Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento

Trabajo de investigación

Autores:: Lucero-Sánchez, Keiner
Monroy-Cárdenas, Luisa Fernanda

Tipo de recurso:: Trabajo de grado de pregrado

Fecha de publicación:: 2021

Institución:: Universidad Católica de Colombia

Repositorio:: RIUCaC - Repositorio U. Católica

Idioma:: spa

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dc.title.spa.fl_str_mv	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
title	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
spellingShingle	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento CONCRETO MODIFICADO PÓRTICOS ALGORITMO DE EVOLUCIÓN DIFERENCIAL POTENCIAL DE CALENTAMIENTO GLOBAL CENIZAS VOLANTES AGREGADOS RECICLADOS
title_short	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
title_full	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
title_fullStr	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
title_full_unstemmed	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
title_sort	Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento
dc.creator.fl_str_mv	Lucero-Sánchez, Keiner Monroy-Cárdenas, Luisa Fernanda
dc.contributor.advisor.none.fl_str_mv	Contreras-Bejarano, Oscar
dc.contributor.author.none.fl_str_mv	Lucero-Sánchez, Keiner Monroy-Cárdenas, Luisa Fernanda
dc.subject.proposal.spa.fl_str_mv	CONCRETO MODIFICADO PÓRTICOS ALGORITMO DE EVOLUCIÓN DIFERENCIAL POTENCIAL DE CALENTAMIENTO GLOBAL CENIZAS VOLANTES AGREGADOS RECICLADOS
topic	CONCRETO MODIFICADO PÓRTICOS ALGORITMO DE EVOLUCIÓN DIFERENCIAL POTENCIAL DE CALENTAMIENTO GLOBAL CENIZAS VOLANTES AGREGADOS RECICLADOS
description	Trabajo de investigación
publishDate	2021
dc.date.accessioned.none.fl_str_mv	2021-09-15T17:03:02Z
dc.date.available.none.fl_str_mv	2021-09-15T17:03:02Z
dc.date.issued.none.fl_str_mv	2021
dc.type.spa.fl_str_mv	Trabajo de grado - Pregrado
dc.type.coarversion.fl_str_mv	http://purl.org/coar/version/c_fa2ee174bc00049f http://purl.org/coar/version/c_71e4c1898caa6e32
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dc.type.content.spa.fl_str_mv	Text
dc.type.driver.spa.fl_str_mv	info:eu-repo/semantics/bachelorThesis
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dc.identifier.citation.none.fl_str_mv	Lucero-Sánchez, K. & Monroy-Cárdenas, L. F. (2021). Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento. Trabajo de Grado. Universidad Católica de Colombia. Facultad de Ingeniería. Programa de Ingeniería Civil. Bogotá, Colombia
dc.identifier.uri.none.fl_str_mv	https://hdl.handle.net/10983/26619
identifier_str_mv	Lucero-Sánchez, K. & Monroy-Cárdenas, L. F. (2021). Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento. Trabajo de Grado. Universidad Católica de Colombia. Facultad de Ingeniería. Programa de Ingeniería Civil. Bogotá, Colombia
url	https://hdl.handle.net/10983/26619
dc.language.iso.spa.fl_str_mv	spa
language	spa
dc.relation.references.spa.fl_str_mv	R. Kurda and J. D. Brito, \A comparative study of the mechanical and life cycle assessment of high-content y ash and recycled aggregates concrete," vol. 29, no. December 2019, 2020. S. PATTERSON, \GROWING BRICKS AND MORE WAYS TO SHRINK CONCRETE'S CARBON FOOTPRINT," The Wall Steeet Journal, 2020. L. Rodgers, \La enorme fuente de emisiones de CO2 que est a por todas partes y que quiz as no conoc as," BBC News, 2018. E. L. Pereira, A. L. de Oliveira Junior, and A. G. Fineza, \Optimization of mechanical properties in concrete reinforced with bers from solid urban wastes (PET bottles) for the production of ecological concrete," Construction and Building Materials, vol. 149, pp. 837{848, 2017. J. F. Brotchie, \Optimization and robustness of structural engineering systems," Engineering Structures, vol. 19, no. 4, pp. 289{292, 1997. W. M. Jenkins, \On the application of natural algorithms to structural design optimization," Engineering Structures, vol. 19, no. 4, pp. 302{308, 1997. Y. H. Lin, Y. Y. Tyan, T. P. Chang, and C. Y. Chang, \An assessment of optimal mixture for concrete made with recycled concrete aggregates," Cement and Concrete Research, vol. 34, no. 8, pp. 1373{1380, 2004. W. Wang, R. Zmeureanu, and H. Rivard, \Applying multi-objective genetic algorithms in green building design optimization," Building and Environment, vol. 40, no. 11, pp. 1512{1525, 2005. J. S. Damtoft, J. Lukasik, D. Herfort, D. Sorrentino, and E. M. Gartner, \Sustainable development and climate change initiatives," Cement and Concrete Research, vol. 38, no. 2, pp. 115{127, 2008. I. Paya-Zaforteza, V. Yepes, A. Hospitaler, and F. Gonz alez-Vidosa, \CO2- optimization of reinforced concrete frames by simulated annealing," Engineering Structures, vol. 31, no. 7, pp. 1501{1508, 2009. D. P. Bentz, A. S. Hansen, and J. M. Guynn, \Optimization of cement and y ash particle sizes to produce sustainable concretes," Cement and Concrete Composites, vol. 33, no. 8, pp. 824{831, 2011. D. Yeo and R. D. Gabbai, \Sustainable design of reinforced concrete structures through embodied energy optimization," Energy and Buildings, vol. 43, no. 8, pp. 2028{2033, 2011. C. V. Camp and A. Assadollahi, \CO2 and cost optimization of reinforced concrete footings using a hybrid big bang-big crunch algorithm," Structural and Multidisciplinary Optimization, vol. 48, no. 2, pp. 411{426, 2013. T. Proske, S. Hainer, M. Rezvani, and C. A. Graubner, \Eco-Friendly Concretes With Reduced Water and Cement Content: Mix Design Principles and Experimental Tests," Handbook of Low Carbon Concrete, vol. 51, pp. 63{87, 2013. G. F. de Medeiros and M. Kripka, \Optimization of reinforced concrete columns according to di erent environmental impact assessment parameters," Enginee- ring Structures, vol. 59, pp. 185{194, 2014. Jane Margolies, \Concrete, a Centuries-Old Material, Gets a New Recipe," The New York Times, 2020. C. A. Reyna Pari, \Reutilizaci on de Pl astico Pet, Papel y Bagazo de Ca~na de Az ucar, como materia prima en la Elaboraci on de Concreto Ecol ogico para la Construcci on de Viviendas de bajo costo," Lexus, no. None, p. 70, 2016. C. Mauricio Bedoya-Montoya, \Sustainable house construction with soil cement blocks: From waste to material," Revista De Arquitectura, vol. 20, no. 1, pp. 62{ 70, 2018. Mariette DiChristina, \Low-Carbon Cement Can Help Combat Climate Change," Scienti c American, 2020. J. Bautista and N. Loaiza, \La Construcci on Sostenible Aplicada a Las Viviendas De Inter es Social En Colombia," Boletin Semillas Ambientales, vol. 11, no. 1, pp. 86{110, 2017. H. Acevedo Agudelo, A. asquez Hern andez@, and D. A. Ramirez Cardona, \Sostenibilidad: Actualidad y necesidad en el sector de la construcci on en Colombia," Revista Gestion y Ambiente, vol. 15, no. 1, pp. 105{118, 2012. Y. C. Yoon, K. H. Kim, S. H. Lee, and D. Yeo, \Sustainable design for reinforced concrete columns through embodied energy and CO2 emission optimization," Energy and Buildings, vol. 174, pp. 44{53, 2018. R. Storn and K. Price, \Di erential Evolution - A Simple and E cient Heuristic for Global Optimization over Continuous Spaces," Journal of Global Optimiza- tion, vol. 11, no. 4, pp. 341{359, 1997. S. Kiranyaz, \Particle swarm optimization," Adaptation, Learning, and Opti- mization, vol. 15, pp. 45{82, 2014. R. Eberhart and J. Kennedy, \A New Optimizer Using Particle Swarm Theory," pp. 39{43, 1995. F. Y. Cheng, Matrix Analysis of Structural Dynamics: Applications and Earth- quake Engineering. Civil and Environmental Engineering, CRC Press, 2017. J. Serra, \Tablas estad sticas," Universdad de Granada, 2002. R. a Bellido@, J. alez Such@, and J. a@, \Pruebas no Param etricas. SPSS. Kolmogorov Smirnov," Grupo de innovacion Educativa. Universidad de Valencia, pp. 1{5, 2010. R. Simard and P. L'Ecuyer, \Computing the Two-Sided Kolmogorov-Smirnov Distribution," Journal of Statistical Software, vol. 1, no. 1, pp. 128{129, 2011. G. Runger and D. Montgomery, Applied Statistics and Probability for Engineers. 5 ed., 2011. A. S. Nowak and K. R. Collins, Reliability of Structures. McGraw-Hill civil engineering series, McGraw-Hill, 2000. L. Taiz and E. Zeiger, Fisiologia vegetal. Ciencies experimentals/ Experimental Sciences, Universitat Jaume I, 2006. M. S anchez-Silva and C. G omez, \Risk assessment and management of civil infrastructure networks: A systems approach," in Handbook of Seismic Risk Analysis and Management of Civil Infrastructure Systems, pp. 437{464, Elsevier Inc., apr 2013. G. aceres, Samuel Belizario Quispe@, \Utilizaci on de la ceniza volante en la dosi caci on del concreto como sustituto del cemento," evista de Investigaciones Altoandinas, 2018. B. Lu, C. Shi, J. Zheng, and T. C. Ling, \Carbon dioxide sequestration on recycled aggregates," in Carbon Dioxide Sequestration in Cementitious Cons- truction Materials, pp. 247{277, Elsevier, jan 2018. J. Martin, \Glasses and ceramics," in Materials for Engineering, pp. 133{158, Elsevier, jan 2006. P. C. Nkinamubanzi, S. Mantellato, and R. J. Flatt, \Superplasticizers in practice," in Science and Technology of Concrete Admixtures, pp. 353{377, Elsevier Inc., jan 2016. A. Ramos, P. Sanchez, J. M. Ferrer, J. Barquin, and P. Linares, \Modelos Matematicos De Optimizaci on," Pdf, vol. 2, p. 55, 2010. H. Lu, J. Chen, and L. Guo, \Energy Quality Management," in Comprehensive Energy Systems, vol. 5-5, pp. 258{314, Elsevier Inc., feb 2018. N. To si c, S. Marinkovi c, T. Da si c, and M. Stani c, \Multicriteria optimization of natural and recycled aggregate concrete for structural use," Journal of Cleaner Production, vol. 87, no. 1, pp. 766{776, 2015. H. Dilbas, O. C ak r, and H. Y ld r m, \Experimental investigation on properties of recycled aggregate concrete with optimized Ball Milling Method," Construc- tion and Building Materials, vol. 252, pp. 716{726, 2019. O. C ak r and H. Dilbas, \Durability properties of treated recycled aggregate concrete: E ect of optimized ball mill method," Construction and Building Materials, vol. 268, 2021. S. R. Salimbahrami and R. Shakeri, \Experimental investigation and comparative machine-learning prediction of compressive strength of recycled aggregate concrete," Soft Computing, vol. 256, 2020. J. Feng, G. Yin, H. Tuo, and Z. Niu, \Parameter optimization and regression analysis for multi-index of hybrid ber-reinforced recycled coarse aggregate concrete using orthogonal experimental design," Construction and Building Materials, vol. 267, 2021. R. Kurda, J. de Brito, and J. D. Silvestre, \CONCRETop method: Optimization of concrete with various incorporation ratios of y ash and recycled aggregates in terms of quality performance and life-cycle cost and environmental impacts," Journal of Cleaner Production, vol. 226, pp. 642{657, 2019. V. J. Gan, J. C. Cheng, and I. M. Lo, \Integrating life cycle assessment and multi-objective optimization for economical and environmentally sustainable supply of aggregate," Journal of Cleaner Production, vol. 113, pp. 76{85, 2015. H. Islam, M. Jollands, S. Setunge, and M. A. Bhuiyan, \Optimization approach of balancing life cycle cost and environmental impacts on residential building design," Energy and Buildings, vol. 87, pp. 282{292, 2015. M. Moini, I. Flores-Vivian, A. Amirjanov, and K. Sobolev, \The optimization of aggregate blends for sustainable low cement concrete," Construction and Building Materials, vol. 93, pp. 627{634, 2015. R. Yu, Q. Song, X. Wang, Z. Zhang, Z. Shui, and H. J. Brouwers, \Sustainable development of Ultra-High Performance Fibre Reinforced Concrete (UHPFRC): Towards to an optimized concrete matrix and e cient bre application," Jour- nal of Cleaner Production, vol. 162, pp. 220{233, 2017. M. Kripka, G. F. Medeiros, and A. C. Lemonge, \Use of optimization for automatic grouping of beam cross-section dimensions in reinforced concrete building structures," Engineering Structures, vol. 99, pp. 311{318, 2015. C. Zheng and M. Lu, \Optimized Reinforcement Detailing Design for Sustainable Construction: Slab Case Study," Procedia Engineering, vol. 145, pp. 1478{ 1485, 2016. L. H. Xu, X. T. Yan, and Z. X. Li, \Development of BP-based seismic behavior optimization of RC and steel frame structures," Engineering Structures, vol. 164, no. October 2017, pp. 214{229, 2018. J. Ferreiro-Cabello, E. Fraile-Garcia, E. Martinez de Pison Ascacibar, and F. J. Martinez de Pison Ascacibar, \Metamodel-based design optimization of structural one-way slabs based on deep learning neural networks to reduce environmental impact," Engineering Structures, vol. 155, no. November 2017, pp. 91{ 101, 2018. T. Garc a-Segura and V. Yepes, \Multiobjective optimization of post-tensioned concrete box-girder road bridges considering cost, CO2 emissions, and safety," Engineering Structures, vol. 125, pp. 325{336, 2016. T. Garc a-Segura, V. Penad es-Pl a, and V. Yepes, \Sustainable bridge design by metamodel-assisted multi-objective optimization and decision-making under uncertainty," Journal of Cleaner Production, vol. 202, pp. 904{915, 2018. A. R. Shooli, A. R. Vosoughi, and M. R. Banan, \A mixed GA-PSO-based approach for performance-based design optimization of 2D reinforced concrete special moment-resisting frames," vol. 85, 2019. Ministerio Ambiente Vivienda y Desarrollo Territorial, \Titulo A - Requisitos Generales de Dise~no y Construcci on Sismo Resistente," Nsr-10, vol. Titulo A, pp. 1{174, 2010.
dc.rights.spa.fl_str_mv	Derechos Reservados - Universidad Católica de Colombia, 2021
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rights_invalid_str_mv	Derechos Reservados - Universidad Católica de Colombia, 2021 Atribución-NoComercial-SinDerivadas 4.0 Internacional (CC BY-NC-ND 4.0) http://purl.org/coar/access_right/c_abf2
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dc.format.extent.spa.fl_str_mv	99 páginas
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dc.publisher.spa.fl_str_mv	Universidad Católica de Colombia
dc.publisher.faculty.spa.fl_str_mv	Facultad de Ingeniería
dc.publisher.place.spa.fl_str_mv	Bogotá
dc.publisher.program.spa.fl_str_mv	Ingeniería Civil
institution	Universidad Católica de Colombia
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spelling	Contreras-Bejarano, Oscarae6f756d-1705-46ea-9f03-e1e4d9e265df-1Lucero-Sánchez, Keiner82600124-d4a4-4aec-a21a-dcb156aba040-1Monroy-Cárdenas, Luisa Fernanda2d33b150-368a-4c49-998b-c4bb85cf5f8a-12021-09-15T17:03:02Z2021-09-15T17:03:02Z2021Trabajo de investigaciónEl trabajo de investigación presentado realiza la optimización del potencial de calentamiento global (GWP) generado por el concreto convencional en tres pórticos de tres, seis y nueve pisos. Este trabajo se realizó a partir del acople del Algoritmo de evolución diferencia (DEA), el análisis matricial para pórticos bidimensionales y la información de distintos concretos modificados con agregados reciclados finos, agregados reciclado gruesos y cenizas volantes.PregradoIngeniero Civil1. INTRODUCCIÓN 2. ANTECEDENTES Y JUSTIFICACIÓN 3. PLANTEAMIENTO Y FORMULACIÓN DEL PROBLEMA 4. MARCO DE REFERENCIA 5. ESTADO DEL ARTE 6. OBJETIVOS 7. ALCANCES Y LIMITACIONES 8. METODOLOGÍA 9. MODELOS A OPTIMIZAR 10. ALGORITMOS ACOPLADOS 11. PÓRTICOS OPTIMIZADOS 12. ANÁLISIS PROBABILÍSTICA 13. CONCLUSIONES Y RECOMENDACIONES99 páginasapplication/pdfLucero-Sánchez, K. & Monroy-Cárdenas, L. F. (2021). Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento. Trabajo de Grado. Universidad Católica de Colombia. Facultad de Ingeniería. Programa de Ingeniería Civil. Bogotá, Colombiahttps://hdl.handle.net/10983/26619spaUniversidad Católica de ColombiaFacultad de IngenieríaBogotáIngeniería CivilR. Kurda and J. D. Brito, \A comparative study of the mechanical and life cycle assessment of high-content y ash and recycled aggregates concrete," vol. 29, no. December 2019, 2020.S. PATTERSON, \GROWING BRICKS AND MORE WAYS TO SHRINK CONCRETE'S CARBON FOOTPRINT," The Wall Steeet Journal, 2020.L. Rodgers, \La enorme fuente de emisiones de CO2 que est a por todas partes y que quiz as no conoc as," BBC News, 2018.E. L. Pereira, A. L. de Oliveira Junior, and A. G. Fineza, \Optimization of mechanical properties in concrete reinforced with bers from solid urban wastes (PET bottles) for the production of ecological concrete," Construction and Building Materials, vol. 149, pp. 837{848, 2017.J. F. Brotchie, \Optimization and robustness of structural engineering systems," Engineering Structures, vol. 19, no. 4, pp. 289{292, 1997.W. M. Jenkins, \On the application of natural algorithms to structural design optimization," Engineering Structures, vol. 19, no. 4, pp. 302{308, 1997.Y. H. Lin, Y. Y. Tyan, T. P. Chang, and C. Y. Chang, \An assessment of optimal mixture for concrete made with recycled concrete aggregates," Cement and Concrete Research, vol. 34, no. 8, pp. 1373{1380, 2004.W. Wang, R. Zmeureanu, and H. Rivard, \Applying multi-objective genetic algorithms in green building design optimization," Building and Environment, vol. 40, no. 11, pp. 1512{1525, 2005.J. S. Damtoft, J. Lukasik, D. Herfort, D. Sorrentino, and E. M. Gartner, \Sustainable development and climate change initiatives," Cement and Concrete Research, vol. 38, no. 2, pp. 115{127, 2008.I. Paya-Zaforteza, V. Yepes, A. Hospitaler, and F. Gonz alez-Vidosa, \CO2- optimization of reinforced concrete frames by simulated annealing," Engineering Structures, vol. 31, no. 7, pp. 1501{1508, 2009.D. P. Bentz, A. S. Hansen, and J. M. Guynn, \Optimization of cement and y ash particle sizes to produce sustainable concretes," Cement and Concrete Composites, vol. 33, no. 8, pp. 824{831, 2011.D. Yeo and R. D. Gabbai, \Sustainable design of reinforced concrete structures through embodied energy optimization," Energy and Buildings, vol. 43, no. 8, pp. 2028{2033, 2011.C. V. Camp and A. Assadollahi, \CO2 and cost optimization of reinforced concrete footings using a hybrid big bang-big crunch algorithm," Structural and Multidisciplinary Optimization, vol. 48, no. 2, pp. 411{426, 2013.T. Proske, S. Hainer, M. Rezvani, and C. A. Graubner, \Eco-Friendly Concretes With Reduced Water and Cement Content: Mix Design Principles and Experimental Tests," Handbook of Low Carbon Concrete, vol. 51, pp. 63{87, 2013.G. F. de Medeiros and M. Kripka, \Optimization of reinforced concrete columns according to di erent environmental impact assessment parameters," Enginee- ring Structures, vol. 59, pp. 185{194, 2014.Jane Margolies, \Concrete, a Centuries-Old Material, Gets a New Recipe," The New York Times, 2020.C. A. Reyna Pari, \Reutilizaci on de Pl astico Pet, Papel y Bagazo de Ca~na de Az ucar, como materia prima en la Elaboraci on de Concreto Ecol ogico para la Construcci on de Viviendas de bajo costo," Lexus, no. None, p. 70, 2016.C. Mauricio Bedoya-Montoya, \Sustainable house construction with soil cement blocks: From waste to material," Revista De Arquitectura, vol. 20, no. 1, pp. 62{ 70, 2018.Mariette DiChristina, \Low-Carbon Cement Can Help Combat Climate Change," Scienti c American, 2020.J. Bautista and N. Loaiza, \La Construcci on Sostenible Aplicada a Las Viviendas De Inter es Social En Colombia," Boletin Semillas Ambientales, vol. 11, no. 1, pp. 86{110, 2017.H. Acevedo Agudelo, A. asquez Hern andez@, and D. A. Ramirez Cardona, \Sostenibilidad: Actualidad y necesidad en el sector de la construcci on en Colombia," Revista Gestion y Ambiente, vol. 15, no. 1, pp. 105{118, 2012.Y. C. Yoon, K. H. Kim, S. H. Lee, and D. Yeo, \Sustainable design for reinforced concrete columns through embodied energy and CO2 emission optimization," Energy and Buildings, vol. 174, pp. 44{53, 2018.R. Storn and K. Price, \Di erential Evolution - A Simple and E cient Heuristic for Global Optimization over Continuous Spaces," Journal of Global Optimiza- tion, vol. 11, no. 4, pp. 341{359, 1997.S. Kiranyaz, \Particle swarm optimization," Adaptation, Learning, and Opti- mization, vol. 15, pp. 45{82, 2014.R. Eberhart and J. Kennedy, \A New Optimizer Using Particle Swarm Theory," pp. 39{43, 1995.F. Y. Cheng, Matrix Analysis of Structural Dynamics: Applications and Earth- quake Engineering. Civil and Environmental Engineering, CRC Press, 2017.J. Serra, \Tablas estad sticas," Universdad de Granada, 2002.R. a Bellido@, J. alez Such@, and J. a@, \Pruebas no Param etricas. SPSS. Kolmogorov Smirnov," Grupo de innovacion Educativa. Universidad de Valencia, pp. 1{5, 2010.R. Simard and P. L'Ecuyer, \Computing the Two-Sided Kolmogorov-Smirnov Distribution," Journal of Statistical Software, vol. 1, no. 1, pp. 128{129, 2011.G. Runger and D. Montgomery, Applied Statistics and Probability for Engineers. 5 ed., 2011.A. S. Nowak and K. R. Collins, Reliability of Structures. McGraw-Hill civil engineering series, McGraw-Hill, 2000.L. Taiz and E. Zeiger, Fisiologia vegetal. Ciencies experimentals/ Experimental Sciences, Universitat Jaume I, 2006.M. S anchez-Silva and C. G omez, \Risk assessment and management of civil infrastructure networks: A systems approach," in Handbook of Seismic Risk Analysis and Management of Civil Infrastructure Systems, pp. 437{464, Elsevier Inc., apr 2013.G. aceres, Samuel Belizario Quispe@, \Utilizaci on de la ceniza volante en la dosi caci on del concreto como sustituto del cemento," evista de Investigaciones Altoandinas, 2018.B. Lu, C. Shi, J. Zheng, and T. C. Ling, \Carbon dioxide sequestration on recycled aggregates," in Carbon Dioxide Sequestration in Cementitious Cons- truction Materials, pp. 247{277, Elsevier, jan 2018.J. Martin, \Glasses and ceramics," in Materials for Engineering, pp. 133{158, Elsevier, jan 2006.P. C. Nkinamubanzi, S. Mantellato, and R. J. Flatt, \Superplasticizers in practice," in Science and Technology of Concrete Admixtures, pp. 353{377, Elsevier Inc., jan 2016.A. Ramos, P. Sanchez, J. M. Ferrer, J. Barquin, and P. Linares, \Modelos Matematicos De Optimizaci on," Pdf, vol. 2, p. 55, 2010.H. Lu, J. Chen, and L. Guo, \Energy Quality Management," in Comprehensive Energy Systems, vol. 5-5, pp. 258{314, Elsevier Inc., feb 2018.N. To si c, S. Marinkovi c, T. Da si c, and M. Stani c, \Multicriteria optimization of natural and recycled aggregate concrete for structural use," Journal of Cleaner Production, vol. 87, no. 1, pp. 766{776, 2015.H. Dilbas, O. C ak r, and H. Y ld r m, \Experimental investigation on properties of recycled aggregate concrete with optimized Ball Milling Method," Construc- tion and Building Materials, vol. 252, pp. 716{726, 2019.O. C ak r and H. Dilbas, \Durability properties of treated recycled aggregate concrete: E ect of optimized ball mill method," Construction and Building Materials, vol. 268, 2021.S. R. Salimbahrami and R. Shakeri, \Experimental investigation and comparative machine-learning prediction of compressive strength of recycled aggregate concrete," Soft Computing, vol. 256, 2020.J. Feng, G. Yin, H. Tuo, and Z. Niu, \Parameter optimization and regression analysis for multi-index of hybrid ber-reinforced recycled coarse aggregate concrete using orthogonal experimental design," Construction and Building Materials, vol. 267, 2021.R. Kurda, J. de Brito, and J. D. Silvestre, \CONCRETop method: Optimization of concrete with various incorporation ratios of y ash and recycled aggregates in terms of quality performance and life-cycle cost and environmental impacts," Journal of Cleaner Production, vol. 226, pp. 642{657, 2019.V. J. Gan, J. C. Cheng, and I. M. Lo, \Integrating life cycle assessment and multi-objective optimization for economical and environmentally sustainable supply of aggregate," Journal of Cleaner Production, vol. 113, pp. 76{85, 2015.H. Islam, M. Jollands, S. Setunge, and M. A. Bhuiyan, \Optimization approach of balancing life cycle cost and environmental impacts on residential building design," Energy and Buildings, vol. 87, pp. 282{292, 2015.M. Moini, I. Flores-Vivian, A. Amirjanov, and K. Sobolev, \The optimization of aggregate blends for sustainable low cement concrete," Construction and Building Materials, vol. 93, pp. 627{634, 2015.R. Yu, Q. Song, X. Wang, Z. Zhang, Z. Shui, and H. J. Brouwers, \Sustainable development of Ultra-High Performance Fibre Reinforced Concrete (UHPFRC): Towards to an optimized concrete matrix and e cient bre application," Jour- nal of Cleaner Production, vol. 162, pp. 220{233, 2017.M. Kripka, G. F. Medeiros, and A. C. Lemonge, \Use of optimization for automatic grouping of beam cross-section dimensions in reinforced concrete building structures," Engineering Structures, vol. 99, pp. 311{318, 2015.C. Zheng and M. Lu, \Optimized Reinforcement Detailing Design for Sustainable Construction: Slab Case Study," Procedia Engineering, vol. 145, pp. 1478{ 1485, 2016.L. H. Xu, X. T. Yan, and Z. X. Li, \Development of BP-based seismic behavior optimization of RC and steel frame structures," Engineering Structures, vol. 164, no. October 2017, pp. 214{229, 2018.J. Ferreiro-Cabello, E. Fraile-Garcia, E. Martinez de Pison Ascacibar, and F. J. Martinez de Pison Ascacibar, \Metamodel-based design optimization of structural one-way slabs based on deep learning neural networks to reduce environmental impact," Engineering Structures, vol. 155, no. November 2017, pp. 91{ 101, 2018.T. Garc a-Segura and V. Yepes, \Multiobjective optimization of post-tensioned concrete box-girder road bridges considering cost, CO2 emissions, and safety," Engineering Structures, vol. 125, pp. 325{336, 2016.T. Garc a-Segura, V. Penad es-Pl a, and V. Yepes, \Sustainable bridge design by metamodel-assisted multi-objective optimization and decision-making under uncertainty," Journal of Cleaner Production, vol. 202, pp. 904{915, 2018.A. R. Shooli, A. R. Vosoughi, and M. R. Banan, \A mixed GA-PSO-based approach for performance-based design optimization of 2D reinforced concrete special moment-resisting frames," vol. 85, 2019.Ministerio Ambiente Vivienda y Desarrollo Territorial, \Titulo A - Requisitos Generales de Dise~no y Construcci on Sismo Resistente," Nsr-10, vol. Titulo A, pp. 1{174, 2010.Derechos Reservados - Universidad Católica de Colombia, 2021info:eu-repo/semantics/openAccessAtribución-NoComercial-SinDerivadas 4.0 Internacional (CC BY-NC-ND 4.0)http://purl.org/coar/access_right/c_abf2CONCRETO MODIFICADOPÓRTICOSALGORITMO DE EVOLUCIÓN DIFERENCIALPOTENCIAL DE CALENTAMIENTO GLOBALCENIZAS VOLANTESAGREGADOS RECICLADOSOptimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momentoTrabajo de grado - Pregradohttp://purl.org/coar/resource_type/c_7a1fTextinfo:eu-repo/semantics/bachelorThesishttp://purl.org/coar/version/c_fa2ee174bc00049fhttp://purl.org/coar/version/c_71e4c1898caa6e32PublicationORIGINALTG_DE_KEINER LUCERO_LUISAMONROY.pdfTG_DE_KEINER LUCERO_LUISAMONROY.pdfTesisapplication/pdf1888445https://repository.ucatolica.edu.co/bitstreams/aa571b3a-b541-4ef6-968d-919fa6351702/downloadc23bcdbac471fa7c6fc028eff52ca5ccMD51RAE Optimización del potencial del calentamiento global generado por el concreto.pdfRAE Optimización del potencial del calentamiento global generado por el concreto.pdfRAEapplication/pdf312692https://repository.ucatolica.edu.co/bitstreams/8c3587c9-c019-49fc-b0f3-33d2d33a0f1d/download53834a808677a1a5810b08aca216bddcMD52TEXTTG_DE_KEINER LUCERO_LUISAMONROY.pdf.txtTG_DE_KEINER LUCERO_LUISAMONROY.pdf.txtExtracted texttext/plain150455https://repository.ucatolica.edu.co/bitstreams/99f65512-7843-4b2e-818d-cb3fe5c21377/downloada8d4015625eecad8f3a3918b11e0b24fMD53RAE Optimización del potencial del calentamiento global generado por el concreto.pdf.txtRAE Optimización del potencial del calentamiento global generado por el concreto.pdf.txtExtracted texttext/plain17884https://repository.ucatolica.edu.co/bitstreams/6481d7d0-404f-4cef-b9eb-7af52c626027/downloadcf1b3b6c4ab26c81c6a9784d89c4d88cMD55THUMBNAILTG_DE_KEINER LUCERO_LUISAMONROY.pdf.jpgTG_DE_KEINER LUCERO_LUISAMONROY.pdf.jpgRIUCACimage/jpeg7816https://repository.ucatolica.edu.co/bitstreams/b2557353-d7ca-4ef1-99ce-cc5f8083524d/downloadaa40c0ce3696f2bc912889c5f156b938MD54RAE Optimización del potencial del calentamiento global generado por el concreto.pdf.jpgRAE Optimización del potencial del calentamiento global generado por el concreto.pdf.jpgRIUCACimage/jpeg17891https://repository.ucatolica.edu.co/bitstreams/fb5552ea-59b7-4790-959a-7143f2dc6e34/downloade1709bef316a38e30a8221a5d95b762aMD5610983/26619oai:repository.ucatolica.edu.co:10983/266192023-03-24 17:29:32.6https://repository.ucatolica.edu.coRepositorio Institucional Universidad Católica de Colombia - RIUCaCbdigital@metabiblioteca.com

Optimización del potencial de calentamiento global generado por el concreto en pórticos resistentes a momento

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