{"id":607,"date":"2020-09-28T14:06:08","date_gmt":"2020-09-28T14:06:08","guid":{"rendered":"https:\/\/www.unioviedo.es\/TBR\/?page_id=607"},"modified":"2020-11-10T16:56:26","modified_gmt":"2020-11-10T16:56:26","slug":"reactions-and-reactors","status":"publish","type":"page","link":"https:\/\/www.unioviedo.es\/TBR\/reactions-and-reactors\/","title":{"rendered":"Reactions and Reactors"},"content":{"rendered":"\n<p class=\"has-medium-font-size\"><strong>3.1. Absorption<\/strong><br><\/p>\n\n\n\n<p>  3.1.1.With reaction <\/p>\n\n\n\n<ul><li>\u201cSulphur dioxide absortion with chemical reaction in a slurry spray reactor\u201d. M. D\u00edaz, J. Coca. Dechema 517-528 (1980).<\/li><li>\u00abAbsorption of Sulphur Dioxide in a Stirred Tank\u00bb. J. Coca, J.L. Bueno, M. D\u00edaz. Act. I Cong. Nac. Qu\u00edmica, Vol. 1, 235-243 (1977).<\/li><li>\u201cProcesos para la eliminaci\u00f3n de SO2 en gases residuales\u201d. M. D\u00edaz, J. Coca. Ingenier\u00eda Qu\u00edmica 89-94 (1979).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.2. Inorganic oxidation<\/strong><\/p>\n\n\n\n<p>  3.2.1.Sulphite oxidation<\/p>\n\n\n\n<ul><li>\u00abKinetics of heterogeneous oxidation of diluted sulphite solutions\u00bb. J. Coca, M. D\u00edaz. Hungary Journal of Industrial Chemistry 15, 187-195 (1987).<\/li><li>\u00abOxidaci\u00f3n Heterog\u00e9nea de Sulfito a Concentraciones Bajas\u00bb. M. D\u00edaz, J. Coca. Actas 1er Cong. Medit. de Ing.Qu\u00edmica, vol1, 570-583 (1977).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.3. Organic oxidation<\/strong><\/p>\n\n\n\n<p>  3.3.1.Solubles: Phenolics<\/p>\n\n\n\n<ul><li>\u00abCatalyzed oxidation kinetics of anthracene with oxygen in ethylene glycol\u00bb. E. Cepeda, M. D\u00edaz. Industrial &amp; Engineering Chemistry Research 26, 2401-2403, (1987).<\/li><li>\u201cNon-catalytic oxidation of phenol in aqueous solutions\u201d. J. Vicente, R. Rosal, M. D\u00edaz. Industrial &amp; Engineering Chemistry Research 41, 46-51 (2002).<br><\/li><li>\u201cThiocyanate\/Phenol wet oxidation interactions\u201d. J. Vicente, M. D\u00edaz. Environmental Science &amp; Technology 37, 1457-1462 (2003).<\/li><li>\u201cCatalytic wet oxidation of phenol with homogeneous iron salts\u201d. J. Vicente, R. Rosal, M. D\u00edaz. Journal of Chemical Technology &amp; Biotechnology 80, 1031-1035 (2005).<\/li><li>\u201cWet oxidation of salicylic acid solutions\u201d. S. Collado, L. Garrido, A. Laca, M. D\u00edaz. Environmental Science and Technology 44 (22), 8629-8635 (2010).<\/li><li>\u201cFe2+ catalyzed wet oxidation of phenolic acids under different pH values\u201d. S. Collado, D. Quero, A. Laca, M. D\u00edaz. Industrial &amp; Engineering Chemistry Research 49 (24), 12405-12413 (2010).<br><\/li><\/ul>\n\n\n\n<p>\n\n 3.3.2.Solubles: CN, SCN\n\n<\/p>\n\n\n\n<ul><li>\u201cThiocyanate wet oxidation\u201d. J. Vicente, M. D\u00edaz. Environmental Science &amp; Technology 37, 1452-1456 (2003).<\/li><li>\u201cOxidation of thiocyanate under different pH conditions: kinetics and mechanistic analysis\u201d. S. Collado, A. Laca, M. D\u00edaz. Industrial and Engineering Chemistry Research 48, 9902-9909 (2009).<\/li><li>\u201cCatalytic wet oxidation of thiocyanate with homogeneous copper (II) sulphate catalyst\u201d. S. Collado, A. Laca, M. D\u00edaz. Journal of Hazardous Materials 177, 183-189 (2010).<\/li><li>\u201cWet oxidation of real coke waste water containing high thiocyanate concentration\u201d. P. Oulego, S. Collado, L. Garrido, A. Laca, M. Rendueles, M. D\u00edaz. Journal of Environmental Management 132, 16-23 (2014).<\/li><li>\u201cSimultaneous oxidation of cyanide and thiocyanate at high pressure and temperature\u201d. P. Oulego, S. Collado, A. Laca, M. D\u00edaz. Journal of Hazardous Materials 280, 570-578 (2014).<\/li><li>\u201cConditions and mechanisms in thiocyanate biodegradation\u201d. R.G. Combarros, S. Collado, A. Laca, M. D\u00edaz. Journal of Residuals Science and Technology 12, 113-114 (2015).<\/li><li>\u201cIron (II) as catalyst for thiocyanate wet oxidation: mechanism and modelization\u201d. P. Oulego, S. Collado, M. D\u00edaz. Chemical Eng. J., 316, 813-822 (2017)<\/li><li>\u201cTratamiento de efluentes de coquer\u00eda mediante oxidaci\u00f3n h\u00fameda (I) Caracter\u00edsticas generales del proceso\u201d. J. Vicente, M. D\u00edaz. Ingenier\u00eda Qu\u00edmica 412, 142-161 (2004).<\/li><li>\u201cTratamiento de efluentes de coquer\u00eda mediante oxidaci\u00f3n h\u00fameda (II). Aplicaci\u00f3n a los principales contaminantes\u201d. J. Vicente, M. D\u00edaz. Ingenier\u00eda Qu\u00edmica 413, 188-209 (2004).<br><\/li><\/ul>\n\n\n\n<p>  3.3.3.Solubles: Pharma and toxics <\/p>\n\n\n\n<ul><li>\u201cEffect of the carboxylic substituent on the reactivity of the aromatic ring during the wet oxidation of phenolic acids\u201d. S. Collado, A. Laca, M. D\u00edaz. Chemical Engineering Journal 166 (3), 940-946 (2011).<\/li><li>\u201cEfficiency and sensitivity of the wet oxidation\/biological steps in coupled pharmaceutical wastewater treatment\u201d. S. Collado, D. Quero, A. Laca, M. D\u00edaz. Journal of Chemical Engineering Journal 234, 484-490 (2013).<br><\/li><li>\u201cEffect of intermediate compounds and products on wet oxidation and biodegradation rates of pharmaceutical compounds\u201d. S. Collado, A. Laca, M. D\u00edaz. J. Chemosphere 92, 207-212 (2013).<\/li><li>\u201cPersulfate activation by modified red mud for the oxidation of antibiotic sulfamethoxazole in water\u201d. Alexandra Ioannidi, Paula Oulego, Sergio Collado, Athanasia Petala, Victor Arniella, Zacharias Frontistis, George N. Angelopoulos, Mario Diaz, Dionissios Mantzavinos. J. of Environmental Management, accepted 21 mayo 2020.<\/li><li>\u201cTratamiento por oxidaci\u00f3n h\u00fameda de lixiviados de vertedero\u201d. P. Oulego, S. Collado, A. Laca, M. D\u00edaz. Libro de Actas, 113-116. META (2014).<br><\/li><\/ul>\n\n\n\n<p>  3.3.4.Solubles: humic acids<\/p>\n\n\n\n<ul><li>\u201cTertiary treatment of biologically pre-treated landfill leachates by non-catalytic wet oxidation\u201d. P. Oulego, S. Collado, A. Laca, M. D\u00edaz. Chemical Engineering Journal 273, 647-655 (2015).<\/li><li>\u201cImpact of leachate composition on the advanced oxidation treatment\u201d. P. Oulego, S. Collado, A. Laca, M. D\u00edaz. Water Research 88, 389-402 (2016).<\/li><li>\u201dThe wet oxidation of aqueous humic acids\u201d, Manuel Garc\u00eda, Paula Oulego, Sergio Collado, Mario D\u00edaz. J. of Hazardous Materials, 396, Sept. 2020 , 122402.<br><\/li><\/ul>\n\n\n\n<p>  3.3.5.Solids <\/p>\n\n\n\n<ul><li>\u201cSludge hydrothermal treatments. Oxidising atmosphere effects on biopolymers and physical properties\u201d, J.L. Urrea, M. Garc\u00eda, S. Collado, P. Oulego, M.D\u00edaz. Journal of Environmental Management (2018) Jan 15;206:284-290<\/li><li>\u201dValorization of steel slag towards a Fenton-like catalyst for the degradation of paraben by activated persulfate\u00bb. Vassili Matthaiou, Paula Oulego, Zacharias Frontistis, Sergio Collado, Dimitra Hela, Ioannis K. Constantinou, Mario D\u00edaz, Dionisios Mantzavinos. Chemical Engineering J. 360, 15 march, 728-739 (2019)<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.4. G\/L: Hydrolisis <\/strong><\/p>\n\n\n\n<p>\n\n 3.4.1.Soluble\n\n<\/p>\n\n\n\n<ul><li>\u201cProduction of carboxylic acids from the non-lignin residue of black liquor by hydrthermal treatments\u201d. Lucia Pola, Sergio Collado, Paula Oulego, Mario D\u00edaz. Bioresource Technology 284, July, 105-114 (2019)<\/li><li>\u201cHydrothermal processing of Kraft Lignin for carboxylic acid production\u201d. L. Pola, P. Oulego, S. Collado, M. D\u00edaz. Journal of Environmental Chemical Engineering Volume 7, Issue 6, December 2019.<br><\/li><\/ul>\n\n\n\n<p>  3.4.2.Suspension <\/p>\n\n\n\n<ul><li>\u201cWet oxidation of activated sludge: Transformations and mechanims\u201d. J.L. Urrea, S. Collado, A. Laca, M. D\u00edaz. Journal of Environmental Management 146, 251-259 (2014).<\/li><li>\u201cEffect of wet oxidation on the fingerprints of polymeric substances from an activated sludge\u201d. J.L. Urrea, P. Oulego, S. Collado, M. D\u00edaz. Water Research 105, 282-290 (2016).<\/li><li>\u201cFormation and degradation of soluble of soluble biopolymers during wet oxidation of sludge\u201d, Jos\u00e9 Luis Urrea, Sergio Collado, Paula Oulego, Mario D\u00edaz. ACS Sustainable Chemistry &amp; Engineering 5(4) 3011-3018 (2017)<\/li><li>\u201cWet oxidation of the structural sludge fractions\u201d J.L. Urrea, P. Oulego, S. Collado, M. D\u00edaz, J. of Cleaner Production, 168, 1 December 1163-117 (2017)<\/li><li>\u201cSludge chemical and rheological transformation by hydrolysis and oxidation at high temperature\u201d. P. Oulego, J.L. Urrea,A. Laca, S. Collado, M. Diaz. 3rd European Conference on Environmental Applications of Advanced Oxidation Processes (EAAOP-3). Libro de Abstracts (2013).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.5. Solid \u2013 fluid reactions <\/strong><\/p>\n\n\n\n<p>  3.5.1.Phase transfer catalysis<\/p>\n\n\n\n<ul><li>\u00abChemical and geometrical factors in limestone slurries dissolution in stirred tanks\u00bb. M. D\u00edaz, L. Fonseca, J. Coca.Hung. J. of Ind. Chem. 11, 81-89 (1983).<\/li><li>\u00abEmpleo de catalizadores s\u00f3lidos en reacciones de alquilaci\u00f3n L-L. Cat\u00e1lisis trif\u00e1sica\u00bb. M. D\u00edaz, F. Varona, J. Gonz\u00e1lez. Afinidad 47, 105-108 (1990).<\/li><li>\u00abEtapas previas a la depuraci\u00f3n y recuperaci\u00f3n de metales de aguas residuales de la lixiviaci\u00f3n de cenizas residuales\u00bb. F. Mijangos, A. Irabien, M. D\u00edaz. Actas SMAGUA 85, 257-264 (1985).<\/li><li>\u00abCin\u00e9tica de intercambio de haluros por reacci\u00f3n de cat\u00e1lisis con transferencia entre fases\u00bb. F. Varona, M. D\u00edaz. Actas Symp. Iberoam Catal. 1, 311-319, (1986).<\/li><li>\u00abDisoluci\u00f3n y tratamiento de residuos s\u00f3lidos cianurados\u00bb. J.R. Viguri, J.M. D\u00edaz. Tecnolog\u00eda del Agua 35, 35-44 (1987).<\/li><li>\u00abReacciones con transferencia de catalizador (PTC) y sus aplicaciones\u00bb. F. Varona, J.M.D\u00edaz. Industria Farmac\u00e9utica Investigaci\u00f3n y Tecnolog\u00eda, Nov-Dic., 47-52 (1989).<br><\/li><\/ul>\n\n\n\n<p>  3.5.2. With limestone<\/p>\n\n\n\n<ul><li>\u00abKinetics of limestone slurries dissolution in sulfuric acid\u00bb. M. D\u00edaz, L. Fonseca, J. Coca. Chemie Ingenieur Technik 57, 882-883 (1985).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.6. Catalysts and adsorbers<\/strong><\/p>\n\n\n\n<p>  3.6.1.Agro wastes<\/p>\n\n\n\n<ul><li>\u201cThe effect of the synthetic route on the structural, textural, morphological and catalytic properties of iron(III) oxides and oxyhydroxides\u201d. P. Oulego, M.A. Villa-Garc\u00eda, A. Laca, M. D\u00edaz. Dalton Transactions 45, 9446-9459 (2016).<\/li><li>\u201cEggshell waste as catalyst: A Review\u201d, A. Laca, A. Laca, M. D\u00edaz. J. of Environmental Management, 197, 351-359, jul (2017)<br><\/li><\/ul>\n\n\n\n<p>  3.6.2.Industrial wastes<\/p>\n\n\n\n<ul><li>\u201cStructural, textural and protein adsorption properties of kaolinite and surface modified kaolinite adsorbents\u201d. R. Duarte-Silva, M.A. Villa-Garc\u00eda, M. Rendueles, M. D\u00edaz. Applied Clay science 90, 73-80 (2014).<br><\/li><li>\u201cSynthesis of the ion-exchanger based on 2-(diethylamino)ethyl Methacrylate-coEthyleneglycol Dimethacrylate beads: physico-chemical characterization and chromatographic performance for sulfonamide adsorption\u201d. A.M. L\u00f3pez, M.A. Villa-Garc\u00eda, M. Rendueles, M. D\u00edaz. Solvent Extraction &amp; Ion Exchange 33, 295-312 (2015).<\/li><li>\u201dValorization of steel slag towards a Fenton-like catalyst for the degradation of paraben by activated persulfate\u00bb Vassili Matthaiou, Paula Oulego, Zacharias Frontistis, Sergio Collado, Dimitra Hela, Ioannis K. Constantinou, Mario D\u00edaz, Dionisios Mantzavinos. Chemical Engineering J. 360, 15 march, 728-739 (2019)<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.7. Solid transformations<\/strong><\/p>\n\n\n\n<p>  3.7.1.With diffusion <\/p>\n\n\n\n<ul><li>\u00abLixiviaci\u00f3n en tanque agitado de una mezcla (pisos-fluidizado) de cenizas pir\u00edticas retostadas\u00bb, F. Mijangos, P. Apeztegu\u00eda, F. Varona, J.I. Lombra\u00f1a, M. D\u00edaz. Revista Metalurgia 28, 32-38 (1992).<\/li><li>\u201cBiochemical and technological properties of Penicillium roqueforti and Geotrichum candidum strains isolated from Cabrales, a Spanish traditional, blue-veined, starter-free cheese\u201d. C.O. Ferreira, P. \u00c1lvarez-Mart\u00edn, A.B. Fl\u00f3rez, M. D\u00edaz, B. Mayo. Italian Journal of Food Science 24, 1-10 (2012).<\/li><li>\u201cSeguridad Alimentaria y desarrollo de pat\u00f3genos. (I) Caracterizaci\u00f3n\u201d. A. Laca, M. D\u00edaz. Alimentaci\u00f3n, Equipos y Tecnolog\u00eda 182, 109-114 (2003).<\/li><li>\u201cSeguridad Alimentaria y desarrollo de dat\u00f3genos. (II) Modelizaci\u00f3n\u201d. A. Laca, M. D\u00edaz. Alimentaci\u00f3n, Equipos y Tecnolog\u00eda 183, 88-93 (2003).<br><\/li><\/ul>\n\n\n\n<p>  3.7.2.Solid models<\/p>\n\n\n\n<ul><li>\u201cCharacterization of natural and synthetic casings and mechanism of BaP penetration in smoked meat products\u201d. E. Ledesma, M. Rendueles, M. D\u00edaz. Food Control 32, 195-205 (2015).<\/li><li>\u201cSpanish Smoked meat products: Benzo(a)pyrene (BaP) contamination and moisture\u201d. E. Ledesma, M. Rendueles, M. D\u00edaz. Journal of Food Composition and Analysis 37, 87-94 (2015).<br><\/li><\/ul>\n\n\n\n<p>  3.7.3.Biologic models<\/p>\n\n\n\n<ul><li>\u00abInformation of metals pollution in the rainfall-plants-soil system in industrial\/urban and rural area\u00bb. C. Elejalde, R. Suarez, F. Romero, M. D\u00edaz. Proceed. world Cong. III Chem. Eng, 671-673, (1986).<\/li><li>\u00abMetal distribution and interaction in plant cultives on artificial soil\u00bb. M.N. Azpiazu, F. Romero, M. D\u00edaz. Water, Air &amp;Soil Pollution 28, 1-26 (1986).<\/li><li>\u00abDistribuci\u00f3n de componentes met\u00e1licos potencialmente t\u00f3xicos en plantas\u00bb M.N. Azpiazu, F. Romero, J.M. D\u00edaz. Afinidad 411, 385-389 (1987).<\/li><li>\u00abCin\u00e9tica y distribuci\u00f3n de componentes met\u00e1licos en un sistema polif\u00e1sico con crecimiento vegetal\u00bb. M.N. Azpiazu, F. Romero, J.M. D\u00edaz. Afinidad 410, 313-319 (1987).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.8. Gas Liquid and Gas Liquid \u2013 liquid  <\/strong><\/p>\n\n\n\n<p>  3.8.1.Reaction and dispersion <\/p>\n\n\n\n<ul><li>\u00abDise\u00f1o de reactores fluido-fluido con dispersi\u00f3n en dos fases para reacciones irreversibles r\u00e1pidas en una fase\u00bb. J.M. D\u00edaz, A.T. Aguayo. Anales de Qu\u00edmica 85, 530-537 (1989). <\/li><\/ul>\n\n\n\n<p>\n\n3.8.2.G-L-L\u2019\n\n<\/p>\n\n\n\n<ul><li>\u00abEmulsion analysis in a gas\/liquid\/liquid reactor with top blowing\u201d. M. Martin, M. Rendueles, M. D\u00edaz. The Canadian Journal of Chemical Engineering 82, 249-255 (2004).<\/li><li>\u201cSteel-slag mass transfer in steel converter, bottom and top\/bottom combined blowing through cold model experiments\u201d. M. Martin, M. Rendueles, M. D\u00edaz. Trans Ichem.E 83 (A9), 1076-1084 (2005).<\/li><li>\u201cAnalysis of kinetic data in industrial steel converter for the operation control\u201d. C. Blanco, E. Garc\u00eda, M. Rendueles, M. D\u00edaz, L.F. Sancho. Revue de Metallurgie 2, 59-66 (2007).<\/li><li>\u00abAproximaci\u00f3n a la modelizaci\u00f3n de los convertidores de acero\u00bb. C. Blanco, A. P\u00e9rez, J.M. D\u00edaz. Actas VIII Congreso Nacional de Qu\u00edmica. Ciencia y Tecnolog\u00eda de Materiales Met\u00e1licos. Vol. I, 285-292 (1989).<\/li><li>\u201c1,2,4-Trichlorobenzene flow characteristics in saturated homogeneous and stratified porous media\u201d. J. D\u00edaz, M. Rendueles, M. D\u00edaz. Water, Air &amp; Soil Pollution 117 (1-4), 3-17 (2006).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.9. Membrane reactors<\/strong><\/p>\n\n\n\n<p>  3.9.1.External reaction<\/p>\n\n\n\n<ul><li>\u201cImpact of mechanical shear stress and protective effect of serum on hybridoma cells\u201d. L. Legazpi, A. Laca, M. D\u00edaz, Journal of Biotechnology 131 (2), S184 (2007).<\/li><li>\u201cKinetic analysis of hybridoma cells viability under mechanical shear stress with and without serum protection\u201d. L. Legazpi, A. Laca, M. D\u00edaz. Bioprocess and Biosystems Engineering 32 (6), 717-722 (2009).<\/li><li>\u201cDiffusion and inhibition processes in a hollow-fiber membrane bioreactor for hybridoma culture. Development of a mathematical model\u201d. L. Legazpi, A. Laca, S. Collado, A. Laca, M. D\u00edaz. Chemical and Biochemical Engineering Quarterly 30, 213-225 (2016).<\/li><li>\u201cEnsuciamiento en MBRs para el tratamiento de aguas residuales (y III)\u201d. S. Collado, A. Laca, M. D\u00edaz, P. Sim\u00f3n, M. Abell\u00e1n, M Polo, A. Ranca\u00f1o. Industria Qu\u00edmica Octubre, 58-64 (2013).<br><\/li><\/ul>\n\n\n\n<p> 3.9.2.Internal reaction <\/p>\n\n\n\n<ul><li>\u201cPseudomonas putida response in membrane bioreactors under salicylic acid-induced stress conditions\u201d. S. Collado, I. Rosas, E. Gonz\u00e1lez, A. Guti\u00e9rrez-Lav\u00edn, M. D\u00edaz. Journal of Hazardous Materials 267, 9-16 (2014).<br><\/li><li>\u201cFouling mechanisms of Pseudomonas putida on PES microfiltration membranes\u201d. I. Rosas, S. Collado, A. Guti\u00e9rrez, M. D\u00edaz. Journal of Membrane Science 465, 27-33 (2014).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.10. In column <\/strong><\/p>\n\n\n\n<p>  3.10.1. Permeation in soils<\/p>\n\n\n\n<ul><li>\u201cInteractions on the Soil-Rainfall System of a lime stabilized sludge as surface amendment\u201d. D. Su\u00e1rez, M. Rendueles, M. D\u00edaz. Water, Air and Soil Pollution 127, 31-48 (2001).<\/li><li>\u201c1,2,4-Trichlorobenzene flow characteristics in saturated homogeneous and stratified porous media\u201d. J. D\u00edaz, M. Rendueles, M. D\u00edaz. Water, Air &amp; Soil Pollution 117 (1-4), 3-17 (2006).<\/li><li>\u201cStraining phenomena in bacteria transport through natural porous media\u201d. J. D\u00edaz, M. Rendueles, M. D\u00edaz. Environmental Science and Pollutant Research 17, 400-409 (2010).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.11. Equipment selection<\/strong><\/p>\n\n\n\n<p>  3.11.1. For water treatment<\/p>\n\n\n\n<ul><li>\u00abLa alternativa energ\u00e9tica del hidr\u00f3geno\u00bb. H. Sastre, M. D\u00edaz. Energ\u00eda, Sept. OC. 89-100 (1985).<\/li><li>\u201cDecision criteria for the selection of wet oxidation and conventional biological treatment\u201d. S. Collado, A. Laca, M. Diaz. Journal of Environmental Management 102, 65-70 (2012).<\/li><li>\u00abCuantificaci\u00f3n del sobredimensionado en plantas Qu\u00edmicas\u00bb. M. D\u00edaz, I. Zubizarreta. Ingenier\u00eda Qu\u00edmica, Octubre ,185-213 (1987).<br><\/li><\/ul>\n\n\n\n<p class=\"has-medium-font-size\"><strong>  3.12. Products preparation <\/strong><\/p>\n\n\n\n<p>  3.12.1. Fertilizer<\/p>\n\n\n\n<ul><li>\u201cSulfato pot\u00e1sico por el m\u00e9todo de la glaserita. calidad del producto y modificaciones del proceso\u201d. M. Rendueles, J.M. Fidalgo, M. D\u00edaz. Ingenier\u00eda Qu\u00edmica, Noviembre, 153-160 (1996).<\/li><li>\u00abFollowing of industrial processes using empirical behaviour models\u00bb. C. Blanco, M. Mart\u00edn, A. Vega, M. D\u00edaz. Computer Oriented Process Engineering, Elsevier Ed., ISBN 0-444-88786-5, 171-176 (1991).<\/li><li>\u00abProcesos de conversi\u00f3n de acero y efecto de variables en convertidores tipo L.B.E.\u00bb. C. Blanco, A. Vega, M. D\u00edaz. Revista Metalurgia Madrid 31, 286-297 (1995).<br><\/li><\/ul>\n\n\n\n<p>  3.12.2. Steel converter <\/p>\n\n\n\n<ul><li>\u00abModel of mixed control for carbon and silicon in a steel converter\u00bb. C. Blanco, M. D\u00edaz. ISIJ International 33, 757-763 (1993).<\/li><li>\u201cSimulaci\u00f3n num\u00e9rica del proceso de mezcla en el convertidor de acero. Efecto del m\u00e9todo de carga de los aditivos\u201d. M. D\u00edaz, M.E. Garc\u00eda. Revista Metalurgia Madrid 32, 96-102 (1996).<\/li><\/ul>\n","protected":false},"excerpt":{"rendered":"<p>3.1. Absorption 3.1.1.With reaction \u201cSulphur dioxide absortion with chemical reaction in a slurry spray reactor\u201d. M. D\u00edaz, J. Coca. Dechema 517-528 (1980). \u00abAbsorption of Sulphur Dioxide in a Stirred Tank\u00bb. J. Coca, J.L. Bueno, M. D\u00edaz. Act. I Cong. Nac. Qu\u00edmica, Vol. 1, 235-243 (1977). \u201cProcesos para la eliminaci\u00f3n de SO2 en gases residuales\u201d. M. [&hellip;]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"ngg_post_thumbnail":0},"_links":{"self":[{"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/pages\/607"}],"collection":[{"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/comments?post=607"}],"version-history":[{"count":4,"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/pages\/607\/revisions"}],"predecessor-version":[{"id":663,"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/pages\/607\/revisions\/663"}],"wp:attachment":[{"href":"https:\/\/www.unioviedo.es\/TBR\/wp-json\/wp\/v2\/media?parent=607"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}