164.
Kinobe, J. (2015). Assessment of Urban Solid Waste Logistics Systems: The Case of Kampala, Uganda (tesis de posgrado). Swedish University of Agricultural Sciences, Upsala, Sweden.
Lakota, M. and Stajnko, D. (2013). Using of GIS Tools for Analysis of Organic Waste Management in Slovenia Region Pomurje. Procedia Technology, 8, 570-574.
Peláez, G.J., Velásquez, S. y Giraldo, D. (2017). Aplicaciones de caucho reciclado: una revisión de la literatura. Ciencia e Ingeniería Neogranadina, 27(2), 27-50.
Redondo, J.M., Ibarra-Vega, D., Monroy, L., Bermuedez, J. (2018). Evaluación de estrategias para la gestión integral de residuos de aparatos eléctricos y electrónicos. DYNA, 85, Número 205, p, 319-327.
SDM. Secretaría Distrital de Movilidad (2016). Parque automotor de Bogotá 2010-2016. Bogotá, Colombia: Alcaldía Mayor de Bogotá.
Sterman, J. (2000). Business Dynamics: Systems Thinking and Modeling for a Complex World with CD-ROM. New York, USA: McGraw-Hill Education.
Wan, Y. et al. (2017). A study of regional sustainable development based on GIS/RS and SD model ( case of Hadaqi Industrial Corridor. Journal of Cleaner Production, 142(2), 654-662.
Wu, H. et al. (2016). An innovative approach to managing demolition waste via GIS (geographic information system): A case study in Shenzhen city, China. Journal of Cleaner Production, 112(1), 494-503.
Xu, Z. and Coors, V. (2012). Combining system dynamics model, GIS and 3D visualization in sustainability assessment of urban residential development. Building and Environment, 47, 272-287.