Beneficio de los finos de coque

66 páginas incluye diagramas.

Autores:: Mora Camacho, Fernando

Tipo de recurso:

Fecha de publicación:: 2015

Institución:: Universidad de la Sabana

Repositorio:: Repositorio Universidad de la Sabana

Idioma:: spa

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dc.title.es_CO.fl_str_mv	Beneficio de los finos de coque
title	Beneficio de los finos de coque
spellingShingle	Beneficio de los finos de coque Carbón -- Análisis -- Colombia Combustibles fósiles -- Colombia Ensayes
title_short	Beneficio de los finos de coque
title_full	Beneficio de los finos de coque
title_fullStr	Beneficio de los finos de coque
title_full_unstemmed	Beneficio de los finos de coque
title_sort	Beneficio de los finos de coque
dc.creator.fl_str_mv	Mora Camacho, Fernando
dc.contributor.advisor.none.fl_str_mv	Rincón Almanza, Jaime Alberto
dc.contributor.author.none.fl_str_mv	Mora Camacho, Fernando
dc.subject.none.fl_str_mv	Carbón -- Análisis -- Colombia Combustibles fósiles -- Colombia Ensayes
topic	Carbón -- Análisis -- Colombia Combustibles fósiles -- Colombia Ensayes
description	66 páginas incluye diagramas.
publishDate	2015
dc.date.accessioned.none.fl_str_mv	2015-11-30T18:44:06Z
dc.date.available.none.fl_str_mv	2015-11-30T18:44:06Z
dc.date.created.none.fl_str_mv	2015
dc.date.issued.none.fl_str_mv	2015-11-30
dc.type.none.fl_str_mv	bachelorThesis
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dc.type.local.none.fl_str_mv	Tesis de especialización
dc.type.hasVersion.none.fl_str_mv	publishedVersion
dc.identifier.citation.none.fl_str_mv	Alvarez, R. (2005). La tecnología de producción de coque de horno alto ante el nuevo milenio. Revista de metalurgia, 29-34. Belkin, A. (2003). Use of iron-coke briquets on a cement binder in blast-furnace smelting. Metallurgist, 147-154. Benk, A. (2008). Phenolic resin binder for the production of metallurgical quality briquettes from coke breeze. Elsevier, 28-37. Benk, A. (2011). Molasses and air blown coal tar pitch binders for the production of metallurgical quality formed coke from anthracite fines or coke breeze. Elsevier, 1078-1086. Benk, A., & Coban, A. (2010). Investigation of resole, novalac and coal tar pitch blended binder for the production of metallurgical quality formed coke briquettes from coke breeze and anthracite. Kayseri, Turkey: Elsevier Cimadevilla, J. (1999). Comparación de la calidad del coque siderúrgico obtenido a diferentes escalas. Revista de Metalurgia, 1-5. Das, A. (2010). Efficient recovery of combustibles from coking coal fines. Mineral Processing & Extractive Metall, 236-249. Diez, M., Alvarez, R., & Cimadevilla, J. (2011). Briquetting of carbon-containing wastes from steelmaking for metallurgical coke production. Oviedo, España: Elsevier. Equihua, L. (22 de 11 de 2011). Que es el valor agregado. Obtenido de http://foroalfa.org/articulos/que-es-el-valor-agregado Groover, M. P. (1997). Fundamentos de manufactura moderna. Mexico: Prentice Hall. Guerrero, C. (2012). Construcción de un modelo de mezcla de carbones colombianos para la producción de coque. Bogotá: Universidad Nacional de Colombia Gupta, A., & D.S., Y. (2006). Mineral Processing Design and Operations an Introduction. Netherlands: Elsevier Gutierrez, M., Mora, W., Rodriguez, L., & Ramirez, J. (2011). Aprovechamiento de partículas de ultrafinos de carbón de una planta lavadora en la producción de coque metalúrgico. Ingeniería e investigación, 65-73. Kulkova, T. (2007). Use of resin-bearing wastes from coke and coal chemicals production at the novokuznetsk metallurgical combine. Metallurgist, 206-2010. Logachov, G. (2012). Evaluating the effectiveness of using coke breeze in blast-furnace smelting. Metallurgist, 15-21. Mahoney, M. (2005). Pilot scale simulation of cokemaking in integrated steelworks. Ironmaking and Steelmaking, 468-478 Maistrenko, A. (2007). Numerical analysis of the process of combustion and gasification of the polydisperse coke residue of high-ash coal under pressure in a fluidized bed. Journal of Engineering Physics and Thermophysics, 1019-1032. Majumder, A., & Shan, H. (2009). Applicability of a dense-medium cyclone and vorsyl separator for upgrading non-coking coal fines for use as a blast furnace injection fuel. International Journal of Coal Preparation and Utilization, 23-33. Mota, O., & Campos, J. (1995). Combustion of coke with high ash content in fluidised beds. Chemical Engineering Science, 433-439 Nersesian, R. L. (2010). Coal and the Industrial Revolution. U.K Nomura, S. (2012). Effect of coke contraction on mean coke size. Elsevier, 176-183. Pinho, C. (2006). Fragmentation on batches of coke or char particles during fluidized bed combustion. Elsevier, 147-155. Pitak, Y. (2010). Study of the properties of ceramic surfacing material used for restoring coking chamber linings. Refractories and industrial ceramics, 114-119. Prachethan, P. (2008). Maximisation of non-coking coals in coke production from non-recovery coke ovens. Ironmaking and Steelmaking, 33-39. Prieto, I. (2010). Centrales termicas sistemas de combustión en lecho fluido. España. Rodriguez, I. B. (2000). Manual de Carbones y Coquización. Tunja: UPTC. Rojas, J. (2013). Productos de valor agregado. Monterrey: Raady 2 eat consulting. Sahu, A. (2009). Development of air dense medium fluidized bed technology for dry beneficiation of coal – a review. International Journal of Coal Preparation and Utilization, 216-241. Sutcu, H. (2006). Effect of hydroxides on carbonization of bituminous coal. Coal Preparation, 201-208. Totten, G. E., Funatani, K., & Xie, L. (2004). Handbook of Metallurgical Process Desing. USA: Marcel Dekker. Umadevi, T. (2008). Influence of coke breeze particle size on quality of sinter. Ironmaking and steelmaking, 567-575. Wang, B. (2012). Experimental investigation of secondary reactions of intermediates in delayed coking. Res Chem Intermed, 2295-2307. Wills, B., & Napier-Munn, T. (2006). Wills Mineral Processing Technology. Elsevier. World Energy Council. (2010). 2010 Survey of Energy Sources. Obtenido de http://www.worldenergy.org/ Yarar, B. (1984). Mineral Processing Design. Turkey: Kluwer Academic Publishers.
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identifier_str_mv	Alvarez, R. (2005). La tecnología de producción de coque de horno alto ante el nuevo milenio. Revista de metalurgia, 29-34. Belkin, A. (2003). Use of iron-coke briquets on a cement binder in blast-furnace smelting. Metallurgist, 147-154. Benk, A. (2008). Phenolic resin binder for the production of metallurgical quality briquettes from coke breeze. Elsevier, 28-37. Benk, A. (2011). Molasses and air blown coal tar pitch binders for the production of metallurgical quality formed coke from anthracite fines or coke breeze. Elsevier, 1078-1086. Benk, A., & Coban, A. (2010). Investigation of resole, novalac and coal tar pitch blended binder for the production of metallurgical quality formed coke briquettes from coke breeze and anthracite. Kayseri, Turkey: Elsevier Cimadevilla, J. (1999). Comparación de la calidad del coque siderúrgico obtenido a diferentes escalas. Revista de Metalurgia, 1-5. Das, A. (2010). Efficient recovery of combustibles from coking coal fines. Mineral Processing & Extractive Metall, 236-249. Diez, M., Alvarez, R., & Cimadevilla, J. (2011). Briquetting of carbon-containing wastes from steelmaking for metallurgical coke production. Oviedo, España: Elsevier. Equihua, L. (22 de 11 de 2011). Que es el valor agregado. Obtenido de http://foroalfa.org/articulos/que-es-el-valor-agregado Groover, M. P. (1997). Fundamentos de manufactura moderna. Mexico: Prentice Hall. Guerrero, C. (2012). Construcción de un modelo de mezcla de carbones colombianos para la producción de coque. Bogotá: Universidad Nacional de Colombia Gupta, A., & D.S., Y. (2006). Mineral Processing Design and Operations an Introduction. Netherlands: Elsevier Gutierrez, M., Mora, W., Rodriguez, L., & Ramirez, J. (2011). Aprovechamiento de partículas de ultrafinos de carbón de una planta lavadora en la producción de coque metalúrgico. Ingeniería e investigación, 65-73. Kulkova, T. (2007). Use of resin-bearing wastes from coke and coal chemicals production at the novokuznetsk metallurgical combine. Metallurgist, 206-2010. Logachov, G. (2012). Evaluating the effectiveness of using coke breeze in blast-furnace smelting. Metallurgist, 15-21. Mahoney, M. (2005). Pilot scale simulation of cokemaking in integrated steelworks. Ironmaking and Steelmaking, 468-478 Maistrenko, A. (2007). Numerical analysis of the process of combustion and gasification of the polydisperse coke residue of high-ash coal under pressure in a fluidized bed. Journal of Engineering Physics and Thermophysics, 1019-1032. Majumder, A., & Shan, H. (2009). Applicability of a dense-medium cyclone and vorsyl separator for upgrading non-coking coal fines for use as a blast furnace injection fuel. International Journal of Coal Preparation and Utilization, 23-33. Mota, O., & Campos, J. (1995). Combustion of coke with high ash content in fluidised beds. Chemical Engineering Science, 433-439 Nersesian, R. L. (2010). Coal and the Industrial Revolution. U.K Nomura, S. (2012). Effect of coke contraction on mean coke size. Elsevier, 176-183. Pinho, C. (2006). Fragmentation on batches of coke or char particles during fluidized bed combustion. Elsevier, 147-155. Pitak, Y. (2010). Study of the properties of ceramic surfacing material used for restoring coking chamber linings. Refractories and industrial ceramics, 114-119. Prachethan, P. (2008). Maximisation of non-coking coals in coke production from non-recovery coke ovens. Ironmaking and Steelmaking, 33-39. Prieto, I. (2010). Centrales termicas sistemas de combustión en lecho fluido. España. Rodriguez, I. B. (2000). Manual de Carbones y Coquización. Tunja: UPTC. Rojas, J. (2013). Productos de valor agregado. Monterrey: Raady 2 eat consulting. Sahu, A. (2009). Development of air dense medium fluidized bed technology for dry beneficiation of coal – a review. International Journal of Coal Preparation and Utilization, 216-241. Sutcu, H. (2006). Effect of hydroxides on carbonization of bituminous coal. Coal Preparation, 201-208. Totten, G. E., Funatani, K., & Xie, L. (2004). Handbook of Metallurgical Process Desing. USA: Marcel Dekker. Umadevi, T. (2008). Influence of coke breeze particle size on quality of sinter. Ironmaking and steelmaking, 567-575. Wang, B. (2012). Experimental investigation of secondary reactions of intermediates in delayed coking. Res Chem Intermed, 2295-2307. Wills, B., & Napier-Munn, T. (2006). Wills Mineral Processing Technology. Elsevier. World Energy Council. (2010). 2010 Survey of Energy Sources. Obtenido de http://www.worldenergy.org/ Yarar, B. (1984). Mineral Processing Design. Turkey: Kluwer Academic Publishers. 176733 TE07969
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spelling	Rincón Almanza, Jaime AlbertoMora Camacho, FernandoEspecialista en Gerencia de Producción y Operaciones2015-11-30T18:44:06Z2015-11-30T18:44:06Z20152015-11-30Alvarez, R. (2005). La tecnología de producción de coque de horno alto ante el nuevo milenio. Revista de metalurgia, 29-34.Belkin, A. (2003). Use of iron-coke briquets on a cement binder in blast-furnace smelting. Metallurgist, 147-154.Benk, A. (2008). Phenolic resin binder for the production of metallurgical quality briquettes from coke breeze. Elsevier, 28-37.Benk, A. (2011). Molasses and air blown coal tar pitch binders for the production of metallurgical quality formed coke from anthracite fines or coke breeze. Elsevier, 1078-1086.Benk, A., & Coban, A. (2010). Investigation of resole, novalac and coal tar pitch blended binder for the production of metallurgical quality formed coke briquettes from coke breeze and anthracite. Kayseri, Turkey: ElsevierCimadevilla, J. (1999). Comparación de la calidad del coque siderúrgico obtenido a diferentes escalas. Revista de Metalurgia, 1-5.Das, A. (2010). Efficient recovery of combustibles from coking coal fines. Mineral Processing & Extractive Metall, 236-249.Diez, M., Alvarez, R., & Cimadevilla, J. (2011). Briquetting of carbon-containing wastes from steelmaking for metallurgical coke production. Oviedo, España: Elsevier.Equihua, L. (22 de 11 de 2011). Que es el valor agregado. Obtenido de http://foroalfa.org/articulos/que-es-el-valor-agregadoGroover, M. P. (1997). Fundamentos de manufactura moderna. Mexico: Prentice Hall.Guerrero, C. (2012). Construcción de un modelo de mezcla de carbones colombianos para la producción de coque. Bogotá: Universidad Nacional de ColombiaGupta, A., & D.S., Y. (2006). Mineral Processing Design and Operations an Introduction. Netherlands: ElsevierGutierrez, M., Mora, W., Rodriguez, L., & Ramirez, J. (2011). Aprovechamiento de partículas de ultrafinos de carbón de una planta lavadora en la producción de coque metalúrgico. Ingeniería e investigación, 65-73.Kulkova, T. (2007). Use of resin-bearing wastes from coke and coal chemicals production at the novokuznetsk metallurgical combine. Metallurgist, 206-2010.Logachov, G. (2012). Evaluating the effectiveness of using coke breeze in blast-furnace smelting. Metallurgist, 15-21.Mahoney, M. (2005). Pilot scale simulation of cokemaking in integrated steelworks. Ironmaking and Steelmaking, 468-478Maistrenko, A. (2007). Numerical analysis of the process of combustion and gasification of the polydisperse coke residue of high-ash coal under pressure in a fluidized bed. Journal of Engineering Physics and Thermophysics, 1019-1032.Majumder, A., & Shan, H. (2009). Applicability of a dense-medium cyclone and vorsyl separator for upgrading non-coking coal fines for use as a blast furnace injection fuel. International Journal of Coal Preparation and Utilization, 23-33.Mota, O., & Campos, J. (1995). Combustion of coke with high ash content in fluidised beds. Chemical Engineering Science, 433-439Nersesian, R. L. (2010). Coal and the Industrial Revolution. U.KNomura, S. (2012). Effect of coke contraction on mean coke size. Elsevier, 176-183.Pinho, C. (2006). Fragmentation on batches of coke or char particles during fluidized bed combustion. Elsevier, 147-155.Pitak, Y. (2010). Study of the properties of ceramic surfacing material used for restoring coking chamber linings. Refractories and industrial ceramics, 114-119.Prachethan, P. (2008). Maximisation of non-coking coals in coke production from non-recovery coke ovens. Ironmaking and Steelmaking, 33-39.Prieto, I. (2010). Centrales termicas sistemas de combustión en lecho fluido. España.Rodriguez, I. B. (2000). Manual de Carbones y Coquización. Tunja: UPTC.Rojas, J. (2013). Productos de valor agregado. Monterrey: Raady 2 eat consulting.Sahu, A. (2009). Development of air dense medium fluidized bed technology for dry beneficiation of coal – a review. International Journal of Coal Preparation and Utilization, 216-241.Sutcu, H. (2006). Effect of hydroxides on carbonization of bituminous coal. Coal Preparation, 201-208.Totten, G. E., Funatani, K., & Xie, L. (2004). Handbook of Metallurgical Process Desing. USA: Marcel Dekker.Umadevi, T. (2008). Influence of coke breeze particle size on quality of sinter. Ironmaking and steelmaking, 567-575.Wang, B. (2012). Experimental investigation of secondary reactions of intermediates in delayed coking. Res Chem Intermed, 2295-2307.Wills, B., & Napier-Munn, T. (2006). Wills Mineral Processing Technology. Elsevier.World Energy Council. (2010). 2010 Survey of Energy Sources. Obtenido de http://www.worldenergy.org/Yarar, B. (1984). Mineral Processing Design. Turkey: Kluwer Academic Publishers.http://hdl.handle.net/10818/20477176733TE0796966 páginas incluye diagramas.En este trabajo de investigación se plantea una alternativa de comercialización para los finos de coque, subproducto del proceso de coquización, por medio del diseño de un proceso productivo que permita dar un valor agregado a este producto. A partir del marco teórico se definieron 4 alternativas técnicamente viables para el beneficio de los finos de coque, en las cuales se hace énfasis y se desarrollan, planteando ventajas y desventajas de cada una de ellas. Al final se plantean las hipótesis de la investigación con la alternativa técnica y económicamente más viable para la empresa. Par el desarrollo de la investigación se usaran las herramientas de diseño de productos y procesos así como un planteamiento de las variables a controlar en el proceso diseñado a partir del control estadístico, teniendo siempre presente los parámetros de control de calidad del coque aceptados ampliamente en la industrial a nivel mundial.spaUniversidad de La SabanaEspecialización en Gerencia de Producción y OperacionesEscuela de Ciencias Económicas y AdministrativasUniversidad de La SabanaIntellectum Repositorio Universidad de La SabanaCarbón -- Análisis -- ColombiaCombustibles fósiles -- ColombiaEnsayesBeneficio de los finos de coquebachelorThesisTesis de especializaciónpublishedVersionhttp://purl.org/coar/version/c_970fb48d4fbd8a85http://purl.org/coar/resource_type/c_7a1fhttp://purl.org/coar/access_right/c_abf2ORIGINALFernando Mora Camacho (tesis).pdfFernando Mora Camacho (tesis).pdfVer documento en PDFapplication/pdf1239328https://intellectum.unisabana.edu.co/bitstream/10818/20477/1/Fernando%20Mora%20Camacho%20%28tesis%29.pdfb113dbb75ceeced574794736a86de8d4MD51Fernando Mora Camacho (rai).pdfFernando Mora Camacho (rai).pdfVer Resumenapplication/pdf112715https://intellectum.unisabana.edu.co/bitstream/10818/20477/2/Fernando%20Mora%20Camacho%20%28rai%29.pdfd1b50b04e0946cb81561751581672b30MD52LICENSElicense.txtlicense.txttext/plain; charset=utf-8498https://intellectum.unisabana.edu.co/bitstream/10818/20477/3/license.txtf52a2cfd4df262e08e9b300d62c85cabMD53Fernando Mora Camacho (Carta).pdfFernando Mora Camacho (Carta).pdfapplication/pdf23548https://intellectum.unisabana.edu.co/bitstream/10818/20477/6/Fernando%20Mora%20Camacho%20%28Carta%29.pdf29402402cb57908af60627bcd0fe080dMD56TEXTFernando Mora Camacho (tesis).pdf.txtFernando Mora Camacho (tesis).pdf.txtExtracted Texttext/plain98677https://intellectum.unisabana.edu.co/bitstream/10818/20477/4/Fernando%20Mora%20Camacho%20%28tesis%29.pdf.txtcbf5df04b4dfa31d65e04fbf53ab3f04MD54Fernando Mora Camacho (rai).pdf.txtFernando Mora Camacho (rai).pdf.txtExtracted Texttext/plain11144https://intellectum.unisabana.edu.co/bitstream/10818/20477/5/Fernando%20Mora%20Camacho%20%28rai%29.pdf.txt0fe993e52b1a92d8136c33ccddaac106MD5510818/20477oai:intellectum.unisabana.edu.co:10818/204772019-08-11 10:05:48.713Intellectum Universidad de la Sabanacontactointellectum@unisabana.edu.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

Beneficio de los finos de coque

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