Escudo Universidad de Pamplona

Repositorio Institucional

Universidad de Pamplona

Preservamos, organizamos y difundimos la producción académica, científica, investigativa y cultural de la Universidad de Pamplona, garantizando el acceso abierto al conocimiento generado por nuestra comunidad universitaria.

Explorar colecciones

  1. Repositorio Institucional Universidad de Pamplona
  2. Trabajos de pregrado y especialización
  3. Facultad de Ingenierías y Arquitectura
  4. Ingeniería Química
Por favor, use este identificador para citar o enlazar este ítem: https://repositoriodspace.unipamplona.edu.co/jspui/handle/20.500.12744/5406
Registro completo de metadatos
Campo DC Valor Lengua/Idioma
dc.contributor.authorGonzalez Gomez, María Paz.-
dc.date.accessioned2022-12-14T21:26:25Z-
dc.date.available2020-09-23-
dc.date.available2020-09-23-
dc.date.available2022-12-14T21:26:25Z-
dc.date.issued2020-
dc.identifier.citationGonzalez Gomez, M. P. (2020). Disposición de residuos sólidos: Revisión de alternativas para la fabricación de nuevos tipos de materiales usados en la industria de la construcción mediante el tratamiento de residuos sólidos de Tereftalato de Polietileno (PET) [Trabajo de Grado Pregrado, Universidad de Pamplona] Repositorio Hulago Universidad de Pamplona. http://repositoriodspace.unipamplona.edu.co/jspui/handle/20.500.12744/5406es_CO
dc.identifier.urihttp://repositoriodspace.unipamplona.edu.co/jspui/handle/20.500.12744/5406-
dc.descriptionLa autora no proporciona la información sobre este ítem.es_CO
dc.description.abstractLa autora no proporciona la información sobre este ítem.es_CO
dc.format.extent41es_CO
dc.format.mimetypeapplication/pdfes_CO
dc.language.isoeses_CO
dc.publisherUniversidad de Pamplona – Facultad de Ingenieras y Arquitectura.es_CO
dc.subjectLa autora no proporciona la información sobre este ítem.es_CO
dc.titleDisposición de residuos sólidos: Revisión de alternativas para la fabricación de nuevos tipos de materiales usados en la industria de la construcción mediante el tratamiento de residuos sólidos de Tereftalato de Polietileno (PET).es_CO
dc.typehttp://purl.org/coar/resource_type/c_7a1fes_CO
dc.typehttp://purl.org/coar/resource_type/c_7a1fes_CO
dc.date.accepted2020-06-23-
dc.date.accepted2020-06-23-
dc.relation.referencesBrown, G.H., Salle, E.M. (2000). Química Cuantitativa, Barcelona, España: Editorial REVERTÉ, S.A.es_CO
dc.relation.referencesZanni, E. (2008). Patología de La Construcción y Restauro de Obras de Arquitectura, Cordoba, Argentina: Editorial BRUJAS.es_CO
dc.relation.referencesRamos Castellanos, P. (2003). Residuos: Alternativas de Gestión, Salamanca, España: Edicciones Universidad de Salamanca.es_CO
dc.relation.referencesAudesirk, T., Audesirk, G., Byers, B.E. (2004). Biology: Life on Earth, Ciudad de Mexico: PRENTICE HALL INCes_CO
dc.relation.referencesMillar, A.A. Manejo de Agua y Producción Química, Chile: Instituto Interamericano de Cooperación para la Agricultures_CO
dc.relation.referencesFuentes, A., Castiñeiras, L., Queraltó, C. (1998). Bioquímica y Patología Molecular, Barcelona, España: Editorial REVERTÉ, S.Aes_CO
dc.relation.referencesMinisterio de ambiente y desarrollo sostenible. (03 de septiembre del 2018). Conceptos básicos de reciclaje. Recuperado de: https://www.minambiente.gov.co/es_CO
dc.relation.referencesBurbano de Ercilla, S., Burbano García, E., Gracia Muñoz, C. Física General, Madrid, España: Editorial TÉBARL S.L.es_CO
dc.relation.referencesHougen, O.A., Watson, K.M., Ragatz, R.A. Principios de Los Procesos Químicos, Tomo I, Barcelona, España: Editorial REVERTÉ.es_CO
dc.relation.referencesRosendo Ramos, D. Conceptos Básicos Del Reciclaje 1era ed, España: WANCEULEN EDITORIAL S.L.es_CO
dc.relation.referencesBueche, F. Ciencias Físicas 4th edición, Barcelona, España: Editorial REVERTÉ, S.A.es_CO
dc.relation.referencesAkshay, E.M., Palaniappan, R., Sowmya, C.F., Rasana, N., Jayanarayanan, K. (2020) Properties of Blends from Polypropylene and Recycled. Mater Today Proceedings, 24:359-368.es_CO
dc.relation.referencesRougeron, C. Aisalmiento Acústico y Térmico En La Construcción, Barcelona, España: Editores técnicos asociados S.A.es_CO
dc.relation.referencesRamsey, M. Glossary Oilfield 1st ed, Texas, USA: Texas Drilling Associateses_CO
dc.relation.referencesAllen, R.D. (2019). Waste PET: A Renewable Resource. Joule, 3(4):910.es_CO
dc.relation.referencesBeaumont, N.J., Aanesen ,M., Austen, M.C. (2019). Global ecological, social and economic impacts of marine plastic. Mar Pollution Bulletion, 142:189-195.es_CO
dc.relation.referencesWeiskopf, S.R., Rubenstein, M.A., Crozier, L.G. (2020). Climate change effects on biodiversity, ecosystems, ecosystem services, and natural resource management in the United States. Science of the Total Environment, 137:72-82es_CO
dc.relation.referencesZambrano-Monserrate, M.A., Ruano, M.A. (2020). Estimating the damage cost of plastic waste in Galapagos Islands: A contingent valuation approach. Marine Policy, 117:103933.es_CO
dc.relation.referencesSatya, S.K., Sreekanth, P.S.R. (2020). An experimental study on recycled polypropylene and high-density polyethylene and evaluation of their mechanical properties. Mater Today Proceedings, 20(4):1-5.es_CO
dc.relation.referencesProcuraduría General de la Nación. (03 de abril del 2019). Colombia genera tonelada de plástico al año. Recuperado de: https://www.procuraduria.gov.co/portal/es_CO
dc.relation.referencesChirayil, C.J., Mishra, R.K., Thomas, S. (2019). Materials Recovery, Direct Reuse and Incineration of PET Bottles. Recycling of Polyethylene Terephthalate Bottles, 19:37-60.es_CO
dc.relation.referencesGrumezescu, V., Grumezescu, A.M. (2017). Materials for biomedical engineering: Inorganic micro and nanostructures, Romania: Editorial Biomedical.es_CO
dc.relation.referencesAbdel-Shafy, H.I., Mansour, M.S.M. (2018). Solid waste issue: Sources, composition, disposal, recycling, and valorization. Egyptian Journal of Petroleum, 27(4):1275-1290.es_CO
dc.relation.referencesChae, Y., An, Y.J. (2018). Current research trends on plastic pollution and ecological impacts on the soil ecosystem: A review. Environmental Pollution, 240:387-395.es_CO
dc.relation.referencesNwafor, N.A., Walker, T.R. (2020) Resources , Conservation & Recycling Rethinking marine insurance and plastic pollution : food for thought. Resources, Conservation & Recycling, 161:104950.es_CO
dc.relation.referencesRani, A., Negi, S., Hussain, A., Kumar, S. (2019). Treatment of urban municipal landfill leachate utilizing garbage enzyme. Bioresource Technology, 297:122437.es_CO
dc.relation.referencesGu, F., Guo, J., Zhang, W., Summers, P.A., Hall, P. (2017). From waste plastics to industrial raw materials: A life cycle assessment of mechanical plastic recycling practice based on a real-world case study. Science of the Total Environment, 601:1192-1207.es_CO
dc.relation.referencesIsabel, M., Prieto, A., Saldaña, F.L., María P, Arias. (2018). Estudio técnico-económico para un plan de negocio en la producción de filamento tipo PET. Universidad Tecnológica del Centro de Veracruz, 350:1-12.es_CO
dc.relation.referencesLucia, C., Liñan, T. (2019). Estudio de prefactibilidad para la producción de carteras con diseños personalizados elaboradas a base de tela de poliester (PET). Universidad San Ignacio Loyola, 19(1):1-157.es_CO
dc.relation.referencesGreenpeace. (Febrero del 2019). Datos sobre la producción de plásticos. Recuperado de: https://es.greenpeace.org/es_CO
dc.relation.referencesBillmeyer, F.W. (2014). Ciencia de Los Polímeros 4th ed, España: Editorial REVERTÉes_CO
dc.relation.referencesZhang, H., Tumarkin, E., Sullan, R.M.A., Walker, G.C., Kumacheva, E. (2017). Exploring Microfluidic Routes to Microgels of Biological Polymers. Macromolecular Rapid Communications, 28(5):527-538.es_CO
dc.relation.referencesBaekeland, L.H. (1909). Original papers: The synthesis, constitution, and uses of bakelite. Industrial and Engineering Chemistry, 1(3):149-161.es_CO
dc.relation.referencesWang, Z., Peng, B., Huang, Y., Sun, G. (2019). Classification for plastic bottles recycling based on image recognition. Waste Management, 88:170-181.es_CO
dc.relation.referencesPatel, Y.S., Patel, H.S. (2017). Thermoplastic-thermosetting merged polyimides via furan-maleimide Diels – Alder polymerization. Arabian Journal of Chemistry, 10:1373- 1380.es_CO
dc.relation.referencesBakkali-hassani, C., Planes, M., Roos, K., Wirotius, A., Ibarboure, E. (2018). Synthesis of polyamide 6 with aramid units by combination of anionic ring- opening and condensation reactions. European Polymer Journal, 102:231-237.es_CO
dc.relation.referencesLopez Carrasquero, F. (2014). Fundamentos de Polímeros 2nd ed, Merida: Universidad de los Andeses_CO
dc.relation.referencesAkshaya, E.M., Palaniappan, R., Sowmya, C.F., Rasana, N., Jayanarayanan, K. (2020). Properties of Blends from Polypropylene and Recycled Polyethylene Terephthalate using a Compatibilizer. Mater Today Proceedings, 24:359-368.es_CO
dc.relation.referencesParolini, M., Ferrario, C., Felice, B. (2020). Interactive e ff ects between sinking polyethylene terephthalate ( PET ) microplastics deriving from water bottles and a benthic grazer. Journal of Hazardous Materials, 398:122848.es_CO
dc.relation.referencesGalo, G., Lima, M., Bachmann, L. (2018). Use of polyethylene terephthalate as a prosthetic component in the prosthesis on an overdenture implant. Materials Science & Engineering, 99:1341-1349.es_CO
dc.relation.referencesBarbaran, S., Cabanillas, M., Paredes, H.J., Rubio Rodriguez, L.E., Alvarez, Y., Quezada Medardo, A. (2018). Biodegradación de polietileno tereftalato (PET) por acción de Pseudomona aeruginosa, en condiciones de laboratorio. Universidad César Vallejo, 34:53.es_CO
dc.relation.referencesOteng-Ababio, M., Owusu-Sekyere, E., Amoah, S.T. (2017). Landfill externalities and property values dilemma–emerging insights from three Ghanaian cities. Journal of Contemporary African Studies, 35(3):349-369.es_CO
dc.relation.referencesObjetivos de Desarrollo Sostenible PNUD. (Junio del 2016). Objetivos medioambientales para los países pertenecientes a la ONU. Recuperado de: https://www.undp.ores_CO
dc.relation.referencesTan, S.T., Ho, W.S., Hashim, H., Lim, J.S., Lee, C.T. (2015). Waste Management Pinch Analysis (WAMPA) with Economic Assessment. Chemical Engineering Transactions, 45:145-150.es_CO
dc.relation.referencesMaskey, B. (2018). Determinants of Household Waste Segregation in Gorkha Municipality, Nepal. Journal of Sustainable Development, 11(1):1-15.es_CO
dc.relation.referencesSuthar, S., Singh, P. (2015). Household solid waste generation and composition in different familysize and socio-economic groups: A case study. Sustainable Cities and Society, 14(4):56-63. 48. Padilla, A.J., Trujillo, Jes_CO
dc.relation.referencesPadilla, A.J., Trujillo, J.C. (2018). Waste disposal and households’ heterogeneity. Identifying factors shaping attitudes towards source-separated recycling in Bogotá, Colombia. Waste Management, 74:16-33.es_CO
dc.relation.referencesChen, X., Yan, N. (2020). A brief overview of renewable plastics. Mater Today Sustainable, 7:100031.es_CO
dc.relation.referencesBriassoulis, D., Pikasi, A., Hiskakis, M. (2020). Recirculation potential of post consumer industrial bio-based plastics through mechanical recycling Techno-economic sustainability criteria and indicators. Polymer Degradation and Stability, 6:109217.es_CO
dc.relation.referencesBenavides, P.T., Dunn, J.B., Han, J., Biddy, M., Markham, J. (2018). Exploring Comparative Energy and Environmental Benefits of Virgin, Recycled, and Bio-Derived PET Bottles. ACS Sustainable Chemistry and Engineering, 6(8):9725-9733.es_CO
dc.relation.referencesSangwan, S.K., Choudhary, K., Batra, C. (2018). Environmental impact assessment of a ceramic tile supply chain – a case study. International Journal of Sustainable engineering, 11(3):211-216.es_CO
dc.relation.referencesHamade, R., Hadchiti, R., Ammouri, A. (2020). Making Environmental Case Case for for Reusable Reusable PET PET Bottles Bottles. Procedia Manufacturing, 43:201-207.es_CO
dc.relation.referencesTshifularo, C.A., Patnaik, A. (2020). Recycling of Plastics into Textile Raw Materials and Products. Sustainable Technologies for Fashion and Textiles, 11:311-326.es_CO
dc.relation.referencesAl-sabagh, A.M., Yehia, F.Z., Eshaq, G., Rabie, A.M., Elmetwally AE. (2016). Greener routes for recycling of polyethylene terephthalate. Egyptian Journal of Petroleum, 25(1):53-64.es_CO
dc.relation.referencesEsquer, R., García, J.J. (2019). Metal-catalysed Poly ( Ethylene ) terephthalate and polyurethane degradations by glycolysis. Journal of Organometallic Chemistry, 902:120972.es_CO
dc.relation.referencesHan, M., (2019). Depolymerization of PET Bottle via Methanolysis and Hydrolysis. Recycling of Polyethylene Terephthalate Bottles, 19:85-108.es_CO
dc.relation.referencesChen, M., Lai, C., Chen, H. (2019). Preparation of long-chain branched polyethylene terephthalates ( PETs ), and crystallization behaviors , thermal characteristics , and hydrolysis resistance of their biaxially stretching films. Journal of Physical and Chemistry Solids, 129:354-367.es_CO
dc.relation.referencesSandin, G., Peters, G.M. (2018). Environmental impact of textile reuse and recycling e A review. Journal of Cleaner Production, 184:353-365.es_CO
dc.relation.referencesGug, J.I., Cacciola, D., Sobkowicz, M.J. (2015). Processing and properties of a solid energy fuel from municipal solid waste (MSW) and recycled plastics. Waste Management, 35:283-292.es_CO
dc.relation.referencesFranco-Urquiza, E.A., Maspoch, M. (2017). Evaluación de las propiedades mecánicas en mezclas de Poliestireno/Polietileno. Coloquio Latinoamericano de Fractura y Fatiga, 114(08222es_CO
dc.relation.referencesPatil, P.S. (2015). Behavior of concrete which is partially replaced with waste plastic. International Journal of Innovate Technology and Exploring Engineering, 11(4).es_CO
dc.relation.referencesJassim, A.K. (2017). Recycling of Polyethylene Waste to Produce Plastic Cement. Procedia Manufacturing, 8:635-642.es_CO
dc.relation.referencesKang, D.H., Auras, R., Singh, J. (2016). Life cycle assessment of non-alcoholic single serve polyethylene terephthalate beverage bottles in the state of California. Resources Conservation & Recycling, 116:45-52es_CO
dc.relation.referencesOliveux, G., Dandy, L.O., Leek,e G.A. (2015). Current status of recycling of fibre reinforced polymers: Review of technologies, reuse and resulting properties. Progress in Materials Science, 72:61-99.es_CO
dc.relation.referencesGaggino, R. (2015). Emprendimiento de fabricación de ladrillos con plástico. Revista invi, 23(63).es_CO
dc.relation.referencesIRAM 4044: Acústica. Protección contra el ruido en edificios. Requisitos de aislamiento acústico mínimo. Método de medición y clasificación. Cerramientos y aberturas, verticales y horizontales, 2015.es_CO
dc.relation.referencesMadrid, J., Bolobosky, M. (2018). Manufacture of bricks based on PET polymers and metal chips. Universidad Tecnológica de Panamá, 4:33-38.es_CO
dc.relation.referencesASTM C67-07: Standard Test Methods for Sampling and Testing Brick and Structural Clay Tile, ASTM International, West Conshohocken, PA, 2007es_CO
dc.relation.referencesASTM C56 - 13: Standard Specification for Structural Clay Nonloadbearing Tile, ASTM International, West Conshohocken, PA, 2017.es_CO
dc.relation.referencesGarcia, S., Bracho, N. (2019). Study of the effect of adding plastic residues in the manufacture of concrete hollow blocks. Revista Latinoamericana de Metalurgia de Materiales, 16:55-5es_CO
dc.relation.referencesPin Parrales, J.H. (2019). Prototipo para un bloque de encastre en base de PET para aplicación en una vivienda planta baja. Universidad Laica Vicente Rocafuerte de Guayaquil, 1-98es_CO
dc.relation.referencesChamorro, H. (2006). Funciones De Las Paredes 1st ed. Argentina: Editorial EL POLITÉCNICO.es_CO
dc.relation.referencesRojas Trejos, D., Lopez Pareja, J.D. (2o19). Planteamiento y propuesta de un ladrillo ecológico a base de PET. Universidad Católica de Manizales,1-120.es_CO
dc.relation.referencesPiñeros Moreno, M.E., Herrera Muriel, D. (2018). Proyecto de factibilidad económica para la fabricación de bloques con agregados de plástico recicladO (PET), aplicados en la construcción de vivienda. Universidad Católica de Colombia,1-118.es_CO
dc.relation.referencesSarhan, S., Pasquire, C., Manu, E., King, A. (2017). Contractual governance as a source of institutionalised waste in construction: A review, implications, and road map for future research directions. International Journal of Managing Projects in Business, 10(3):550-577.es_CO
dc.relation.referencesHan, I., Wee, G.N., No, J.H., Lee, T.K. (2018). Pollution level and reusability of the waste soil generated from demolition of a rural railway. Environmental Pollution, 240:867-874.es_CO
dc.relation.referencesKong, L., Ma, B. (2020). Evaluation of environmental impact of construction waste disposal based on fuzzy set analysis. Environmental Technology & Innovation, 19:100877.es_CO
dc.relation.referencesDing, Z., Zhu, M., Tam, V.W.Y., Yi, G., Tran, C.N.N. (2018). A system dynamics-based environmental benefit assessment model of construction waste reduction management at the design and construction stages. Journal of Cleaner Production, 176:676-692.es_CO
dc.relation.referencesArulrajah, A., Yaghoubi, E., Wong, Y.C., Horpibulsuk, S. (2017). Recycled plastic granules and demolition wastes as construction materials: Resilient moduli and strength characteristics. Construction and Building Materials, 147:639-647.es_CO
dc.relation.referencesPerera, S., Arulrajah ,A., Wong, Y.C., Horpibulsuk, S., Maghool, F. (2019). Utilizing recycled PET blends with demolition wastes as construction materials. Construction and Building Materials, 221:200-209.es_CO
dc.relation.referencesSaha, G. (2015). Basic of PET Imaging: Physics, Chemistry, and Regulations 4th ed. USA: Editorial Springer Science & Business Mediaes_CO
dc.relation.referencesArulrajah, A., Perera, S., Wong, Y.C., Horpibulsuk, S., Maghool, F. (2020). Stiffness and flexural strength evaluation of cement stabilized PET blends with demolition wastes. Construction and Building Materials, 239:117819.es_CO
dc.relation.referencesASTM C131-03: Standard Test Method for Resistance to Degradation of Coarse Aggregate of Small Size by Impact Abrasion on Machine in Los Angeles ASTM International, West Conshohocken, PA, 2008es_CO
dc.rights.accessrightshttp://purl.org/coar/access_right/c_abf2es_CO
dc.type.coarversionhttp://purl.org/coar/resource_type/c_2df8fbb1es_CO
Aparece en las colecciones: Ingeniería Química

Ficheros en este ítem:
Fichero Descripción Tamaño Formato  
Gonzalez_2020_TG.pdfGonzalez_2020_TG649,18 kBAdobe PDFVisualizar/Abrir
Mostrar el registro sencillo del ítem


Los ítems de DSpace están protegidos por copyright, con todos los derechos reservados, a menos que se indique lo contrario.