Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas

El uso indiscriminado de combustibles fósiles ha sido hasta el punto de agotar las reservas de combustibles que son limitadas, lo que ha llevado a la búsqueda de nuevas alternativas. Se ha demostrado en varios estudios que con el uso de reactores anaerobios se facilita el proceso de digestión anaero...

Full description

Autores:: García García, Ana Carolina
Baquero Muñoz, Alejandra Catalina

Tipo de recurso:

Fecha de publicación:: 2017

Institución:: Universidad Militar Nueva Granada

Repositorio:: Repositorio UMNG

Idioma:: spa

id	UNIMILTAR2_f3b5319ef43315bd769b9950426778f3
oai_identifier_str	oai:repository.unimilitar.edu.co:10654/16053
network_acronym_str	UNIMILTAR2
network_name_str	Repositorio UMNG
repository_id_str
dc.title.spa.fl_str_mv	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
dc.title.translated.spa.fl_str_mv	Effect of different support media on the production of hydrogen from the industrial non-alcoholic wastewater treatment
title	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
spellingShingle	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas BIOGAS HIDROGENO TRATAMIENTO DEL AGUA AGUAS RESIDUALES Biogas Hydrogen production Activated carbon Ground rim Anaerobic reactor ANOVA Conversion of glucose Biogás Producción de hidrógeno Carbón activado Llanta triturada Digestión anaerobia Glucosa Reactor anaerobio ANOVA Conversión de glucosa
title_short	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
title_full	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
title_fullStr	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
title_full_unstemmed	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
title_sort	Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas
dc.creator.fl_str_mv	García García, Ana Carolina Baquero Muñoz, Alejandra Catalina
dc.contributor.advisor.spa.fl_str_mv	Rodríguez Chaparro, Adela Tatiana
dc.contributor.author.spa.fl_str_mv	García García, Ana Carolina Baquero Muñoz, Alejandra Catalina
dc.subject.lemb.spa.fl_str_mv	BIOGAS HIDROGENO TRATAMIENTO DEL AGUA AGUAS RESIDUALES
topic	BIOGAS HIDROGENO TRATAMIENTO DEL AGUA AGUAS RESIDUALES Biogas Hydrogen production Activated carbon Ground rim Anaerobic reactor ANOVA Conversion of glucose Biogás Producción de hidrógeno Carbón activado Llanta triturada Digestión anaerobia Glucosa Reactor anaerobio ANOVA Conversión de glucosa
dc.subject.keywords.spa.fl_str_mv	Biogas Hydrogen production Activated carbon Ground rim Anaerobic reactor ANOVA Conversion of glucose
dc.subject.proposal.spa.fl_str_mv	Biogás Producción de hidrógeno Carbón activado Llanta triturada Digestión anaerobia Glucosa Reactor anaerobio ANOVA Conversión de glucosa
description	El uso indiscriminado de combustibles fósiles ha sido hasta el punto de agotar las reservas de combustibles que son limitadas, lo que ha llevado a la búsqueda de nuevas alternativas. Se ha demostrado en varios estudios que con el uso de reactores anaerobios se facilita el proceso de digestión anaerobia, y con la intervención de grupos de bacterias que se desarrollan, ayudan a la producción de hidrógeno en un alto rendimiento.
publishDate	2017
dc.date.accessioned.none.fl_str_mv	2017-06-27T19:34:09Z 2019-12-26T22:03:04Z
dc.date.available.none.fl_str_mv	2017-06-27T19:34:09Z 2019-12-26T22:03:04Z
dc.date.issued.none.fl_str_mv	2017-02-28
dc.type.spa.fl_str_mv	info:eu-repo/semantics/bachelorThesis
dc.type.coar.fl_str_mv	http://purl.org/coar/resource_type/c_7a1f
dc.type.local.spa.fl_str_mv	Trabajo de grado
dc.identifier.uri.none.fl_str_mv	http://hdl.handle.net/10654/16053
url	http://hdl.handle.net/10654/16053
dc.language.iso.spa.fl_str_mv	spa
language	spa
dc.relation.references.spa.fl_str_mv	Acosta, L.Y., Obaya, A. y Ma, Cristina. (2005).La digestión anaerobia. Aspectos teóricos. Parte I.ICIDCA. Sobre los derivados de la caña de azúcar, Vol XXXIX, num.1, 35-48 Alzate ,L.M.G.,P,L. Sebastian., Pérez ,A.H. y Eapen, D.(2007).Comparison of two anaerobic systems for hydrogen production from the organic fraction of municipal solid waste and synthetic wastewater. International Hydrogen Energy 32, 3141-3146. ANDESAPA.(1994).Aguas residuales del procesamiento de aguas minerales y de la industria de refrescos y jugos de frutas. Comité coordinador regional de instituciones de Agua potable y saneamiento de Centroamérica, Panamá y Republica Dominicana. Avilés,M.H. y Chaparro,T.R.(2016).Efecto de la configuración de reactores anaerobios de alta tasa en la producción de hidrógeno: biomasa fija y UASB-híbrido.Rev.ion 29,27-36. Azbar, N., C¸ etinkaya Dokgo¨z, FT., Keskin, T., Korkmaz, KS., Syed HM.(2009).Continuous fermentative hydrogen production from cheese whey wastewater under thermophilic anaerobic conditions. International Journal of Hydrogen Energy 34(17):7441–7447 Barca,C.,Ranava,D.,Bauzan,M.,Ferrasse,J-H.,Giudici,M. y Soric,A.(2016).Fermentative hydrogen production in an up –flow biofilm reactor inoculated with a co –culture of Clostridium acetobutylicum and Desulfovibrio vulgaris. Bioresource Technology 221,526– 533. Barros, R.A.,Silva,E.L.(2012).Hydrogen and etanol production in anaerobic fluidized bed rectors:performance evaluation for three support materials under different operating condictions.Biochemical Engineering Journal 61,59-65. Bakonyi, P., Kumar, G., Nemesto´thy, N., Lin, CY, and Be´lafi-Bako´, K. (2013).Biohydrogen purification using a commercial polyimide membrane module: studying the effects of some process variables. Hydrogen Energy 38:15092–15099. Bakonyi, P., Nemesto´thy, N., Lanko´, J., Rivera, I., Buitro´n, G., Be´lafi- Bako´, K. (2015) Simultaneous biohydrogen production and purification in a double-membrane bioreactor system. International Journal of Hydrogen Energy 40:1690–1697. Bedoya, A., Castrillón, J.C., Ramírez .J.E., Vásquez, J.E. y Zabalara, M.A. (2007).Producción biológica de hidrógeno: una aproximación al estado del arte universidad nacional de Colombia. Bisaillon,A., Turcot,J. y Hallenbeck,P.C.(2006). The effect of nutrient limitation on hydrogen production by batch cultures of Escherichia coli. Int J Hydrogen Energy 31(11) , 1504–1508. Boileau,C., Richard ,A., Sylvain, D., Laurence, C., Pierre,C., Pierre‑Pol,L. y Combet‑Blanc,Y. (2016).Hydrogen production by the hyperthermophilic bacterium Thermotoga maritima part I: effects of sulfured nutriments, with thiosulfate as model, on hydrogen production and growth.Biotechnol Biofuels9,269. Carminato,V.M. (2013). Influência do cálcio na produção biológica de hidrogênio a partir de águas residuárias em biorreatores anaeróbios. Escola de Engenharia de São Carlos, da Universidade de São Paulo Cavalcante de A,E.L.,Barros,A.R.,Zamariolli,M.H.R.y Silva,E.L.(2009).Anaerobic fluidized bed reactor with expanded clay as support for hydrogen production through dark fermentation of glucose .International Journal of Hydrogen Energy 34,783-790. Cavalcante de A,E.L.,Sader,L.T. y Silva.E,L.(2011). Effect of Substrate Concentration on Dark Fermentation Hydrogen Production Using an Anaerobic Fluidized Bed Reactor.Biochem Biotechnol 166, 1248-1263. Cavinato, C., Giuliano, A., Bolzonella, D., Pavan, P., Cecchi, F. (2012).Bio-hythane production from food waste by dark fermentation coupled with anaerobic digestion process: a longterm pilot scale experience. International Journal of Hydrogen Energy 37:11549– 11555. Cheng, SS., Chao, YC., Yang, KH., Bai, MD. (2011).Process recovery of biohydrogenation in a pilot plant from methanogens invasion. International Journal of Hydrogen Energy 36:8779– 8784. Chin,H.L.,Chen,Z.S. y Chou,C.P.(2003).Fedbatch operation using Clostridium acetobutylicum suspension culture as biocatalyst for enhancing hydrogen production. Biotechnol Prog. 19(2) ,383–8. Chong, ML., Abdul, Rahman, NA., Rahim, RA., Aziz, SA., Shirai, Y.,Hassan, MA. (2009a) Optimization of biohydrogen production by Clostridium butyricum EB6 from palm oil mil effluent using response surface methodology. International Journal of Hydrogen Energy 34(17):7475–7482 Chunfeng, C.,Yoshitaka,E.,Yuhei,I. y Hainan,K.(2009) .Effect of hydraulic retention time on the hydrogen yield and population of Clostridium in hydrogen fermentation of glucose. Journal of Environmental Sciences 21,424–428. Classen,P. y Vrije,G.J.(2007).Hydrogen from biomass.Agrotecnologt and food sciences Group,member of Wagening .Biohydrogen Corrales, L.C., Romero,D.M.A.,Macias,J.A.B,y Vargas,A.M.C.(2015).Bacterias anaerobias: procesos que realizan y contribuyen a la sostenibilidad de la vida en el planeta . Nova.vol.13, N.24, 55-81. Dutta S. (2014) .A review on production, storage of hydrogen and its utilization as an energy resource. Journal of Industrial and Engineering Chemistry 20:1148–1156. Díaz, I. I. (2004). Utilización de biogás para la generación de biogás. Costa Rica: Ambientice. Fang,H.H.P. y Liu,H. (2002). Effect of pH on hydrogen production fromglucose by a mixed culture. Bioresource Technology 82, 87–93. El Heraldo. (2015).Las bebidas no alcohólicas mueven $3.5 billones al año. Recuperado de: http://www.elheraldo.co/economia/las-bebidas-no-alcoholicas-mueven-35-billones-al-ano- 225111. Ferchichi, M., Crabbe, E., Gil, GH., Hintz, W., Almadidy, A. (2005).Influence of initial pH on hydrogen production from cheese whey. Journal Biotechnologie 120(4):402–409. Fernandez,B.S. (2008).Producao de hidrogenio em reator anaeróbio de leito fixo (Tese de Doutor).Universidade de Sao Paulo,Sao Carlos,Brasil. Fernandes,B.S.,Saavedra,N.K.,Maintinguer,S.I.,Sette,L.D.,Oliveira,V.M.,Varesche,M.B.A. y Zait,M.(2013).The effect of biomass immobilization support material and bed porosity on hydrogen production in an upflow anaerobic packed-be bioreactor. Biochem Biotechnol 170, 1348-1366. Fernandes, BS., Peixoto, G., Albrecht, FR., Saavedra del Aguila, NK., ZaiatM.(2010).Potential to produce biohydrogen from various wastewaters. Energy for Sustainable Development 14(2):143–148. Ferreira,P.R.R.,Santos,S.C.y Silva,E.L.(2014).Different ratios of carbon sources in the fermentation of cheese whey and glucose as substrates for hydrogen and ethanol production in continuous reactors. International Journal of Hydrogen Energy 39, 1288-1296. Fontes Lima,D.M., Moreira,W.K.,Zaiat,M.(2013).Comparison of the use of sucrose and glucose as substrate for hydrogen production in an upflow anaerobic fixed – bed reactor. International Journal of Hydrogen Energy 38, 15074-15083. Hafez,H.,Baghchehsaraee,B.,Nakhla,G.,Karamanev,D.,Maragaritis,A.,Naggar,H.(2009). Comparative assessment of decoupling of biomass and hydraulic retention time in hydrogen production bioreactors. International Journal of Hydrogen Energy 34, 7603-7611. Hsiao, CL., Chang, JJ., Wu, JH., Chin, WC., Wen, FS., Huang, CC., Lin, CY. (2009).Clostridium strain co-cultures for biohydrogen production enhancement from condensed molasses fermentation solubles. International Journal of Hydrogen Energy 34(17):7173– 7181. Hu,B. y Chen,S.(2007).Pretreatment of methanogenic granules for immobilized hydrogen fermentation. International Journal Hydrogen Energy 32, 3266-73. Hung,C-H.,Lee,K-S.,Cheng,L-S.,Huang.Y-H.,Lin,P-J. y Chang,J-S. (2007).Quantitative analysis of a high-rate hydrogen –producing microbial community in anaerobic agitated granular sludge bed bioreactors using glucose as substrate. Microbiol Biotechnol 75,693– 701. Ishikawa,M., Yamamura ,S., Takamura,Y., Sode,K., Tamiya, E. y Tomiyama,M. (2006).Development of a compact high-density microbial hydrogen reactor for portable biofuel cell system.International Journal of hydrogen energy 31,1484-1489 Islam,R.,Cicek,N., Sparling,R. y Levin,D.(2006). Effect of substrate loading on hydrogen production during anaerobic fermentation by Clostridium thermocellum 27405.Microbiol Biotechnol 72(3), 576-583. Jayalakshmi, S., Joseph, K., Sukumaran, V. (2009).Biohydrogen generation from kitchen waste in an inclined plug flow reactor. International Journal of Hydrogen Energy 34, 8854– 8858. Jo,J.H., Lee,D.S., Park,D., Choe,W-S. Y Park, J.M. (2008). Optimization of key process variables for enhanced hydrogen production by Enterobacter aerogenes using statistical methods. Bioresource Technology 99, 2061–2066. Jung, KW., Kim, DH., Shin, HS. (2010).Continuous fermentative hydrogen production from coffee drink manufacturing wastewater by applying UASB reactor. International Journal of Hydrogen Energy 35(24), 13370–13378. Khanal,S.K.,Chen,W-H.,Li,L. y Sung,S.(2004).Biological hydrogen production: effects of pH and intermediate products. International Journal of hydrogen Energy 29, 1123-1121. Kim, DH., Kim, SH., Kim,KY., Shin, HS. (2010).Experience of pilot-scale hydrogenproducing anaerobic sequencing batch reactor (ASBR) treating food waste. International Journal of Hydrogen Energy 35:1590–1594. Kumar,N. y Das,D. (2001).Continuous hydrogen production by immobilized Enterobacter cloacae IIT-BT 08 using lignocellulosic materials as solid matrices. Enzyme and Microbial Technology 29,280–287. La nota económica. (2010).Pequeños sectores, gaseosas y jugos .Recuperado de: http://www.lanotadigital.com/vademecum/small/bebidas-y-tabaco/gaseosas-y-jugos. Lee, D.Y.,Li,Y.Y. y Noike,T.(2009).Continuous H2 production by anaerobic mixed microflora in membrane bioreactor. Bioresource Technology 100,690-695. Lee,K-S.,Wu,J-F.,Lo,Y-C.,Lin,P-J.,Chang,J-S.(2004).Anaerobic hydrogen production with an efficient carrier-inducedzhan sludge bed biorreactor. Biotechnology Bioteng 87,648-657. Lee,N.,Nielsen,P.H,Aspegren,H.,Henze,M.,Scleifer,K.H. y Jansen,J.(2003).Long-term population Dynamics and in situ Physiology in activated sludge systems with Enhanced biological Phosphorus Removal Operated with and without Nitrogen Removal. Systematic and Applied Microbioly 26,211–227. Lee, YW., Chung, J. (2010).Bioproduction of hydrogen from food waste by pilot-scale combined hydrogen/methane fermentation. International Journal of Hydrogen Energy 35:11746–11755 Leite,J.A.C.,Fernandes,B.S.,Pozzi,E.,Barbosza,M. y Zait,M.(2008).Application of an anaerobic packed-bed biorreactor for the production of hydrogen and organic acids. International Journal Hydrogen Energy 33,579-86. Lin,C-Y. y Chang,R-C.(2004).Fermentative hydrogen production at ambient temperature. International Journal Hydrogen Energy 29,715-20. Lin, CY., Wu, SY., Lin, PJ., Chang, JS., Hung, CH., Lee, KS., Lay, CH., Chu, CY., Cheng, CH., Chang, AC., Wu, JH., Chang, FY., Yang, LH., Lee, CW., Lin, YC. (2011) A pilot-scale high-rate biohydrogen production system with mixed microflora. International Journal of Hydrogen Energy 36:8758–8764. Mangayil, R., Karp, M., Santala, V. (2012).Bioconversion of crude glycerol from biodiesel production to hydrogen. International Journal of Hydrogen Energy 37(17):12198–12204. Moraes,B.S.,Zaiat,M., Bonomi ,A.(2015).Anaerobic digestion of vinasse from sugarcane etanol production in Brazil:Challenges and perspectives.Renewable and Sustainable Energy Reviews 44,888-903. Moreno, M.T.V. (2011).Manual de Biogás. MINENERGIA/PNUD/FAO/GEF. Santiago de Chile. Mu,Y., Zheng,X-J., Yu, H-Q. y Zhu, R-F.(2006). Biological hydrogen production by anaerobic sludge at various temperatures. International Journal of hydrogen energy31, 780– 785. Masset,J., Calusinska,M., Hamilton,C., Hiligsmann,S., Joris,B.,Wilmotte,A y Thonart,P.(2012).Fermentative hydrogen production from glucose and starch using pure strains and artificial co-cultures of Clostridium spp. Biotechnology for biofuel 5,35 Ngo, TA., Kim, MS., Sim, SJ. (2011).High-yield biohydrogen production from biodiesel manufacturing waste by Thermotoga neapolitana. International Journal of Hydrogen Energy 36(10):5836–5842. Nishio,N. y Nakashimada,Y.(2004). High Rate Production of hydrogen/methane from various substrates and wastes .Biochem Engin/Biotechnol 90, 63-87. Ntaikou ,I., Gavala,H.N., Kornaros,M. y Lyberatos, G.(2008). Hydrogen production from sugars and sweet sorghum biomass using Ruminococcus albus. International Journal of hydrogen energy 33, 1153–63 Nuñez,G.C.V.(2013).Panorama del tratamiento de aguas residuales con tecnología anaerobia en la Costa Atlántica Colombiana (Tesis de maestría).Universidad Nacional de Colombia. Bogota, Colombia. Ogino,H.,Miura,T.,Ishimi,K.,Selki,M. y Yoshida,H.(2005).Hydrogen production from glucose by anaerobes. Biotechnol Prog 21, 1786-1788. Oh,S-E.,Ginkel,S.V. y Logan,B.E.(2003).The relative effectiveness of pH control and heat treatment for enhancing biohydrogen gas production .Environmental science & technology 37 (22),5186-5190. Oh,Y.K.,Kim,H-J.,Park,S.,Kim,M-S. y Ryu,D.D.Y.(2008).Metabolic-flux analysis of hydrogen production pathway in Citrobacter amalonaticus Y19. International Journal of Hydrogen Energy 33, 1471–1482. Otero,J., Sanches,A. y Moral,E.(2005).Análisis de la varianza (ANOVA). O-Thong, S., Prasertsan, P., Intrasungkha, N., Dhamwichukorn, S., Birkeland, NK. (2007). Improvement of biohydrogen production and treatment efficiency on palm oil mill effluent with nutrient supplementation at thermophilic condition using an anaerobic sequencing batch reactor. Enzyme Microbial Technology 41(5):583–590. Pan,C.M.,Fan,Y.T., Xing,Y., Hou, H.W. y Zhang,M.L.(2008). Statistical optimization of process parameters on biohydrogen production from glucose by Clostridium sp. Fanp2. Bioresource Technology 99, 3146–3154. Penagos, D.K.G., López, L.J.O., Londoño,S.A.B., Chaparro, T.R., Ortiz, C.E.M., Revollo, A.A.M.,Ruiz,L.A.H.(2017).Manual para el análisis de aguas residuales y lodos. Universidad Militar Nueva Granada. Bogotá, Colombia Podesta,J.J.,Gutierrez-Navarro,A.M.,Estrella,C.N. y Esteso,M.A.(1997).Electrochemical measurement of trace concentrations of biological hydrogen produced by Enterobacteriaceae. Res. Microbiol 148, 87-93. Reis,C.M,Silva,E.L.(2011).Effect of upflow velocity and hydraulic retention time in anaerobic fluidized-bed reactors used for hydrogen production. Chemical Engineering Journal 172, 28-36. Reis,C.M,Silva,E.L.(2014).Simultaneous Coproduction of Hydrogen and Ethanol in Anaerobic Packed –Bed Reactors .BioMed Research International. Article ID 921291. Ren, N., Li, J., Li, B., Wang, Y., Liu, S. (2006).Biohydrogen production from molasses by anaerobic fermentation with a Rev Environ Sci Biotechnol (2015) 14:761–785 783123pilotscale bioreactor system. International Journal of Hydrogen Energy 31:2147–2157. Revollo,A.A.M.,Avilés,D.M.H.,Arevalo,Y.V.T.y Rodriguez,A.T.C.(2014).Influencia del medio de soporte en la producción de biohidrógeno a partir del tratamiento de aguas residuales de la industria cervecera utilizando reactores de biomasa inmovilizada y flujo ascendente. Universidad Militar Nueva Granada. Bogotá. Colombia. Shi, XY., Jin, DW., Sun, QY., Li, WW. (2010).Optimization of conditions for hydrogen production from brewery wastewater by anaerobic sludge using desirability function approach. Renewable Energy 35(7):1493–1498. Show,K.Y.,Lee,D.J.,Tay,J.H.,Lin,C.Y. y Chang,J.S.(2012).Biohydrogen production :Current perspectives and the way forward. International Journal of Hydrogen Energy 37, 15616-15631. Sivaramakrishna, D., Sreekanth, D., Himabindu, V., Anjaneyulu, Y. (2009).Biological hydrogen production from probiotic wastewater as substrate by selectively enriched anaerobic mixed microflora. Renewable Energy 34(3):937–940. Sreethawong,T.,Niyamapa,T.,Neramitsuk,H.,Rangsunvigit,P.,Leethochawalit,M.,Chavadej, S.(2010).Hydrogen production from glucose-containing wastewater using an anaerobic sequencing batch reactor: Effects of COD loading rate, nitrogen content , and organic acid composition, Chemical Engineering Journal 160,322-332. Satar,I.,Ghasemi,M.,Aljlil,S.,Isahak,W.N.R.W.,Abdalla,A.,Alam,J.,..Y.kbarzdeh,O.(2016). Production of hydrogen by Enterobacter aerogenes in an immobilized cell reactor. International Journal of Hydrogen Energy I-7. Sheldon,M.S. y Edogan,I.G.(2016).Multi –stage EGSB/MBR treatment of soft drink industry wastewater. Chemical Engineering Journal 285,368-377. Shida,G.M.,Barros,A.R.,Reis,C.M.,Calvacante,E.L.,Zamariolli,M.H.R. y Silva,E.L.(2009).Long-term stability of hydrogen and organic acids production in a anaerobic fluidized –bed reactor using heat treated anaerobic sludge inoculum. International journal of Hydrogen energy 34, 3679-3688. Sinha,P.y Pandey,A.(2011).An evaluative report and challenges for fermentative biohydrogen production. International Journal of Hydrogen Energy 36, 7460-7478. Sun,M.,Yongkang,L.V. y Yuxiang,L.(2015). A New Hydrogen-producing strain and its characterization of hydrogen production .Biochem Biotechnol 177, 1676-1689. Suematsu, I. G. (1995). Tratamiento de aguas y selección de tecnologías en función del tipo de reuso. Sutton. (2011). Causas y efectos de la actividad humana. Centro global de cambio climático. Tang, GL., Huang, J., Sun, ZJ., Tang, QQ., Yan, CH., Liu, GQ. (2008).Biohydrogen production from cattle wastewater by enriched anaerobic mixed consortia: influence of fermentation temperature and pH. Journal of Bioscience and Bioengineering 106(1):80–87. Turcot, J., Bisaillon,A. y Hallenbeck, P.C.(2008).Hydrogen production by continuous cultures of Escherchia coli under different nutrient regimes. International Journal of Hydrogen Energy 33, 1465–1470. Trchounian,K.y Trchounian,A.(2014).Hydrogen producing activity by Escherichia coli hydrogenase 4 (hyf) depends on glucose concentration. International Journal of Hydrogen Energy 39, 16914-16918. Ueno,Y., Haruta ,S., Ishii, M. y Igarashi, Y. (2001).Characterization of a microorganism isolated from the effluent of hydrogen fermentation by microflora. J Biosci Bioeng 92,397– 400. Ueno, Y., Fukui, H., Goto, M. (2007).Operation of a two-stage fermentation process producing hydrogen and methane from organic waste. Environmental Science & Technology 41:1413–1419. Vanginkel, S., Oh, S., Logan, B. (2005).Biohydrogen gas production from food processing and domestic wastewaters. International Journal of Hydrogen Energy 30(15):1535–1542. Van ,N.E.W.J., Budde, M.A.W., de Haas ,G.G., van der Wal,F.J., Claassen ,P.A.M.y Stams, A.J.M.(2002).Distinctive properties of high hydrogen producing extreme thermophiles, Caldicellulosiruptor saccharolyticus and Thermotoga elfii. Int J Hydrogen Energy 27, 1391– 1398. Van ,H. A. y Lettinga,G.(1994).Tratamento Anaeróbio de Esgotos. Editora EPGRAF. Campina Grande, Brasil. Vatsala, T., Raj, S., Manimaran, A. (2008).A pilot-scale study of biohydrogen production from distillery effluent using defined bacterial co-culture. International Journal of Hydrogen Energy 33(20):5404–5415. Venegas,E., Morales,J,E,R., Illanes, F,S., Alarcon, J, T., Paillet,F., Escudie, R., Lay, C, H., Chu, C, Y., Leu, H,J., Marone, A.,Lin C,Y., Kim, D, H., Trably, Eric., Filipi,G, R.(2015). Biohydrogen production by dark fermentation: scaling-up and technologies integration for a sustainable system. Environmental Science and Bio/Technology 14:761–785. Venkata, M, S., Lalit Babu, V., Sarma, PN. (2007a).Anaerobic biohydrogen production from dairy wastewater treatment in sequencing batch reactor (AnSBR): effect of organic loading rate. Enzyme Microbial Technologie 41(4):506–515. Venkata, M, S., Vijaya B, Y., Murali, K, P., Chandrasekhara Rao, N., Lalit Babu, V., Sarma, P. (2007b).Biohydrogen production from chemical wastewater as substrate by selectively enriched anaerobic mixed consortia: influence of fermentation pH and substrate composition. International Journal of Hydrogen Energy 32(13):2286–2295. Wang,J. y Wei,W.(2009).Factors influencing fermentative hydrogen production: A revie.International Journal of hydrogen energy 34,799-811. Wang ,J.L. y Wan, W.(2008). Influence of Ni2+ concentration on biohydrogen production. Bioresource Technology 99, 8864–8868. Wang,X.J.,Ren ,N.Q.,Xiang,W.S. y Guo,W.Q.(2007). Influence of gaseous end-products inhibition and nutrient limitations on the growth and hydrogen production by hydrogenproducing fermentative bacterial B49. International Journal Hydrogen Energy 32, 748–54. Wang ,J.L. y Wan, W .(2008). Effect of temperature on fermentative hydrogen production by mixed cultures. Int J Hydrogen Energy 33, 5392–7. Wu,K-J.,Chang,C-F.y Chang,J-S.(2007).Simultaneous production of biohydrogen and bioethanol with fluidized –bes and packed –bed bioreactors containing immobilized anaerobic sludge. Process Biochemistry 42, 1165–1171. Xing ,D.F., Ren,N.Q.,Wang,A.J.,Li,Q.,Feng,Y. y Ma,Fang.(2008). Continuous hydrogen production of auto-aggregative Ethanoligenens harbinense YUAN-3 under non-sterile condition. International Journal Hydrogen Energy 33, 1489–95. Y, Lu., Slater,F.R., Mohd-Zaki,Z., Pratt ,S.y Batstone,D.J. (2011). Impact of operating history on mixed culture fermentation microbial ecology and product mixture. Water Science & Technology 64 (3), 760-765. Yang, H., Shao, P., Lu, T., Shen, J., Wang, D., Xu, Z., Yuan, X. (2006) Continuous biohydrogen production from citric acid wastewater via facultative anaerobic bacteria. International Journal of Hydrogen Energy 31(10):1306–1313. Yecong ,L.,Zhu,J.,Wu,X.,Miller,C. y Wang,L.(2010).The Effect of pH on Continuous Biohydrogen Productionfrom Swine Wastewater Supplemented with Glucose. Biochemistry and biotechnology 162, 1286-1296. Yokoi,H., Ohkawara ,T., Hirose,J., Hayashi,S. y Takasaki,Y. (1995).Characteristics of hydrogen production by aciduric Enterobacter aerogenes strain HO-39. Journal Fermentation Bioengineering 80,571–574. Yu, H., Zhu, Z., Hu, W., Zhang, H. (2002).Hydrogen production from rice winery wastewater in an upflow anaerobic reactor by using mixed anaerobic cultures. International Journal of Hydrogen Energy 27:1359–1365. Zegers, F. (1987) Microbiología, arranque y operación de sistemas de flujo ascendente con manto de lodos UASB. Manual de curso. Universidad del Valle, CVC y Universidad Agrícola de Wageningen. Cali (Colombia). Zhang, H.,Bruns,M.A.y Logan,B.E.(2006).Biological hydrogen production by Clostridium acetobutylicum in an unsaturated flow reactor.Water Research 40,728-734. Zhang,Z-P., Tay,J-H., Show,K-Y., Yan,R.,Liang,D.T., Lee,D-J. y Jiang,W-J. (2007).Biohydrogen production in a granular activated carbón anaerobic fluidized bed reactor. International Journal of Hydrogen Energy 32,185-191. Zheng,X-J y Yu, H-Q. (2003).Roles of pH in Biologic Production of Hydrogen and Volatile Fatty Acids From Glucose by Enriched Anaerobic Cult Laboratory of Clean Bioenergy, School of Chemistry. Zheng, X.J. y Yu, H.Q. (2004). Biological hydrogen production by enriched anaerobic cultures in the presence of copper and zinc. Journal Environ Sci Health 39, 89–101.
dc.rights.coar.fl_str_mv	http://purl.org/coar/access_right/c_abf2
rights_invalid_str_mv	http://purl.org/coar/access_right/c_abf2
dc.format.mimetype.spa.fl_str_mv	application/pdf
dc.coverage.spatial.spa.fl_str_mv	Calle 100
dc.publisher.department.spa.fl_str_mv	Facultad de Ingeniería
dc.publisher.program.spa.fl_str_mv	Ingeniería Civil
dc.publisher.grantor.spa.fl_str_mv	Universidad Militar Nueva Granada
institution	Universidad Militar Nueva Granada
bitstream.url.fl_str_mv	http://repository.unimilitar.edu.co/bitstream/10654/16053/1/BaqueroMu%c3%b1ozAlejandraCatalinaGarc%c3%adaGarc%c3%adaAnaCarolina2017.pdf http://repository.unimilitar.edu.co/bitstream/10654/16053/2/license.txt http://repository.unimilitar.edu.co/bitstream/10654/16053/3/BaqueroMu%c3%b1ozAlejandraCatalinaGarc%c3%adaGarc%c3%adaAnaCarolina2017.pdf.txt http://repository.unimilitar.edu.co/bitstream/10654/16053/4/BaqueroMu%c3%b1ozAlejandraCatalinaGarc%c3%adaGarc%c3%adaAnaCarolina2017.pdf.jpg
bitstream.checksum.fl_str_mv	7e5870d492304341705f28d4e0fceb74 57c1b5429c07cf705f9d5e4ce515a2f6 1814fa749295a45d6a17844008a9884d fc37c5f52da131f6102410d234512650
bitstream.checksumAlgorithm.fl_str_mv	MD5 MD5 MD5 MD5
repository.name.fl_str_mv	Repositorio Institucional UMNG
repository.mail.fl_str_mv	bibliodigital@unimilitar.edu.co
_version_	1837098351022047232
spelling	Rodríguez Chaparro, Adela TatianaGarcía García, Ana CarolinaBaquero Muñoz, Alejandra CatalinaIngeniero CivilCalle 1002017-06-27T19:34:09Z2019-12-26T22:03:04Z2017-06-27T19:34:09Z2019-12-26T22:03:04Z2017-02-28http://hdl.handle.net/10654/16053El uso indiscriminado de combustibles fósiles ha sido hasta el punto de agotar las reservas de combustibles que son limitadas, lo que ha llevado a la búsqueda de nuevas alternativas. Se ha demostrado en varios estudios que con el uso de reactores anaerobios se facilita el proceso de digestión anaerobia, y con la intervención de grupos de bacterias que se desarrollan, ayudan a la producción de hidrógeno en un alto rendimiento.The indiscriminate use of fossil fuels has been to the point of depleting reserves Of fuels that are limited, which has led to the search for new alternatives. It has been demonstrated in several studies that the use of anaerobic reactors facilitates the Process of anaerobic digestion, and with the intervention of groups of bacteria that are Develop, help the production of hydrogen in a high yield.Pregradoapplication/pdfspaEfecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicasEffect of different support media on the production of hydrogen from the industrial non-alcoholic wastewater treatmentinfo:eu-repo/semantics/bachelorThesisTrabajo de gradohttp://purl.org/coar/resource_type/c_7a1fBIOGASHIDROGENOTRATAMIENTO DEL AGUAAGUAS RESIDUALESBiogasHydrogen productionActivated carbonGround rimAnaerobic reactorANOVAConversion of glucoseBiogásProducción de hidrógenoCarbón activadoLlanta trituradaDigestión anaerobiaGlucosaReactor anaerobioANOVAConversión de glucosaFacultad de IngenieríaIngeniería CivilUniversidad Militar Nueva GranadaAcosta, L.Y., Obaya, A. y Ma, Cristina. (2005).La digestión anaerobia. Aspectos teóricos. Parte I.ICIDCA. Sobre los derivados de la caña de azúcar, Vol XXXIX, num.1, 35-48Alzate ,L.M.G.,P,L. Sebastian., Pérez ,A.H. y Eapen, D.(2007).Comparison of two anaerobic systems for hydrogen production from the organic fraction of municipal solid waste and synthetic wastewater. International Hydrogen Energy 32, 3141-3146.ANDESAPA.(1994).Aguas residuales del procesamiento de aguas minerales y de la industria de refrescos y jugos de frutas. Comité coordinador regional de instituciones de Agua potable y saneamiento de Centroamérica, Panamá y Republica Dominicana.Avilés,M.H. y Chaparro,T.R.(2016).Efecto de la configuración de reactores anaerobios de alta tasa en la producción de hidrógeno: biomasa fija y UASB-híbrido.Rev.ion 29,27-36.Azbar, N., C¸ etinkaya Dokgo¨z, FT., Keskin, T., Korkmaz, KS., Syed HM.(2009).Continuous fermentative hydrogen production from cheese whey wastewater under thermophilic anaerobic conditions. International Journal of Hydrogen Energy 34(17):7441–7447Barca,C.,Ranava,D.,Bauzan,M.,Ferrasse,J-H.,Giudici,M. y Soric,A.(2016).Fermentative hydrogen production in an up –flow biofilm reactor inoculated with a co –culture of Clostridium acetobutylicum and Desulfovibrio vulgaris. Bioresource Technology 221,526– 533.Barros, R.A.,Silva,E.L.(2012).Hydrogen and etanol production in anaerobic fluidized bed rectors:performance evaluation for three support materials under different operating condictions.Biochemical Engineering Journal 61,59-65.Bakonyi, P., Kumar, G., Nemesto´thy, N., Lin, CY, and Be´lafi-Bako´, K. (2013).Biohydrogen purification using a commercial polyimide membrane module: studying the effects of some process variables. Hydrogen Energy 38:15092–15099.Bakonyi, P., Nemesto´thy, N., Lanko´, J., Rivera, I., Buitro´n, G., Be´lafi- Bako´, K. (2015) Simultaneous biohydrogen production and purification in a double-membrane bioreactor system. International Journal of Hydrogen Energy 40:1690–1697.Bedoya, A., Castrillón, J.C., Ramírez .J.E., Vásquez, J.E. y Zabalara, M.A. (2007).Producción biológica de hidrógeno: una aproximación al estado del arte universidad nacional de Colombia.Bisaillon,A., Turcot,J. y Hallenbeck,P.C.(2006). The effect of nutrient limitation on hydrogen production by batch cultures of Escherichia coli. Int J Hydrogen Energy 31(11) , 1504–1508.Boileau,C., Richard ,A., Sylvain, D., Laurence, C., Pierre,C., Pierre‑Pol,L. y Combet‑Blanc,Y. (2016).Hydrogen production by the hyperthermophilic bacterium Thermotoga maritima part I: effects of sulfured nutriments, with thiosulfate as model, on hydrogen production and growth.Biotechnol Biofuels9,269.Carminato,V.M. (2013). Influência do cálcio na produção biológica de hidrogênio a partir de águas residuárias em biorreatores anaeróbios. Escola de Engenharia de São Carlos, da Universidade de São PauloCavalcante de A,E.L.,Barros,A.R.,Zamariolli,M.H.R.y Silva,E.L.(2009).Anaerobic fluidized bed reactor with expanded clay as support for hydrogen production through dark fermentation of glucose .International Journal of Hydrogen Energy 34,783-790.Cavalcante de A,E.L.,Sader,L.T. y Silva.E,L.(2011). Effect of Substrate Concentration on Dark Fermentation Hydrogen Production Using an Anaerobic Fluidized Bed Reactor.Biochem Biotechnol 166, 1248-1263.Cavinato, C., Giuliano, A., Bolzonella, D., Pavan, P., Cecchi, F. (2012).Bio-hythane production from food waste by dark fermentation coupled with anaerobic digestion process: a longterm pilot scale experience. International Journal of Hydrogen Energy 37:11549– 11555.Cheng, SS., Chao, YC., Yang, KH., Bai, MD. (2011).Process recovery of biohydrogenation in a pilot plant from methanogens invasion. International Journal of Hydrogen Energy 36:8779– 8784.Chin,H.L.,Chen,Z.S. y Chou,C.P.(2003).Fedbatch operation using Clostridium acetobutylicum suspension culture as biocatalyst for enhancing hydrogen production. Biotechnol Prog. 19(2) ,383–8.Chong, ML., Abdul, Rahman, NA., Rahim, RA., Aziz, SA., Shirai, Y.,Hassan, MA. (2009a) Optimization of biohydrogen production by Clostridium butyricum EB6 from palm oil mil effluent using response surface methodology. International Journal of Hydrogen Energy 34(17):7475–7482Chunfeng, C.,Yoshitaka,E.,Yuhei,I. y Hainan,K.(2009) .Effect of hydraulic retention time on the hydrogen yield and population of Clostridium in hydrogen fermentation of glucose. Journal of Environmental Sciences 21,424–428.Classen,P. y Vrije,G.J.(2007).Hydrogen from biomass.Agrotecnologt and food sciences Group,member of Wagening .BiohydrogenCorrales, L.C., Romero,D.M.A.,Macias,J.A.B,y Vargas,A.M.C.(2015).Bacterias anaerobias: procesos que realizan y contribuyen a la sostenibilidad de la vida en el planeta . Nova.vol.13, N.24, 55-81.Dutta S. (2014) .A review on production, storage of hydrogen and its utilization as an energy resource. Journal of Industrial and Engineering Chemistry 20:1148–1156.Díaz, I. I. (2004). Utilización de biogás para la generación de biogás. Costa Rica: Ambientice.Fang,H.H.P. y Liu,H. (2002). Effect of pH on hydrogen production fromglucose by a mixed culture. Bioresource Technology 82, 87–93.El Heraldo. (2015).Las bebidas no alcohólicas mueven $3.5 billones al año. Recuperado de: http://www.elheraldo.co/economia/las-bebidas-no-alcoholicas-mueven-35-billones-al-ano- 225111.Ferchichi, M., Crabbe, E., Gil, GH., Hintz, W., Almadidy, A. (2005).Influence of initial pH on hydrogen production from cheese whey. Journal Biotechnologie 120(4):402–409.Fernandez,B.S. (2008).Producao de hidrogenio em reator anaeróbio de leito fixo (Tese de Doutor).Universidade de Sao Paulo,Sao Carlos,Brasil.Fernandes,B.S.,Saavedra,N.K.,Maintinguer,S.I.,Sette,L.D.,Oliveira,V.M.,Varesche,M.B.A. y Zait,M.(2013).The effect of biomass immobilization support material and bed porosity on hydrogen production in an upflow anaerobic packed-be bioreactor. Biochem Biotechnol 170, 1348-1366.Fernandes, BS., Peixoto, G., Albrecht, FR., Saavedra del Aguila, NK., ZaiatM.(2010).Potential to produce biohydrogen from various wastewaters. Energy for Sustainable Development 14(2):143–148.Ferreira,P.R.R.,Santos,S.C.y Silva,E.L.(2014).Different ratios of carbon sources in the fermentation of cheese whey and glucose as substrates for hydrogen and ethanol production in continuous reactors. International Journal of Hydrogen Energy 39, 1288-1296.Fontes Lima,D.M., Moreira,W.K.,Zaiat,M.(2013).Comparison of the use of sucrose and glucose as substrate for hydrogen production in an upflow anaerobic fixed – bed reactor. International Journal of Hydrogen Energy 38, 15074-15083.Hafez,H.,Baghchehsaraee,B.,Nakhla,G.,Karamanev,D.,Maragaritis,A.,Naggar,H.(2009). Comparative assessment of decoupling of biomass and hydraulic retention time in hydrogen production bioreactors. International Journal of Hydrogen Energy 34, 7603-7611.Hsiao, CL., Chang, JJ., Wu, JH., Chin, WC., Wen, FS., Huang, CC., Lin, CY. (2009).Clostridium strain co-cultures for biohydrogen production enhancement from condensed molasses fermentation solubles. International Journal of Hydrogen Energy 34(17):7173– 7181.Hu,B. y Chen,S.(2007).Pretreatment of methanogenic granules for immobilized hydrogen fermentation. International Journal Hydrogen Energy 32, 3266-73.Hung,C-H.,Lee,K-S.,Cheng,L-S.,Huang.Y-H.,Lin,P-J. y Chang,J-S. (2007).Quantitative analysis of a high-rate hydrogen –producing microbial community in anaerobic agitated granular sludge bed bioreactors using glucose as substrate. Microbiol Biotechnol 75,693– 701.Ishikawa,M., Yamamura ,S., Takamura,Y., Sode,K., Tamiya, E. y Tomiyama,M. (2006).Development of a compact high-density microbial hydrogen reactor for portable biofuel cell system.International Journal of hydrogen energy 31,1484-1489Islam,R.,Cicek,N., Sparling,R. y Levin,D.(2006). Effect of substrate loading on hydrogen production during anaerobic fermentation by Clostridium thermocellum 27405.Microbiol Biotechnol 72(3), 576-583.Jayalakshmi, S., Joseph, K., Sukumaran, V. (2009).Biohydrogen generation from kitchen waste in an inclined plug flow reactor. International Journal of Hydrogen Energy 34, 8854– 8858.Jo,J.H., Lee,D.S., Park,D., Choe,W-S. Y Park, J.M. (2008). Optimization of key process variables for enhanced hydrogen production by Enterobacter aerogenes using statistical methods. Bioresource Technology 99, 2061–2066.Jung, KW., Kim, DH., Shin, HS. (2010).Continuous fermentative hydrogen production from coffee drink manufacturing wastewater by applying UASB reactor. International Journal of Hydrogen Energy 35(24), 13370–13378.Khanal,S.K.,Chen,W-H.,Li,L. y Sung,S.(2004).Biological hydrogen production: effects of pH and intermediate products. International Journal of hydrogen Energy 29, 1123-1121.Kim, DH., Kim, SH., Kim,KY., Shin, HS. (2010).Experience of pilot-scale hydrogenproducing anaerobic sequencing batch reactor (ASBR) treating food waste. International Journal of Hydrogen Energy 35:1590–1594.Kumar,N. y Das,D. (2001).Continuous hydrogen production by immobilized Enterobacter cloacae IIT-BT 08 using lignocellulosic materials as solid matrices. Enzyme and Microbial Technology 29,280–287.La nota económica. (2010).Pequeños sectores, gaseosas y jugos .Recuperado de: http://www.lanotadigital.com/vademecum/small/bebidas-y-tabaco/gaseosas-y-jugos.Lee, D.Y.,Li,Y.Y. y Noike,T.(2009).Continuous H2 production by anaerobic mixed microflora in membrane bioreactor. Bioresource Technology 100,690-695.Lee,K-S.,Wu,J-F.,Lo,Y-C.,Lin,P-J.,Chang,J-S.(2004).Anaerobic hydrogen production with an efficient carrier-inducedzhan sludge bed biorreactor. Biotechnology Bioteng 87,648-657.Lee,N.,Nielsen,P.H,Aspegren,H.,Henze,M.,Scleifer,K.H. y Jansen,J.(2003).Long-term population Dynamics and in situ Physiology in activated sludge systems with Enhanced biological Phosphorus Removal Operated with and without Nitrogen Removal. Systematic and Applied Microbioly 26,211–227.Lee, YW., Chung, J. (2010).Bioproduction of hydrogen from food waste by pilot-scale combined hydrogen/methane fermentation. International Journal of Hydrogen Energy 35:11746–11755Leite,J.A.C.,Fernandes,B.S.,Pozzi,E.,Barbosza,M. y Zait,M.(2008).Application of an anaerobic packed-bed biorreactor for the production of hydrogen and organic acids. International Journal Hydrogen Energy 33,579-86.Lin,C-Y. y Chang,R-C.(2004).Fermentative hydrogen production at ambient temperature. International Journal Hydrogen Energy 29,715-20.Lin, CY., Wu, SY., Lin, PJ., Chang, JS., Hung, CH., Lee, KS., Lay, CH., Chu, CY., Cheng, CH., Chang, AC., Wu, JH., Chang, FY., Yang, LH., Lee, CW., Lin, YC. (2011) A pilot-scale high-rate biohydrogen production system with mixed microflora. International Journal of Hydrogen Energy 36:8758–8764.Mangayil, R., Karp, M., Santala, V. (2012).Bioconversion of crude glycerol from biodiesel production to hydrogen. International Journal of Hydrogen Energy 37(17):12198–12204.Moraes,B.S.,Zaiat,M., Bonomi ,A.(2015).Anaerobic digestion of vinasse from sugarcane etanol production in Brazil:Challenges and perspectives.Renewable and Sustainable Energy Reviews 44,888-903.Moreno, M.T.V. (2011).Manual de Biogás. MINENERGIA/PNUD/FAO/GEF. Santiago de Chile.Mu,Y., Zheng,X-J., Yu, H-Q. y Zhu, R-F.(2006). Biological hydrogen production by anaerobic sludge at various temperatures. International Journal of hydrogen energy31, 780– 785.Masset,J., Calusinska,M., Hamilton,C., Hiligsmann,S., Joris,B.,Wilmotte,A y Thonart,P.(2012).Fermentative hydrogen production from glucose and starch using pure strains and artificial co-cultures of Clostridium spp. Biotechnology for biofuel 5,35Ngo, TA., Kim, MS., Sim, SJ. (2011).High-yield biohydrogen production from biodiesel manufacturing waste by Thermotoga neapolitana. International Journal of Hydrogen Energy 36(10):5836–5842.Nishio,N. y Nakashimada,Y.(2004). High Rate Production of hydrogen/methane from various substrates and wastes .Biochem Engin/Biotechnol 90, 63-87.Ntaikou ,I., Gavala,H.N., Kornaros,M. y Lyberatos, G.(2008). Hydrogen production from sugars and sweet sorghum biomass using Ruminococcus albus. International Journal of hydrogen energy 33, 1153–63Nuñez,G.C.V.(2013).Panorama del tratamiento de aguas residuales con tecnología anaerobia en la Costa Atlántica Colombiana (Tesis de maestría).Universidad Nacional de Colombia. Bogota, Colombia.Ogino,H.,Miura,T.,Ishimi,K.,Selki,M. y Yoshida,H.(2005).Hydrogen production from glucose by anaerobes. Biotechnol Prog 21, 1786-1788.Oh,S-E.,Ginkel,S.V. y Logan,B.E.(2003).The relative effectiveness of pH control and heat treatment for enhancing biohydrogen gas production .Environmental science & technology 37 (22),5186-5190.Oh,Y.K.,Kim,H-J.,Park,S.,Kim,M-S. y Ryu,D.D.Y.(2008).Metabolic-flux analysis of hydrogen production pathway in Citrobacter amalonaticus Y19. International Journal of Hydrogen Energy 33, 1471–1482.Otero,J., Sanches,A. y Moral,E.(2005).Análisis de la varianza (ANOVA).O-Thong, S., Prasertsan, P., Intrasungkha, N., Dhamwichukorn, S., Birkeland, NK. (2007). Improvement of biohydrogen production and treatment efficiency on palm oil mill effluent with nutrient supplementation at thermophilic condition using an anaerobic sequencing batch reactor. Enzyme Microbial Technology 41(5):583–590.Pan,C.M.,Fan,Y.T., Xing,Y., Hou, H.W. y Zhang,M.L.(2008). Statistical optimization of process parameters on biohydrogen production from glucose by Clostridium sp. Fanp2. Bioresource Technology 99, 3146–3154.Penagos, D.K.G., López, L.J.O., Londoño,S.A.B., Chaparro, T.R., Ortiz, C.E.M., Revollo, A.A.M.,Ruiz,L.A.H.(2017).Manual para el análisis de aguas residuales y lodos. Universidad Militar Nueva Granada. Bogotá, ColombiaPodesta,J.J.,Gutierrez-Navarro,A.M.,Estrella,C.N. y Esteso,M.A.(1997).Electrochemical measurement of trace concentrations of biological hydrogen produced by Enterobacteriaceae. Res. Microbiol 148, 87-93.Reis,C.M,Silva,E.L.(2011).Effect of upflow velocity and hydraulic retention time in anaerobic fluidized-bed reactors used for hydrogen production. Chemical Engineering Journal 172, 28-36.Reis,C.M,Silva,E.L.(2014).Simultaneous Coproduction of Hydrogen and Ethanol in Anaerobic Packed –Bed Reactors .BioMed Research International. Article ID 921291.Ren, N., Li, J., Li, B., Wang, Y., Liu, S. (2006).Biohydrogen production from molasses by anaerobic fermentation with a Rev Environ Sci Biotechnol (2015) 14:761–785 783123pilotscale bioreactor system. International Journal of Hydrogen Energy 31:2147–2157.Revollo,A.A.M.,Avilés,D.M.H.,Arevalo,Y.V.T.y Rodriguez,A.T.C.(2014).Influencia del medio de soporte en la producción de biohidrógeno a partir del tratamiento de aguas residuales de la industria cervecera utilizando reactores de biomasa inmovilizada y flujo ascendente. Universidad Militar Nueva Granada. Bogotá. Colombia.Shi, XY., Jin, DW., Sun, QY., Li, WW. (2010).Optimization of conditions for hydrogen production from brewery wastewater by anaerobic sludge using desirability function approach. Renewable Energy 35(7):1493–1498.Show,K.Y.,Lee,D.J.,Tay,J.H.,Lin,C.Y. y Chang,J.S.(2012).Biohydrogen production :Current perspectives and the way forward. International Journal of Hydrogen Energy 37, 15616-15631.Sivaramakrishna, D., Sreekanth, D., Himabindu, V., Anjaneyulu, Y. (2009).Biological hydrogen production from probiotic wastewater as substrate by selectively enriched anaerobic mixed microflora. Renewable Energy 34(3):937–940.Sreethawong,T.,Niyamapa,T.,Neramitsuk,H.,Rangsunvigit,P.,Leethochawalit,M.,Chavadej, S.(2010).Hydrogen production from glucose-containing wastewater using an anaerobic sequencing batch reactor: Effects of COD loading rate, nitrogen content , and organic acid composition, Chemical Engineering Journal 160,322-332.Satar,I.,Ghasemi,M.,Aljlil,S.,Isahak,W.N.R.W.,Abdalla,A.,Alam,J.,..Y.kbarzdeh,O.(2016). Production of hydrogen by Enterobacter aerogenes in an immobilized cell reactor. International Journal of Hydrogen Energy I-7.Sheldon,M.S. y Edogan,I.G.(2016).Multi –stage EGSB/MBR treatment of soft drink industry wastewater. Chemical Engineering Journal 285,368-377.Shida,G.M.,Barros,A.R.,Reis,C.M.,Calvacante,E.L.,Zamariolli,M.H.R. y Silva,E.L.(2009).Long-term stability of hydrogen and organic acids production in a anaerobic fluidized –bed reactor using heat treated anaerobic sludge inoculum. International journal of Hydrogen energy 34, 3679-3688.Sinha,P.y Pandey,A.(2011).An evaluative report and challenges for fermentative biohydrogen production. International Journal of Hydrogen Energy 36, 7460-7478.Sun,M.,Yongkang,L.V. y Yuxiang,L.(2015). A New Hydrogen-producing strain and its characterization of hydrogen production .Biochem Biotechnol 177, 1676-1689.Suematsu, I. G. (1995). Tratamiento de aguas y selección de tecnologías en función del tipo de reuso.Sutton. (2011). Causas y efectos de la actividad humana. Centro global de cambio climático.Tang, GL., Huang, J., Sun, ZJ., Tang, QQ., Yan, CH., Liu, GQ. (2008).Biohydrogen production from cattle wastewater by enriched anaerobic mixed consortia: influence of fermentation temperature and pH. Journal of Bioscience and Bioengineering 106(1):80–87.Turcot, J., Bisaillon,A. y Hallenbeck, P.C.(2008).Hydrogen production by continuous cultures of Escherchia coli under different nutrient regimes. International Journal of Hydrogen Energy 33, 1465–1470.Trchounian,K.y Trchounian,A.(2014).Hydrogen producing activity by Escherichia coli hydrogenase 4 (hyf) depends on glucose concentration. International Journal of Hydrogen Energy 39, 16914-16918.Ueno,Y., Haruta ,S., Ishii, M. y Igarashi, Y. (2001).Characterization of a microorganism isolated from the effluent of hydrogen fermentation by microflora. J Biosci Bioeng 92,397– 400.Ueno, Y., Fukui, H., Goto, M. (2007).Operation of a two-stage fermentation process producing hydrogen and methane from organic waste. Environmental Science & Technology 41:1413–1419.Vanginkel, S., Oh, S., Logan, B. (2005).Biohydrogen gas production from food processing and domestic wastewaters. International Journal of Hydrogen Energy 30(15):1535–1542.Van ,N.E.W.J., Budde, M.A.W., de Haas ,G.G., van der Wal,F.J., Claassen ,P.A.M.y Stams, A.J.M.(2002).Distinctive properties of high hydrogen producing extreme thermophiles, Caldicellulosiruptor saccharolyticus and Thermotoga elfii. Int J Hydrogen Energy 27, 1391– 1398.Van ,H. A. y Lettinga,G.(1994).Tratamento Anaeróbio de Esgotos. Editora EPGRAF. Campina Grande, Brasil.Vatsala, T., Raj, S., Manimaran, A. (2008).A pilot-scale study of biohydrogen production from distillery effluent using defined bacterial co-culture. International Journal of Hydrogen Energy 33(20):5404–5415.Venegas,E., Morales,J,E,R., Illanes, F,S., Alarcon, J, T., Paillet,F., Escudie, R., Lay, C, H., Chu, C, Y., Leu, H,J., Marone, A.,Lin C,Y., Kim, D, H., Trably, Eric., Filipi,G, R.(2015). Biohydrogen production by dark fermentation: scaling-up and technologies integration for a sustainable system. Environmental Science and Bio/Technology 14:761–785.Venkata, M, S., Lalit Babu, V., Sarma, PN. (2007a).Anaerobic biohydrogen production from dairy wastewater treatment in sequencing batch reactor (AnSBR): effect of organic loading rate. Enzyme Microbial Technologie 41(4):506–515.Venkata, M, S., Vijaya B, Y., Murali, K, P., Chandrasekhara Rao, N., Lalit Babu, V., Sarma, P. (2007b).Biohydrogen production from chemical wastewater as substrate by selectively enriched anaerobic mixed consortia: influence of fermentation pH and substrate composition. International Journal of Hydrogen Energy 32(13):2286–2295.Wang,J. y Wei,W.(2009).Factors influencing fermentative hydrogen production: A revie.International Journal of hydrogen energy 34,799-811.Wang ,J.L. y Wan, W.(2008). Influence of Ni2+ concentration on biohydrogen production. Bioresource Technology 99, 8864–8868.Wang,X.J.,Ren ,N.Q.,Xiang,W.S. y Guo,W.Q.(2007). Influence of gaseous end-products inhibition and nutrient limitations on the growth and hydrogen production by hydrogenproducing fermentative bacterial B49. International Journal Hydrogen Energy 32, 748–54.Wang ,J.L. y Wan, W .(2008). Effect of temperature on fermentative hydrogen production by mixed cultures. Int J Hydrogen Energy 33, 5392–7.Wu,K-J.,Chang,C-F.y Chang,J-S.(2007).Simultaneous production of biohydrogen and bioethanol with fluidized –bes and packed –bed bioreactors containing immobilized anaerobic sludge. Process Biochemistry 42, 1165–1171.Xing ,D.F., Ren,N.Q.,Wang,A.J.,Li,Q.,Feng,Y. y Ma,Fang.(2008). Continuous hydrogen production of auto-aggregative Ethanoligenens harbinense YUAN-3 under non-sterile condition. International Journal Hydrogen Energy 33, 1489–95.Y, Lu., Slater,F.R., Mohd-Zaki,Z., Pratt ,S.y Batstone,D.J. (2011). Impact of operating history on mixed culture fermentation microbial ecology and product mixture. Water Science & Technology 64 (3), 760-765.Yang, H., Shao, P., Lu, T., Shen, J., Wang, D., Xu, Z., Yuan, X. (2006) Continuous biohydrogen production from citric acid wastewater via facultative anaerobic bacteria. International Journal of Hydrogen Energy 31(10):1306–1313.Yecong ,L.,Zhu,J.,Wu,X.,Miller,C. y Wang,L.(2010).The Effect of pH on Continuous Biohydrogen Productionfrom Swine Wastewater Supplemented with Glucose. Biochemistry and biotechnology 162, 1286-1296.Yokoi,H., Ohkawara ,T., Hirose,J., Hayashi,S. y Takasaki,Y. (1995).Characteristics of hydrogen production by aciduric Enterobacter aerogenes strain HO-39. Journal Fermentation Bioengineering 80,571–574.Yu, H., Zhu, Z., Hu, W., Zhang, H. (2002).Hydrogen production from rice winery wastewater in an upflow anaerobic reactor by using mixed anaerobic cultures. International Journal of Hydrogen Energy 27:1359–1365.Zegers, F. (1987) Microbiología, arranque y operación de sistemas de flujo ascendente con manto de lodos UASB. Manual de curso. Universidad del Valle, CVC y Universidad Agrícola de Wageningen. Cali (Colombia).Zhang, H.,Bruns,M.A.y Logan,B.E.(2006).Biological hydrogen production by Clostridium acetobutylicum in an unsaturated flow reactor.Water Research 40,728-734.Zhang,Z-P., Tay,J-H., Show,K-Y., Yan,R.,Liang,D.T., Lee,D-J. y Jiang,W-J. (2007).Biohydrogen production in a granular activated carbón anaerobic fluidized bed reactor. International Journal of Hydrogen Energy 32,185-191.Zheng,X-J y Yu, H-Q. (2003).Roles of pH in Biologic Production of Hydrogen and Volatile Fatty Acids From Glucose by Enriched Anaerobic Cult Laboratory of Clean Bioenergy, School of Chemistry.Zheng, X.J. y Yu, H.Q. (2004). Biological hydrogen production by enriched anaerobic cultures in the presence of copper and zinc. Journal Environ Sci Health 39, 89–101.http://purl.org/coar/access_right/c_abf2ORIGINALBaqueroMuñozAlejandraCatalinaGarcíaGarcíaAnaCarolina2017.pdfTrabajo de gradoapplication/pdf1898916http://repository.unimilitar.edu.co/bitstream/10654/16053/1/BaqueroMu%c3%b1ozAlejandraCatalinaGarc%c3%adaGarc%c3%adaAnaCarolina2017.pdf7e5870d492304341705f28d4e0fceb74MD51LICENSElicense.txttext/plain1521http://repository.unimilitar.edu.co/bitstream/10654/16053/2/license.txt57c1b5429c07cf705f9d5e4ce515a2f6MD52TEXTBaqueroMuñozAlejandraCatalinaGarcíaGarcíaAnaCarolina2017.pdf.txtExtracted texttext/plain195395http://repository.unimilitar.edu.co/bitstream/10654/16053/3/BaqueroMu%c3%b1ozAlejandraCatalinaGarc%c3%adaGarc%c3%adaAnaCarolina2017.pdf.txt1814fa749295a45d6a17844008a9884dMD53THUMBNAILBaqueroMuñozAlejandraCatalinaGarcíaGarcíaAnaCarolina2017.pdf.jpgIM Thumbnailimage/jpeg4028http://repository.unimilitar.edu.co/bitstream/10654/16053/4/BaqueroMu%c3%b1ozAlejandraCatalinaGarc%c3%adaGarc%c3%adaAnaCarolina2017.pdf.jpgfc37c5f52da131f6102410d234512650MD5410654/16053oai:repository.unimilitar.edu.co:10654/160532020-06-30 12:39:57.727Repositorio Institucional UMNGbibliodigital@unimilitar.edu.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

Efecto de diferentes medios de soporte en la producción de hidrógeno a partir del tratamiento de aguas residuales industriales no alcohólicas

Publicaciones similares