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11	Gas separation of steam and hydrogen mixtures using an α-alumina-Alumina supported NaA membrane / by S. Moodley Moodley, Shawn January 2007 (has links) In this study, the feasibility of a NaA zeolite membrane for the gas phase separation of steam and hydrogen mixtures was determined. The Fischer-Tropsch (FT) process, which produces high value fuels and chemicals from coal and natural gas, can be greatly improved upon by the selective removal of water from the FT reactor product stream. According to the FT reaction kinetics, the rate of reaction increases with the partial pressure of hydrogen but is adversely affected the presence of water in the reactor product stream. Chemisorbed water on the surface of the metal catalysts also enhances deactivation due to sintering and fouling. The use of a zeolite membrane reactor is well equipped to serve the purpose of in-situ water removal as it can facilitate the separation of chemical components from one another in the presence of catalytic reactions. The LTA type zeolite membrane NaA or zeolite 4A, in particular, is well suited for the separation of polar (H2O) from non-polar (H2) molecules because of its high hydrophilicity. NaA has also been identified as an excellent candidate for selective water removal applications due its high adsorption affinity and capacity for water. The NaA membrane used in this study was manufactured by means of the in-situ crystallisation method where the growth of crystals on the inside surface of a centrifugally casted a-alumina support was favoured. Scanning electron microscopy (SEM) analyses performed on the membrane after a double hydrothermal synthesis indicated that the surface topology was rough and that the zeolite crystals formed were not uniform in size. Overall, the membrane thickness varied between 6.5 and 8.0 flm. An evaluation of the membrane quality was made possible through permeation experiments involving SF6 and Hz. The calculated Hz/SF6 permselectivity in this study was found to be 9.78, which despite being higher than the Knudsen diffusion selectivity of 8.54, confirmed the presence of intercrystalline defects or non-zeolitic pores in the membrane. Experiments concerning pure component and binary mixture permeation of steam and hydrogen through the supported NaA membrane were conducted over a temperature range of 115°C to 160 °c for binary hydrogen/steam mixtures, 25°C to 160°C for pure hydrogen and 130°C to 170°C for pure steam. For the permeation of pure component hydrogen, a local maximum in its permeance having a value of 224 x 10'°8 mol.m,z.s'!.Pa'! was reached at a system pressure and temperature of 6.875 bar and 75°C respectively. For the permeation of pure component steam through NaA, the effects of capillary condensation in the pores and defects of the zeolite membrane resulted in a decrease in steam permeance as a function of absolute pressure for temperatures lower than 160 °c. Once the effects of capillary condensation had receded, maxima in the steam permeances as a function of temperature corresponding to values of 70 x 10,08, 65 X 10,08 and 75 x 10,08 mol.m•2.s'I.Pa'l were found for the 182.5, 197.5 and 222.5 kPa isobars respectively. These observations collaborated well with the description of surface diffusion with permeation taking place in the Langmuir (strong adsorption) regime. Permeation experiments through NaA as function of temperature were conducted for a 90 mol% steam -10 mol% hydrogen (90-10) binary mixture as well as for a 60-40 mixture of these two. At low temperatures the permeation of hydrogen was completely suppressed by the condensed steam resulting in an almost perfect separation. The Kelvin equation was used to estimate the pore size of the defects which was found to range between 1.86 and 2.45 nm. The temperature range over which these defects in the membrane were assumed to become unblocked (i.e. assuming when the first breakthrough of hydrogen occurred), were determined to be between 140 to 148 °c and between 128 to 130 °c for the 90-10 and 60-40 mixtures respectively. The mixture selectivities (towards water) between 115 °c and 130 °c were found to be immensely high (much greater than 1000) for both the 90-10 and 60-40 mixtures, while the ideal selectivities were calculated to be less than lover the same temperature range. At 140 °c, the selectivity towards water for the 9010 mixture was still greater than 1000; however for the 60-40 mixture at this temperature, an inversion of selectivity towards H2 had already taken place. The breakthrough in H2 permeance occurs at a much lower temperature when the feed mixture contains a lower concentration of water. Since the partial pressure of steam will be reduced, larger pores will become unblocked at lower temperatures according to the Kelvin equation. / Thesis (M. Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2008. Fischer-Tropsch (FT) NaA zeolite membrane In-situ crystallisation Double hydrothermal synthesis α-alumina support Capillary condensation Kelvin equation
12	Gas separation of steam and hydrogen mixtures using an α-alumina-Alumina supported NaA membrane / by S. Moodley Moodley, Shawn January 2007 (has links) In this study, the feasibility of a NaA zeolite membrane for the gas phase separation of steam and hydrogen mixtures was determined. The Fischer-Tropsch (FT) process, which produces high value fuels and chemicals from coal and natural gas, can be greatly improved upon by the selective removal of water from the FT reactor product stream. According to the FT reaction kinetics, the rate of reaction increases with the partial pressure of hydrogen but is adversely affected the presence of water in the reactor product stream. Chemisorbed water on the surface of the metal catalysts also enhances deactivation due to sintering and fouling. The use of a zeolite membrane reactor is well equipped to serve the purpose of in-situ water removal as it can facilitate the separation of chemical components from one another in the presence of catalytic reactions. The LTA type zeolite membrane NaA or zeolite 4A, in particular, is well suited for the separation of polar (H2O) from non-polar (H2) molecules because of its high hydrophilicity. NaA has also been identified as an excellent candidate for selective water removal applications due its high adsorption affinity and capacity for water. The NaA membrane used in this study was manufactured by means of the in-situ crystallisation method where the growth of crystals on the inside surface of a centrifugally casted a-alumina support was favoured. Scanning electron microscopy (SEM) analyses performed on the membrane after a double hydrothermal synthesis indicated that the surface topology was rough and that the zeolite crystals formed were not uniform in size. Overall, the membrane thickness varied between 6.5 and 8.0 flm. An evaluation of the membrane quality was made possible through permeation experiments involving SF6 and Hz. The calculated Hz/SF6 permselectivity in this study was found to be 9.78, which despite being higher than the Knudsen diffusion selectivity of 8.54, confirmed the presence of intercrystalline defects or non-zeolitic pores in the membrane. Experiments concerning pure component and binary mixture permeation of steam and hydrogen through the supported NaA membrane were conducted over a temperature range of 115°C to 160 °c for binary hydrogen/steam mixtures, 25°C to 160°C for pure hydrogen and 130°C to 170°C for pure steam. For the permeation of pure component hydrogen, a local maximum in its permeance having a value of 224 x 10'°8 mol.m,z.s'!.Pa'! was reached at a system pressure and temperature of 6.875 bar and 75°C respectively. For the permeation of pure component steam through NaA, the effects of capillary condensation in the pores and defects of the zeolite membrane resulted in a decrease in steam permeance as a function of absolute pressure for temperatures lower than 160 °c. Once the effects of capillary condensation had receded, maxima in the steam permeances as a function of temperature corresponding to values of 70 x 10,08, 65 X 10,08 and 75 x 10,08 mol.m•2.s'I.Pa'l were found for the 182.5, 197.5 and 222.5 kPa isobars respectively. These observations collaborated well with the description of surface diffusion with permeation taking place in the Langmuir (strong adsorption) regime. Permeation experiments through NaA as function of temperature were conducted for a 90 mol% steam -10 mol% hydrogen (90-10) binary mixture as well as for a 60-40 mixture of these two. At low temperatures the permeation of hydrogen was completely suppressed by the condensed steam resulting in an almost perfect separation. The Kelvin equation was used to estimate the pore size of the defects which was found to range between 1.86 and 2.45 nm. The temperature range over which these defects in the membrane were assumed to become unblocked (i.e. assuming when the first breakthrough of hydrogen occurred), were determined to be between 140 to 148 °c and between 128 to 130 °c for the 90-10 and 60-40 mixtures respectively. The mixture selectivities (towards water) between 115 °c and 130 °c were found to be immensely high (much greater than 1000) for both the 90-10 and 60-40 mixtures, while the ideal selectivities were calculated to be less than lover the same temperature range. At 140 °c, the selectivity towards water for the 9010 mixture was still greater than 1000; however for the 60-40 mixture at this temperature, an inversion of selectivity towards H2 had already taken place. The breakthrough in H2 permeance occurs at a much lower temperature when the feed mixture contains a lower concentration of water. Since the partial pressure of steam will be reduced, larger pores will become unblocked at lower temperatures according to the Kelvin equation. / Thesis (M. Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2008. Fischer-Tropsch (FT) NaA zeolite membrane In-situ crystallisation Double hydrothermal synthesis α-alumina support Capillary condensation Kelvin equation
13	Síntese de membranas zeolíticas (ZSM-5/y-ALUMINA e ZSM-5/a-ALUMINA) por Pore-Plugging para permeação de gás N2. / Synthesis of zeolite membranes (ZSM-5 / y-ALUMINA and ZSM-5 / a-ALUMINA) by Pore-Plugging for N2 gas permeation SCHEIBLER, Janaina Rafaella. 23 March 2018 (has links) Submitted by Johnny Rodrigues (johnnyrodrigues@ufcg.edu.br) on 2018-03-23T18:44:54Z No. of bitstreams: 1 JANAINA RAFAELLA SCHEIBLER - DISSERTAÇÃO PPGEQ 2015..pdf: 2465420 bytes, checksum: cbecc726b67d3d76a334570b655735eb (MD5) / Made available in DSpace on 2018-03-23T18:44:54Z (GMT). No. of bitstreams: 1 JANAINA RAFAELLA SCHEIBLER - DISSERTAÇÃO PPGEQ 2015..pdf: 2465420 bytes, checksum: cbecc726b67d3d76a334570b655735eb (MD5) Previous issue date: 2015 / Entre as membranas inorgânicas microporosas, as membranas zeolíticas constituem uma tecnologia promissora, devido às suas potenciais aplicações normalmente na desidratação do álcool, separação de moléculas de gás, separação de isômeros ou em processos químicos, incluindo reações de esterificação. Sob este aspecto, torna-se imprescindível o estudo das rotas de preparação desses materiais, visando desenvolver produtos com qualidade e a baixo custo. Portanto, a inovação deste estudo se dá na síntese de membranas zeolíticas via método de síntese poreplugging visando a utilização das membranas inorgânicas para permeação gasosa de N2. Neste trabalho foram desenvolvidos os seguintes materiais: zeólita ZSM-5, membranas cerâmicas (γ-alumina e α-alumina) e as membranas zeolíticas (ZSM5/γ-alumina e ZSM-5/α-alumina). A zeólita ZSM-5 foi sintetizada por meio do método hidrotérmico. As membranas cerâmicas (γ-alumina e α-alumina) foram preparadas a partir da técnica de conformação de pós cerâmicos e posteriormente submetidas à sinterização a uma temperatura de 1000 ºC/1h e 1200 ºC/1h respectivamente. A preparação das membranas zeolíticas (ZSM-5/γ-alumina e ZSM-5/α-alumina) foi realizada com base no método pore in plugging. As amostras foram caracterizadas a partir das técnicas de difração de raios X e Microscopia Eletrônica de Varredura. Os resultados experimentais permitem diversas conclusões acerca do desenvolvimento dos materiais: zeólita ZSM-5, membranas cerâmicas (γ-alumina e α-alumina) e membranas zeolíticas (ZSM-5/γ-alumina e ZSM-5/α-alumina). A partir da difração de raios X, foi possível verificar que o método de síntese empregado, foi efetivo na obtenção da zeólita ZSM-5. O difratograma apresentou picos característicos de uma zeólita ZSM-5 quando comparada ao padrão. Os resultados obtidos por DRX para as membranas cerâmicas (γ-alumina e α-alumina) demonstraram a formação de picos característicos do óxido de alumínio, os materiais são cristalinos e puros. Para o método pore-plugging pode se dizer que é um método promissor, pois mostrou uma formação satisfatória da camada zeolítica no resultado do DRX de ambas as membranas zeolíticas (ZSM-5/γ-alumina e ZSM-5/α-alumina). / Among the microporous inorganic membranes, zeolite membranes are a promising technology due to their potential applications normally in alcohol dehydration, separation of gas molecules, separation of isomers or chemical processes, including esterification reactions. In this regard, it is essential to study the preparation of these materials routes in order to develop products with quality and low cost. Therefore, innovation of this study gives the synthesis of zeolite membranes via pore-plugging synthesis method aimed at the use of inorganic membranes for gas permeation N2. In this work the following materials were developed: ZSM-5 zeolite, ceramic membranes (γ-alumina and α-alumina) and zeolitic membranes (ZSM-5/γ-alumina and ZSM-5/α-alumina). Zeolite ZSM-5 was synthesized by the hydrothermal method. Ceramic membranes (γ-alumina and α-alumina) were prepared from the ceramic powder forming technique, and subsequently subjected to a sintering temperature of 1000 °C/1h and 1200 °C/1h respectively. The preparation of zeolite membranes (ZSM-5/γ-alumina and ZSM-5/α-alumina) was carried out based on the method in pore plugging. The samples were characterized from the techniques of X diffraction and scanning electron microscopy rays. The experimental results allow several conclusions about the development of materials: zeolite ZSM-5, ceramic membranes (γ-alumina and α-alumina) and zeolite membranes (ZSM-5/γ-alumina and ZSM-5/αalumina). From the X-ray diffraction, it found that the method of synthesis used was effective in obtaining the zeolite ZSM-5. The XRD pattern showed peaks characteristic of ZSM-5 compared to the standard. The results obtained by XRD ceramic membranes (γ-alumina and α-alumina) showed the formation of peaks characteristic of aluminum oxide, the materials are crystalline and pure. For the poreplugging method can be said to be a promising method because it showed a satisfactory formation of the zeolite layer on the result of XRD both zeolite membranes (ZSM-5/γ-alumina and ZSM-5/α-alumina). Engenharia Química. ZSM-5 Membrana zeolítica γ-alumina α-alumina Permeação gasosa de N2 Zeolite membrane N2 gas permeation
14	Studies on Ion Transport in Mesoporous and Microporous Inorganic Membranes as Ion Separators for Redox Flow Batteries Michos, Ioannis 30 May 2017 (has links) No description available. Chemical Engineering zeolite membrane redox flow battery ZSM-5 membrane renewable energy iron-chromium redox flow battery
15	S?ntese e caracteriza??o de membranas zeol?ticas tipo mfi e aplica??o em separa??o de arom?ticos Rigo, Reus Tiago 22 July 2013 (has links) Made available in DSpace on 2014-12-17T15:42:06Z (GMT). No. of bitstreams: 1 ReusTR_DISSERT.pdf: 4094188 bytes, checksum: 4969fc6bf4243a6e241302a399783473 (MD5) Previous issue date: 2013-07-22 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / The synthesis of MFI-type zeolite membranes was carried by the process in situ or hydrothermal crystallization. We studied the homogenization time of the room temperature and gel filtration just before the crystallization step performed out in an oven, thus obtaining a more uniform zeolite film. The powder synthesized zeolite (structure type MFI, Silicalite) was characterized by several complementary techniques such as Xray diffraction (XRD), scanning electron microscopy (SEM), thermal analysis, temperature programmed desorption (TPD), Fourier Transform infrared spectroscopy (FTIR) and textural analysis by nitrogen adsorption (specific surface area). For the purpose of evaluating the quality of the layer supported on the ceramic support, N2 permeation tests were carried starting from room temperature to 600 ?C, where values were observed values more appropriate permeation from 200 ?C. With the data obtained, it was made into a graph of temperature versus permeation function, the curve of surface diffusion was found. For scanning electron microscopy, we observed the formation of homogeneous crystals and the zeolite film showed no fissures or cracks, indicating that the process of synthesis and subsequent treatments not damaged the zeolite layer on the support. Carried permeation studies were found values ranging from 3.64x10-6 to 3.78x10-6, 4.71x10-6 to 5.02x10-6, to pressures 20 and 25 psi, respectively. And the mixture xylenes/N2 values were between 5.39x10-6 to 5.67x10-6 and 8.13x10-6 to 8.36x10-6, also for pressures of 20 and 25 psi. The values found for the separation factor were 15.22 at 400 ?C in the first experiment and 1.64 for the second experiment at a temperature of 150 ?C. It is concluded that the Silicalite membrane was successfully synthesized and that it is effective in the separation of binary mixtures of xylenes / A s?ntese de membranas zeol?ticas do tipo MFI foi realizada pelo processo de cristaliza??o in situ ou hidrot?rmica. Foi estudado o tempo de homogeneiza??o do gel em temperatura ambiente e filtra??o do mesmo antes da etapa de cristaliza??o efetuada em estufa, obtendo-se um filme zeol?tico uniforme. O p? da ze?lita sintetizada (estrutura tipo MFI, Silicalita) foi caracterizado por diversas t?cnicas complementares, como: difra??o de raios X (DRX), microscopia eletr?nica de varredura (MEV), an?lise t?rmica, dessor??o a temperatura programada (TPD), infravermelho por transformada de Fourier (FTIR) e an?lise textural por adsor??o de nitrog?nio (?rea espec?fica). Com a finalidade de avaliar a qualidade da camada suportada sobre o suporte cer?mico, testes de permea??o com N2 foram efetuados partindo da temperatura ambiente at? 600 ?C, onde foram observados valores mais adequados de permea??o a partir dos 200 ?C. Com os dados obtidos confeccionou-se um gr?fico em fun??o da temperatura versus a permea??o, a curva encontrada foi de difus?o superficial. Por microscopia eletr?nica de varredura, observouse a forma??o de cristais homog?neos e que o filme zeol?tico n?o apresentava fissuras ou rachaduras, indicando que o processo de s?ntese e tratamentos posteriores n?o danificaram a camada de ze?lita sobre o suporte. Realizando estudos de permea??o foram verificados valores que variam entre 3,64x10-6 a 3,78x10-6 e 4,71x10-6 a 5,02x10-6, para press?es de 20 e 25 psi, respectivamente. Para a mistura xilenos/N2 os valores foram de 5,39x10-6 a 5,67x10-6 e 8,13x10-6 a 8,36x10-6, tamb?m para press?es de 20 e 25 psi. Os valores encontrados para o fator de separa??o foram de 15,22 em 400 ?C no primeiro experimento e 1, 64 para o segundo experimento em uma temperatura de 150 ?C. Conclui-se que a membrana Silicalita foi sintetizada com sucesso e que a mesma ? efetiva na separa??o de misturas bin?rias de xilenos
16	Herstellung und Charakterisierung von Kompositmembranen aus seitlich von einer Polymermatrix eingefassten Zeolithpartikeln Kiesow, Ina 23 March 2012 (has links) (PDF) Für die hochselektive technische Trennung von Stoffen hält die Natur eine optimale Lösung namens Zeolithe bereit. In dieser Arbeit wurden Zeolith 4A in Form von Partikeln und wenig permeables Polymer in einer Membran kombiniert. Die Partikel lagen dabei in einer Monolage vor und wurden lediglich seitlich vom Polymer eingefasst, sodass sie beide Oberflächen der Polymerschicht durchbrachen. Diese Einbettung zu so genannten Zeolithkompositmembranen erlaubt einen Stofftransport ausschließlich durch die hochselektiven Zeolithpartikel. Die Herstellung und Charakterisierung der Zeolithkompositmembranen stehen im Mittelpunkt der vorliegenden Arbeit. Für die Membranherstellung kam das Prinzip der partikelassistierten Benetzung einer Wasseroberfläche zum Einsatz. Hierfür wurden die Zeolithpartikel beschichtet und anschließend das unverändert zugängliche Porensystem mittels Thermogravimetrie in Wasseradsorptions-Desorptionsmessungen nachgewiesen. Aus beschichteten Partikeln und passendem Monomer konnten schichtdickenoptimierte Zeolithkompositmembranen hergestellt werden. Es wurde eine Permeabilität P für Wasserdampf von 49 barrer festgestellt, während die Gase Stickstoff und Sauerstoff keinen Transportnachweis zuließen (P < 0,03 barrer). Daraus ergeben sich Selektivitäten von über 1600. Die Durchlässigkeit für Wasser beweist ein offenes Porensystem, die Impermeabilität für Stickstoff und Sauerstoff deutet auf eine sehr geringe Defektdichte hin, was beste Voraussetzungen für Trennmembranen darstellt. Das Herstellungsprinzip soll als Vorlage für die Präparation maßgeschneiderter Kompositmembranen mit wählbarer Porengröße dienen. Vergleiche zu konventionellen Zeolithmembranen belegen, dass die partikelassistierte Benetzung die Methode der Wahl ist, partikelförmiges hochselektives Material optimal einzubetten, ohne die begehrten Permeationseigenschaften zu beeinträchtigen. / An optimal material for highly selective separation processes can be found in zeolites. We prepared composite membranes composed of zeolite 4A particles and a polymer of low permeability. The particles formed a dense monolayer which were embedded into the polymer sheet in such a way that each particle prenetrates both the top and the bottom surface of the sheet. Only this embedding offffers a transport through the highly selective particles exclusively. This work focusses on these so called zeolite composite membranes, on their preparation and characterization. The preparation of the membranes was done via particle assisted wetting on a water surface. Therefore the zeolite particles were coated by a suitable silane agent and a blocking of the pore openings by the coating process was disproved by water adsorption-desorption measurements via TGA. Using the coated particles and a suitable monomer composite membranes could be formed and the optimum thickness was found. The membranes were permeable for water vapor (permeability P = 49 barrer), but impermeable for nitrogen and oxygene (P < 0,03 barrer (detection limit)). This results in a selectivity of above 1600. The permeability for water indicates that the molecules are transported through the zeolite channels. The impermeability for nitrogene and oxygene indicates a very low amount of defects. Furthermore the composite nature of the membrane reduces brittleness thus rendering it a promising candidate for separation technology with tailoring the pore size. Zeolith 4A Zeolithpartikel Zeolithmembran Kompositmembran Gaspermeation Dampfpermeation Partikelassistierte Benetzung Zeolite A Zeolite particle Zeolite membrane Composite membrane Gas separation Vapor permeation Particle assisted wetting ddc:541 Kompositmembran Trennverfahren Zeolith A
17	Síntese de membranas zeolíticas (Mordenita/α-Alumina) utilizando os métodos de síntese hidrotérmica, Dip-Coating e transporte em fase vapor e avaliação na separação emulsão óleo/água. SILVA, Fabiana Medeiros do Nascimento. 16 August 2018 (has links) Submitted by Maria Medeiros (maria.dilva1@ufcg.edu.br) on 2018-08-16T11:47:56Z No. of bitstreams: 1 FABIANA MEDEIROS DO NASCIMENTO SILVA - TESE (PPGEQ) 2017.pdf: 6622967 bytes, checksum: bfed827814b744a5e9e9e565d28f0682 (MD5) / Made available in DSpace on 2018-08-16T11:47:56Z (GMT). No. of bitstreams: 1 FABIANA MEDEIROS DO NASCIMENTO SILVA - TESE (PPGEQ) 2017.pdf: 6622967 bytes, checksum: bfed827814b744a5e9e9e565d28f0682 (MD5) Previous issue date: 2017 / Capes / O presente trabalho tem como objetivo geral sintetizar as membranas zeolíticas (Mordenita/α-alumina), utilizando os métodos de síntese hidrotérmica, crescimento secundário: dip-coating e transporte em fase vapor, para serem avaliadas no processo de separação emulsão óleo/água. Dentro deste contexto foram avaliados alguns parâmetros, destacando-se, a influência do tempo de cristalização na síntese da zeólita mordenita, a influência do precursor (sulfato de alumínio e gibsita) na síntese da membrana zeolítica, influência dos métodos de síntese das membranas zeolíticas e os testes de permeação de água e o processo de separação emulsão óleo/água. A síntese da zeólita mordenita foi realizada utilizando o método hidrotérmico a 170°C, com tempos de cristalização de 24, 36, 48, 72, 96 e 120 horas, a fim de avaliar a cristalinidade da zeólita, e selecionar o melhor tempo para a síntese das membranas zeolíticas. Os suportes cerâmicos α-alumina foram preparados a partir da decomposição dos precursores sulfato de alumínio a 1000°C e gibsita a 1200ºC por 2 horas, e conformados, compactados e sinterizados a 1300ºC por 2h, e então submetidos às técnicas de caracterização: Difratometria de raios X (DRX), Adsorção Física de Nitrogênio, Microscopia Eletrônica de Varredura (MEV), Espectroscopia de Fluorescência de raios X por Energia Dispersiva (FRX-ED) e Termogravimétrica/Térmica Diferencial (TG/DTA). As membranas zeolíticas foram sintetizadas pelos métodos de síntese hidrotérmica, crescimento secundário: dip-coating e transporte em fase vapor a 170°C por 72h e caracterizadas por DRX e MEV. Os suportes cerâmicos e as membranas zeolíticas foram avaliadas em testes de permeação de água e no sistema de separação emulsão óleo/água de um efluente sintético, utilizando um processo de separação por membrana (PSM). Os ensaios foram realizados nas condições de concentração inicial da emulsão 100 mg.L-1, temperatura de 25 °C e pressão de 2,5 bar, permitindo avaliar a permeabilidade e a seletividade a partir da variação da concentração do permeado em (mg.L-1) e da percentagem de rejeição ao óleo (%R). A partir dos resultados obtidos para a síntese dos materiais, pode-se observar a efetiva formação da zeólita mordenita em fase pura e cristalina. Os precursores foram decompostos de maneira satisfatória obtendo a fase α-alumina. A manutenção da fase α-alumina pós-produção dos suportes cerâmicos foi confirmada após caracterização. De acordo com os resultados exibidos pelas análises de DRX e MEV as membranas zeolíticas MZMOR/α-alumina apresentaram uma distribuição homogênea e uniforme dos cristais zeolíticos correspondentes à fase mordenita, sem a presença de impurezas, livres de defeitos e sem fissuras, confirmando a formação da estrutura da membrana zeolítica pelos três métodos de síntese, utilizados neste trabalho. A zeólita mordenita se mostrou excelente em relação à adesão e formação da camada zeolítica sobre o suporte cerâmico α-alumina. A partir da avaliação da permeabilidade e seletividade nos testes de separação da emulsão óleo/água, pode-se concluir que a inserção da zeólita mordenita aos suportes cerâmicos melhorou o processo de separação da emulsão óleo/água. Em termos de eficiência no processo de separação, considera-se que a membrana zeolítica MZMOR/α – Al2O3 (SHGB) foi a que apresentou melhor relação entre fluxo e capacidade seletiva, mostrando a eficácia da utilização das membranas zeolíticas. Todas as membranas zeolíticas sintetizadas e avaliadas mostraram-se promissoras. / The objective of the present work is to synthesize zeolite membranes (Mordenite/α-alumina) using hydrothermal synthesis, secondary growth: dip-coating and vapor-phase transport, to be evaluated in the oil/water emulsion separation process. The influence of the crystallization time on the synthesis of the mordenite zeolite, the influence of the precursor (aluminum sulphate and gibsite) on the synthesis of the zeolite membrane, influence of the synthesis methods of the zeolite membranes and the water permeation tests and the oil/water emulsion separation process. The synthesis of the mordenite zeolite was performed using the hydrothermal method at 170°C, with crystallization times of 24, 36, 48, 72, 96 and 120 hours, in order to evaluate the crystallinity of the zeolite, and to select the best time for the synthesis of zeolite membranes. The α-alumina ceramic supports were prepared from the decomposition of the aluminum sulfate precursors at 1000°C and gibsite at 1200°C for 2 hours, and conformed, compacted and sintered at 1300°C for 2h, and then submitted to the characterization techniques: (XRD), Nitrogen Physical Adsorption, Scanning Electron Microscopy (SEM), X-ray Fluorescence Spectroscopy (FRX-ED) and Thermogravimetric/Differential Thermal (TG/DTA). The zeolite membranes were synthesized by hydrothermal synthesis, secondary growth: dip-coating and vapor-phase transport at 170°C for 72 hours and characterized by XRD and SEM. Ceramic supports and zeolite membranes were evaluated in water permeation tests and in the oil/water emulsion separation system of a synthetic effluent using a membrane separation process. The tests were carried out under the conditions of initial concentration of the emulsion 100 mg.L-1, temperature of 25°C and pressure of 2,5 bar, allowing to evaluate the permeability and the selectivity from the variation of the permeate concentration in (mg. L-1) and the percentage of oil rejection (% R). From the results obtained for the synthesis of the materials, it is possible to observe the effective formation of zeolite mordenite in pure and crystalline phase. The precursors were satisfactorily decomposed to give the α-alumina phase. The maintenance of the post-production α-alumina phase of the ceramic supports was confirmed after characterization. The MZMOR/α-alumina zeolite membranes presented a homogeneous and uniform distribution of the zeolite crystals corresponding to the mordenite phase, without the presence of impurities, free of defects and without cracks, confirming the formation of the structure of the zeolite membrane by the three methods of synthesis, used in this work. The mordenite zeolite showed excellent adhesion and formation of the zeolitic layer on the ceramic support α-alumina. From the evaluation of the permeability and selectivity in the oil/water emulsion separation tests, it can be concluded that the insertion of the mordenite zeolite to the ceramic supports improved the separation process of the oil/water emulsion. In terms of efficiency in the separation process, the zeolite membrane MZMOR/α-Al2O3(SHGB) was considered to have the best relationship between flow and selectivity, showing the efficacy of zeolite membranes. All zeolite membranes synthesized and evaluated were promising. Engenharia Química Membrana Zeolítica MOR/α-Alumina Sulfato de Alumínio Gibsita Síntese Hidrotérmica Dip-Coating Transporte em Fase Vapor Emulsão Óleo/Água MOR/α-Alumina Zeolite Membrane Aluminum Sulfate Gibsite Hydrothermal Synthesis Vapor - Phase Transport Oil/Water Emulsion
18	Herstellung und Charakterisierung von Kompositmembranen aus seitlich von einer Polymermatrix eingefassten Zeolithpartikeln Kiesow, Ina 24 February 2012 (has links) Für die hochselektive technische Trennung von Stoffen hält die Natur eine optimale Lösung namens Zeolithe bereit. In dieser Arbeit wurden Zeolith 4A in Form von Partikeln und wenig permeables Polymer in einer Membran kombiniert. Die Partikel lagen dabei in einer Monolage vor und wurden lediglich seitlich vom Polymer eingefasst, sodass sie beide Oberflächen der Polymerschicht durchbrachen. Diese Einbettung zu so genannten Zeolithkompositmembranen erlaubt einen Stofftransport ausschließlich durch die hochselektiven Zeolithpartikel. Die Herstellung und Charakterisierung der Zeolithkompositmembranen stehen im Mittelpunkt der vorliegenden Arbeit. Für die Membranherstellung kam das Prinzip der partikelassistierten Benetzung einer Wasseroberfläche zum Einsatz. Hierfür wurden die Zeolithpartikel beschichtet und anschließend das unverändert zugängliche Porensystem mittels Thermogravimetrie in Wasseradsorptions-Desorptionsmessungen nachgewiesen. Aus beschichteten Partikeln und passendem Monomer konnten schichtdickenoptimierte Zeolithkompositmembranen hergestellt werden. Es wurde eine Permeabilität P für Wasserdampf von 49 barrer festgestellt, während die Gase Stickstoff und Sauerstoff keinen Transportnachweis zuließen (P < 0,03 barrer). Daraus ergeben sich Selektivitäten von über 1600. Die Durchlässigkeit für Wasser beweist ein offenes Porensystem, die Impermeabilität für Stickstoff und Sauerstoff deutet auf eine sehr geringe Defektdichte hin, was beste Voraussetzungen für Trennmembranen darstellt. Das Herstellungsprinzip soll als Vorlage für die Präparation maßgeschneiderter Kompositmembranen mit wählbarer Porengröße dienen. Vergleiche zu konventionellen Zeolithmembranen belegen, dass die partikelassistierte Benetzung die Methode der Wahl ist, partikelförmiges hochselektives Material optimal einzubetten, ohne die begehrten Permeationseigenschaften zu beeinträchtigen. / An optimal material for highly selective separation processes can be found in zeolites. We prepared composite membranes composed of zeolite 4A particles and a polymer of low permeability. The particles formed a dense monolayer which were embedded into the polymer sheet in such a way that each particle prenetrates both the top and the bottom surface of the sheet. Only this embedding offffers a transport through the highly selective particles exclusively. This work focusses on these so called zeolite composite membranes, on their preparation and characterization. The preparation of the membranes was done via particle assisted wetting on a water surface. Therefore the zeolite particles were coated by a suitable silane agent and a blocking of the pore openings by the coating process was disproved by water adsorption-desorption measurements via TGA. Using the coated particles and a suitable monomer composite membranes could be formed and the optimum thickness was found. The membranes were permeable for water vapor (permeability P = 49 barrer), but impermeable for nitrogen and oxygene (P < 0,03 barrer (detection limit)). This results in a selectivity of above 1600. The permeability for water indicates that the molecules are transported through the zeolite channels. The impermeability for nitrogene and oxygene indicates a very low amount of defects. Furthermore the composite nature of the membrane reduces brittleness thus rendering it a promising candidate for separation technology with tailoring the pore size. info:eu-repo/classification/ddc/541 ddc:541

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