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1	Einfluss intermetallischer Phasen der Systeme Al-Cu und Al-Ag auf den Widerstand stromtragender Verbindungen im Temperaturbereich von 90 °C bis 200 °C Pfeifer, Stephanie 27 October 2016 (has links) (PDF) Im Netz der Elektroenergieversorgung werden einzelne Netzkomponenten und Betriebsmittel durch Verbindungen elektrisch zusammengeschaltet. Dabei werden häufig Schraubenverbindungen mit Stromschienen eingesetzt. Diese müssen über mehrere Jahrzehnte zuverlässig hohe Ströme tragen können. Abhängig von der sich einstellenden Temperatur an den Verbindungen altern diese mit der Zeit. Die Alterung wird je nach Verbindungssystem von verschiedenen Mechanismen beeinflusst, die alle parallel ablaufen. Bei ruhenden, stationären elektrotechnischen Verbindungen, deren Kontaktpartner aus verschiedenen Materialien bestehen, können abhängig von der Paarung intermetallische Phasen (IMP) entstehen. Die sich bildenden IMP haben schlechtere elektrische und mechanische Eigenschaften als die reinen Metalle. Daraus resultiert ein höherer Verbindungswiderstand. Die erzeugte Verlustleistung sowie die Temperatur der Verbindung steigen an. Dies kann zum Ausfall der Verbindung führen. In der Elektroenergietechnik werden aufgrund ihrer guten elektrischen Leitfähigkeit häufig die Werkstoffe Aluminium und Kupfer sowie das Beschichtungsmetall Silber bei Temperaturen von üblicherweise 90 °C bis 200 °C eingesetzt. Speziell bei Aluminium-Kupfer-Verbindungen, die nicht langzeitstabil sind, wird als maßgebliche Ausfallursache das Bilden von IMP gesehen. Die IMP des Systems Al-Cu wurden in der Vergangenheit bereits vielfach untersucht. Das Übertragen der Ergebnisse auf die Problematik stromtragender Verbindungen der Elektroenergietechnik ist jedoch nicht ohne Weiteres möglich. Der relevante niedrige Temperaturbereich zwischen 90 °C und 200 °C spielt bei vielen Untersuchungen nur eine untergeordnete Rolle. Zusätzlich können die Eigenschaften der IMP bei unterschiedlichen Herstellungsverfahren voneinander abweichen. Zum System Al-Ag ist in der Literatur nur wenig bekannt. Deshalb wurden für diese Arbeit phasenreine IMP der Systeme Al-Cu und Al-Ag mit unterschiedlichen Herstellungsverfahren bei möglichst identischen Randbedingungen hergestellt. Diese wurden mit einer speziell für diese Proben entwickelten Messeinrichtung elektrisch charakterisiert und der ermittelte spezifische elektrische Widerstand der IMP und ihr Temperaturbeiwert mit Werten aus der Literatur verglichen. An verschiedenen Schraubenverbindungen mit Stromschienen aus Aluminium und Kupfer wurden Langzeitversuche von bis zu 3 Jahren durchgeführt. Der Verbindungswiderstand wurde abhängig von der Zeit ermittelt. An ausgewählten Verbindungen wurde zusätzlich in zwei identischen Versuchen der Einfluss der Belastung mit Dauer- und Wechsellast auf das Langzeitverhalten untersucht. Mithilfe der an den IMP ermittelten elektrischen Eigenschaf-ten wurde deren Einfluss auf den Verbindungswiderstand berechnet. Die Ergebnisse dieser Modellrechnung wurden mit den Ergebnissen aus den Langzeitversuchen verglichen. Ausgewählte Verbindungen wurden dazu mikroskopisch untersucht. Es wurde festgestellt, dass die IMP nicht ausschließlich das Langzeitverhalten stromtragender Verbindungen bestimmen. Es muss mindestens ein weiterer Alterungsmechanismus einen signifikanten Einfluss haben. Die Untersuchungen deuten darauf hin, dass dabei Sauerstoff eine zentrale Rolle spielen könnte. / In electrical power supply networks a huge number of electrical joints are used to connect transmission lines, conductors, switchgears and other components. During operation these joints are aging due to different aging mechanisms. Depending on the type of the joint several aging mechanisms can take place at the same time. For stationary joints with contact partners made of different materials, the formation of intermetallic compounds (IMC) may be an issue. These IMC have worse electrical and mechanical properties compared to the pure metals. Therefore, the presence of IMC in the contact area results in a higher joint re-sistance and the temperature and the thermal power losses increase. Typical temperatures for high current joints are between 90 °C and 200 °C. Due to their good electrical conductivity aluminum and copper are often used as conductor materials and silver as a coating material. Especially bimetal joints made of aluminum and copper are not long term stable. The formation of Al-Cu IMC is held responsible as a cause of failure. The IMC of the System Al-Cu have already been studied by several authors. However, it is difficult to apply the results directly to electrical joints in power supply networks. In many studies the low temperature range between 90 °C and 200 °C is not regarded. In addition, the properties of the IMC may vary due to different preparation processes. There is only little information about the system Al-Ag in the literature. For this work, phase pure IMC of the systems Al-Cu and Al-Ag were prepared by different preparation processes using similar process parameters. These IMC samples were electrically characterized with a specially developed measuring device. The specific electric resistivity and the temperature coefficient of resistance were determined and compared to values taken from the literature. Various combinations of bus bar joints made of aluminum and copper were investigated in long term tests for up to three years. The joint resistance was determined as a function of time. In addition, for selected joints two identic setups were operated with continuous load and alternating load. The long term behavior was investigated with regard to the load ap-plied. Using the results of the electrical characterization of the IMC their influence on the joint resistance was calculated theoretically. The results of the calculation were compared to the results determined in the long term tests. Selected joints were examined microscopi-cally after termination of the long term tests. It was found, that the long term behavior of bimetal electrical joints with the combination Al-Cu and Al-Ag cannot be exclusively described by the growth of IMC. At least there is one further aging mechanism involved. The studies suggest, that oxygen may have a significant influence. stromtragende Verbindungen Elektroenergietechnik Intermetallische Phasen Al-Cu Al-Ag Kupfer-Aluminium Aluminium-Silber Verbindungswiderstand Langzeitverhalten electrical contacts intermetallics Al-Cu Al-Ag copper aluminum silver joint-resistance long-term behaviour ddc:621.3 rvk:ZN 8100
2	Einfluss intermetallischer Phasen der Systeme Al-Cu und Al-Ag auf den Widerstand stromtragender Verbindungen im Temperaturbereich von 90 °C bis 200 °C Pfeifer, Stephanie 26 October 2015 (has links) Im Netz der Elektroenergieversorgung werden einzelne Netzkomponenten und Betriebsmittel durch Verbindungen elektrisch zusammengeschaltet. Dabei werden häufig Schraubenverbindungen mit Stromschienen eingesetzt. Diese müssen über mehrere Jahrzehnte zuverlässig hohe Ströme tragen können. Abhängig von der sich einstellenden Temperatur an den Verbindungen altern diese mit der Zeit. Die Alterung wird je nach Verbindungssystem von verschiedenen Mechanismen beeinflusst, die alle parallel ablaufen. Bei ruhenden, stationären elektrotechnischen Verbindungen, deren Kontaktpartner aus verschiedenen Materialien bestehen, können abhängig von der Paarung intermetallische Phasen (IMP) entstehen. Die sich bildenden IMP haben schlechtere elektrische und mechanische Eigenschaften als die reinen Metalle. Daraus resultiert ein höherer Verbindungswiderstand. Die erzeugte Verlustleistung sowie die Temperatur der Verbindung steigen an. Dies kann zum Ausfall der Verbindung führen. In der Elektroenergietechnik werden aufgrund ihrer guten elektrischen Leitfähigkeit häufig die Werkstoffe Aluminium und Kupfer sowie das Beschichtungsmetall Silber bei Temperaturen von üblicherweise 90 °C bis 200 °C eingesetzt. Speziell bei Aluminium-Kupfer-Verbindungen, die nicht langzeitstabil sind, wird als maßgebliche Ausfallursache das Bilden von IMP gesehen. Die IMP des Systems Al-Cu wurden in der Vergangenheit bereits vielfach untersucht. Das Übertragen der Ergebnisse auf die Problematik stromtragender Verbindungen der Elektroenergietechnik ist jedoch nicht ohne Weiteres möglich. Der relevante niedrige Temperaturbereich zwischen 90 °C und 200 °C spielt bei vielen Untersuchungen nur eine untergeordnete Rolle. Zusätzlich können die Eigenschaften der IMP bei unterschiedlichen Herstellungsverfahren voneinander abweichen. Zum System Al-Ag ist in der Literatur nur wenig bekannt. Deshalb wurden für diese Arbeit phasenreine IMP der Systeme Al-Cu und Al-Ag mit unterschiedlichen Herstellungsverfahren bei möglichst identischen Randbedingungen hergestellt. Diese wurden mit einer speziell für diese Proben entwickelten Messeinrichtung elektrisch charakterisiert und der ermittelte spezifische elektrische Widerstand der IMP und ihr Temperaturbeiwert mit Werten aus der Literatur verglichen. An verschiedenen Schraubenverbindungen mit Stromschienen aus Aluminium und Kupfer wurden Langzeitversuche von bis zu 3 Jahren durchgeführt. Der Verbindungswiderstand wurde abhängig von der Zeit ermittelt. An ausgewählten Verbindungen wurde zusätzlich in zwei identischen Versuchen der Einfluss der Belastung mit Dauer- und Wechsellast auf das Langzeitverhalten untersucht. Mithilfe der an den IMP ermittelten elektrischen Eigenschaf-ten wurde deren Einfluss auf den Verbindungswiderstand berechnet. Die Ergebnisse dieser Modellrechnung wurden mit den Ergebnissen aus den Langzeitversuchen verglichen. Ausgewählte Verbindungen wurden dazu mikroskopisch untersucht. Es wurde festgestellt, dass die IMP nicht ausschließlich das Langzeitverhalten stromtragender Verbindungen bestimmen. Es muss mindestens ein weiterer Alterungsmechanismus einen signifikanten Einfluss haben. Die Untersuchungen deuten darauf hin, dass dabei Sauerstoff eine zentrale Rolle spielen könnte. / In electrical power supply networks a huge number of electrical joints are used to connect transmission lines, conductors, switchgears and other components. During operation these joints are aging due to different aging mechanisms. Depending on the type of the joint several aging mechanisms can take place at the same time. For stationary joints with contact partners made of different materials, the formation of intermetallic compounds (IMC) may be an issue. These IMC have worse electrical and mechanical properties compared to the pure metals. Therefore, the presence of IMC in the contact area results in a higher joint re-sistance and the temperature and the thermal power losses increase. Typical temperatures for high current joints are between 90 °C and 200 °C. Due to their good electrical conductivity aluminum and copper are often used as conductor materials and silver as a coating material. Especially bimetal joints made of aluminum and copper are not long term stable. The formation of Al-Cu IMC is held responsible as a cause of failure. The IMC of the System Al-Cu have already been studied by several authors. However, it is difficult to apply the results directly to electrical joints in power supply networks. In many studies the low temperature range between 90 °C and 200 °C is not regarded. In addition, the properties of the IMC may vary due to different preparation processes. There is only little information about the system Al-Ag in the literature. For this work, phase pure IMC of the systems Al-Cu and Al-Ag were prepared by different preparation processes using similar process parameters. These IMC samples were electrically characterized with a specially developed measuring device. The specific electric resistivity and the temperature coefficient of resistance were determined and compared to values taken from the literature. Various combinations of bus bar joints made of aluminum and copper were investigated in long term tests for up to three years. The joint resistance was determined as a function of time. In addition, for selected joints two identic setups were operated with continuous load and alternating load. The long term behavior was investigated with regard to the load ap-plied. Using the results of the electrical characterization of the IMC their influence on the joint resistance was calculated theoretically. The results of the calculation were compared to the results determined in the long term tests. Selected joints were examined microscopi-cally after termination of the long term tests. It was found, that the long term behavior of bimetal electrical joints with the combination Al-Cu and Al-Ag cannot be exclusively described by the growth of IMC. At least there is one further aging mechanism involved. The studies suggest, that oxygen may have a significant influence. info:eu-repo/classification/ddc/621.3 ddc:621.3
3	Produção de estruturas porosas contendo nanopartículas de prata e silício por Melt Spinning Pérez, Isaac Rodríguez January 2015 (has links) No presente trabalho estudou-se uma nova rota para obter nanopartículas de prata e silício aleatoriamente dispersas em uma matriz nanoporosa de nanotubos de óxido de alumínio sobre alumínio. Além disso, estudou-se a aplicação deste novo material como ânodo em células a combustível alcalinas com etanol como combustível, usando a prata como catalisador na eletroxidação do etanol e da produção de H2. O processo proposto consiste na solidificação rápida mediante melt spinner de uma liga de alumínio-prata rica em alumínio (95.25% em peso de alumínio) para obter uma solução sólida supersaturada. Posteriormente foi feita uma anodização porosa em ácido oxálico e estudo eletroquímico em meio alcalino por meia hora. A morfologia da liga obtida foi caracterizada por Microscopia Eletrônica de Varredura, Difração de Raios-X, Microscopia Eletrônica de Transmissão equipado com Espectrometria de Raios X Dispersiva em Energia e avaliado o desempenho como ânodo mediante ensaios de voltametria cíclica Os resultados obtidos confirmam que o desenvolvimento de um novo processo para produzir nanopartículas cristalinas de prata com um tamanho que varia de 4 a 120 nm, com 95% delas entre 4 e 87 nm. A partir dos estudos eletroquímicos concluiu-se que a liga de Al-Ag produzida exibe um comportamento semelhante ao alumínio puro em NaOH 0.1 M e NaOH 0.1 M com 1 M de etanol. A reação entre o alumínio e o meio alcalino produz uma camada de hidrogênio que impede que a prata catalise a eletroxidação do etanol. Portanto, conclui-se que a liga de alumínio-prata produzida não é um material viável como ânodo em células a combustível alcalinas de etanol direto. Portanto, foi avaliado o método de produção de nanopartículas para uma liga Al-Si eutética (14.2% em peso). Esta liga com nanopartículas de silício apresentou um incremento no desempenho na produção de H2 de 17% comparado à liga Al-Si eutética sem o tratamento térmico. / In the present work a new route to obtain silver nanoparticles randomly dispersed in a porous Al2O3 nanotube matrix layer on aluminum was studied. Moreover, the use as an anode in alkaline fuel cells (AFC) with ethanol as combustible was studied, using the prepared surfaces as a catalyzer for the electrooxidation of ethanol. The developed process consists of the rapid solidification (quenching) through melt spinning of an aluminum-silver alloy (92.25 %wt. Al) to obtain a supersaturated solid solution, followed by a porous anodization in oxalic acid and electrochemical treatment in alkaline medium. The morphology of the alloy was characterized by Scanning Electron Microscopy, X-Ray Diffraction, Transmission Electron Microscopy and Energy Dispersive X. Ray Spectrometry and the performance of the ethanol electrooxidation was tested though cyclic voltammetry The obtained results confirm that this process produces crystalline silver nanoparticles with a size varying from 4 to 120 nm with 95% of the particles between 4 and 87 nm. The electrochemical study showed that the produced alloy exhibits a similar behavior to that of pure aluminum in the tested mediums. The reaction between the aluminum and the alkaline medium produces a gaseous hydrogen layer that impedes the catalytic action of silver on the ethanol oxidation. Moreover, it was concluded that the produced alloy is not a viable material for the use as anode for direct ethanol AFCs. Therefore, the nanoparticle production method was tested for an Al-Si near-eutectic alloy (14.2 %wt.). This alloy with silicon nanoparticles showed an increase in the performance of H2 production rate of 17% compared to that of the regular Al-Si near-eutectic alloy. Nanoparticulas Nanotubos Óxido de alumínio Produção de hidrogênio Nanoparticles Nanotubes Al-Ag alloy Al-Si alloy Melt spinner H2 production
4	Produção de estruturas porosas contendo nanopartículas de prata e silício por Melt Spinning Pérez, Isaac Rodríguez January 2015 (has links) No presente trabalho estudou-se uma nova rota para obter nanopartículas de prata e silício aleatoriamente dispersas em uma matriz nanoporosa de nanotubos de óxido de alumínio sobre alumínio. Além disso, estudou-se a aplicação deste novo material como ânodo em células a combustível alcalinas com etanol como combustível, usando a prata como catalisador na eletroxidação do etanol e da produção de H2. O processo proposto consiste na solidificação rápida mediante melt spinner de uma liga de alumínio-prata rica em alumínio (95.25% em peso de alumínio) para obter uma solução sólida supersaturada. Posteriormente foi feita uma anodização porosa em ácido oxálico e estudo eletroquímico em meio alcalino por meia hora. A morfologia da liga obtida foi caracterizada por Microscopia Eletrônica de Varredura, Difração de Raios-X, Microscopia Eletrônica de Transmissão equipado com Espectrometria de Raios X Dispersiva em Energia e avaliado o desempenho como ânodo mediante ensaios de voltametria cíclica Os resultados obtidos confirmam que o desenvolvimento de um novo processo para produzir nanopartículas cristalinas de prata com um tamanho que varia de 4 a 120 nm, com 95% delas entre 4 e 87 nm. A partir dos estudos eletroquímicos concluiu-se que a liga de Al-Ag produzida exibe um comportamento semelhante ao alumínio puro em NaOH 0.1 M e NaOH 0.1 M com 1 M de etanol. A reação entre o alumínio e o meio alcalino produz uma camada de hidrogênio que impede que a prata catalise a eletroxidação do etanol. Portanto, conclui-se que a liga de alumínio-prata produzida não é um material viável como ânodo em células a combustível alcalinas de etanol direto. Portanto, foi avaliado o método de produção de nanopartículas para uma liga Al-Si eutética (14.2% em peso). Esta liga com nanopartículas de silício apresentou um incremento no desempenho na produção de H2 de 17% comparado à liga Al-Si eutética sem o tratamento térmico. / In the present work a new route to obtain silver nanoparticles randomly dispersed in a porous Al2O3 nanotube matrix layer on aluminum was studied. Moreover, the use as an anode in alkaline fuel cells (AFC) with ethanol as combustible was studied, using the prepared surfaces as a catalyzer for the electrooxidation of ethanol. The developed process consists of the rapid solidification (quenching) through melt spinning of an aluminum-silver alloy (92.25 %wt. Al) to obtain a supersaturated solid solution, followed by a porous anodization in oxalic acid and electrochemical treatment in alkaline medium. The morphology of the alloy was characterized by Scanning Electron Microscopy, X-Ray Diffraction, Transmission Electron Microscopy and Energy Dispersive X. Ray Spectrometry and the performance of the ethanol electrooxidation was tested though cyclic voltammetry The obtained results confirm that this process produces crystalline silver nanoparticles with a size varying from 4 to 120 nm with 95% of the particles between 4 and 87 nm. The electrochemical study showed that the produced alloy exhibits a similar behavior to that of pure aluminum in the tested mediums. The reaction between the aluminum and the alkaline medium produces a gaseous hydrogen layer that impedes the catalytic action of silver on the ethanol oxidation. Moreover, it was concluded that the produced alloy is not a viable material for the use as anode for direct ethanol AFCs. Therefore, the nanoparticle production method was tested for an Al-Si near-eutectic alloy (14.2 %wt.). This alloy with silicon nanoparticles showed an increase in the performance of H2 production rate of 17% compared to that of the regular Al-Si near-eutectic alloy. Nanoparticulas Nanotubos Óxido de alumínio Produção de hidrogênio Nanoparticles Nanotubes Al-Ag alloy Al-Si alloy Melt spinner H2 production
5	Estudo da cinética de precipitação de Ag na liga Cu-7% Al-4% Ag Maia Neto, Alfredo dos Santos [UNESP] 02 1900 (has links) (PDF) Made available in DSpace on 2014-06-11T19:29:06Z (GMT). No. of bitstreams: 0 Previous issue date: 2005-02Bitstream added on 2014-06-13T19:37:59Z : No. of bitstreams: 1 maianeto_as_me_araiq.pdf: 907997 bytes, checksum: 246ee7468bbd3c17dd5762fc7651b5eb (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Neste trabalho, foi feito um estudo da cinética de precipitação da fase rica em prata, na liga Cu-7%Al-4%Ag, em peso, utilizando-se o modelo cinético isotérmico de Johnson-Mehl-Avrami e os modelos cinéticos nãoisotérmicos de Kissinger e Ozawa. A reação de precipitação da fase rica em prata foi acompanhada por medidas de variação da microdureza da liga com a temperatura de têmpera e o tempo de envelhecimento, e também por medidas de dilatometria. As fases presentes nas diversas temperaturas e tempos considerados, foram identificadas e caracterizadas por microscopia óptica e eletrônica de varredura, análise por dispersão de energias de raios X e por difratometria de raios X. Os resultados obtidos indicaram que a formação dos precipitados ricos em prata corresponde a um processo controlado por difusão da prata nos contornos de grão da matriz, no intervalo de temperaturas de 400 a 600 oC. O cálculo da energia de ativação para a formação dos precipitados, utilizando-se a equação de Johnson-Mehl-Avrami, forneceu um valor bastante próximo daquele encontrado na literatura, confirmando que o processo é controlado pela difusão da prata. O valor da energia de ativação para o crescimento dos precipitados ricos em Ag, calculado a partir de um método que considera o inverso do tempo necessário para o precipitado atingir seu tamanho máximo como proporcional à taxa de crescimento, ficou próximo daquele obtido utilizando-se a equação de Johnson-Mehl-Avrami, indicando que esse método pode ser utilizado para o cálculo da energia de ativação do processo cinético. Os valores da energia de ativação associados ao processo de precipitação de Ag, obtidos por métodos não isotérmicos, ficaram razoavelmente próximos daqueles encontrados na literatura e os valores assim obtidos associados à solubilização de Ag foram maiores do que aqueles encontrados na literatura... / In this work, the Ag-rich phase precipitation kinetics in the Cu-7wt.%Al-4wt.%Ag alloy, was studied using the Johnson-Mehl-Avrami isothermal kinetic model and the Kissinger and Ozawa non-isothermal kinetic models. The Ag-rich phase precipitation reaction was followed by microhardness changes measurements with quenching temperature and with aging time, and also by dilatometric measurements. The identification and characterization of the phases present at the considered temperatures and times were made by optical and scanning electronic microscopy, energy dispersive X-ray analysis and X-ray diffractometry. The results showed that the Ag-rich precipitates formation corresponds to a diffusion controlled process at the matrix grain boundaries, in the temperatures range from 400 to 600 oC. The activation energy value for the precipitates formation, calculated using the Johnson-Mehl-Avrami equation, is close to that found in the literature, thus confirming that the process is diffusion controlled. The activation energy value for the growing of Ag-rich precipitates, obtained considering that the inverse of the time to reach the precipitates maximum size is proportional to the growing rate, is close to that found using the Johnson-Mehl-Avrami equation, indicating that this method is useful to evaluate the activation energy for the kinetic process. The activation energy values obtained by non-isothermal methods and associated to the precipitation process were very close to those found in the literature, and the values associated to Ag dissolution were greater than those reported in the literature. This discrepancy may be associated to the presence of Al, and the Al-Ag interaction may be disturbing the diffusion process. Cinética Precipitação (Quimica) Difusão Método isotérmico Método não-isotérmico Físico-química Cu-Al-Ag alloys Non-isothermal method Isothermal method
6	Produção de estruturas porosas contendo nanopartículas de prata e silício por Melt Spinning Pérez, Isaac Rodríguez January 2015 (has links) No presente trabalho estudou-se uma nova rota para obter nanopartículas de prata e silício aleatoriamente dispersas em uma matriz nanoporosa de nanotubos de óxido de alumínio sobre alumínio. Além disso, estudou-se a aplicação deste novo material como ânodo em células a combustível alcalinas com etanol como combustível, usando a prata como catalisador na eletroxidação do etanol e da produção de H2. O processo proposto consiste na solidificação rápida mediante melt spinner de uma liga de alumínio-prata rica em alumínio (95.25% em peso de alumínio) para obter uma solução sólida supersaturada. Posteriormente foi feita uma anodização porosa em ácido oxálico e estudo eletroquímico em meio alcalino por meia hora. A morfologia da liga obtida foi caracterizada por Microscopia Eletrônica de Varredura, Difração de Raios-X, Microscopia Eletrônica de Transmissão equipado com Espectrometria de Raios X Dispersiva em Energia e avaliado o desempenho como ânodo mediante ensaios de voltametria cíclica Os resultados obtidos confirmam que o desenvolvimento de um novo processo para produzir nanopartículas cristalinas de prata com um tamanho que varia de 4 a 120 nm, com 95% delas entre 4 e 87 nm. A partir dos estudos eletroquímicos concluiu-se que a liga de Al-Ag produzida exibe um comportamento semelhante ao alumínio puro em NaOH 0.1 M e NaOH 0.1 M com 1 M de etanol. A reação entre o alumínio e o meio alcalino produz uma camada de hidrogênio que impede que a prata catalise a eletroxidação do etanol. Portanto, conclui-se que a liga de alumínio-prata produzida não é um material viável como ânodo em células a combustível alcalinas de etanol direto. Portanto, foi avaliado o método de produção de nanopartículas para uma liga Al-Si eutética (14.2% em peso). Esta liga com nanopartículas de silício apresentou um incremento no desempenho na produção de H2 de 17% comparado à liga Al-Si eutética sem o tratamento térmico. / In the present work a new route to obtain silver nanoparticles randomly dispersed in a porous Al2O3 nanotube matrix layer on aluminum was studied. Moreover, the use as an anode in alkaline fuel cells (AFC) with ethanol as combustible was studied, using the prepared surfaces as a catalyzer for the electrooxidation of ethanol. The developed process consists of the rapid solidification (quenching) through melt spinning of an aluminum-silver alloy (92.25 %wt. Al) to obtain a supersaturated solid solution, followed by a porous anodization in oxalic acid and electrochemical treatment in alkaline medium. The morphology of the alloy was characterized by Scanning Electron Microscopy, X-Ray Diffraction, Transmission Electron Microscopy and Energy Dispersive X. Ray Spectrometry and the performance of the ethanol electrooxidation was tested though cyclic voltammetry The obtained results confirm that this process produces crystalline silver nanoparticles with a size varying from 4 to 120 nm with 95% of the particles between 4 and 87 nm. The electrochemical study showed that the produced alloy exhibits a similar behavior to that of pure aluminum in the tested mediums. The reaction between the aluminum and the alkaline medium produces a gaseous hydrogen layer that impedes the catalytic action of silver on the ethanol oxidation. Moreover, it was concluded that the produced alloy is not a viable material for the use as anode for direct ethanol AFCs. Therefore, the nanoparticle production method was tested for an Al-Si near-eutectic alloy (14.2 %wt.). This alloy with silicon nanoparticles showed an increase in the performance of H2 production rate of 17% compared to that of the regular Al-Si near-eutectic alloy. Nanoparticulas Nanotubos Óxido de alumínio Produção de hidrogênio Nanoparticles Nanotubes Al-Ag alloy Al-Si alloy Melt spinner H2 production
7	Estudo da cinética de precipitação de Ag na liga Cu-7% Al-4% Ag / Maia Neto, Alfredo dos Santos. January 2005 (has links) Orientador: Antonio Tallarico Vicente Adorno / Resumo: Neste trabalho, foi feito um estudo da cinética de precipitação da fase rica em prata, na liga Cu-7%Al-4%Ag, em peso, utilizando-se o modelo cinético isotérmico de Johnson-Mehl-Avrami e os modelos cinéticos nãoisotérmicos de Kissinger e Ozawa. A reação de precipitação da fase rica em prata foi acompanhada por medidas de variação da microdureza da liga com a temperatura de têmpera e o tempo de envelhecimento, e também por medidas de dilatometria. As fases presentes nas diversas temperaturas e tempos considerados, foram identificadas e caracterizadas por microscopia óptica e eletrônica de varredura, análise por dispersão de energias de raios X e por difratometria de raios X. Os resultados obtidos indicaram que a formação dos precipitados ricos em prata corresponde a um processo controlado por difusão da prata nos contornos de grão da matriz, no intervalo de temperaturas de 400 a 600 oC. O cálculo da energia de ativação para a formação dos precipitados, utilizando-se a equação de Johnson-Mehl-Avrami, forneceu um valor bastante próximo daquele encontrado na literatura, confirmando que o processo é controlado pela difusão da prata. O valor da energia de ativação para o crescimento dos precipitados ricos em Ag, calculado a partir de um método que considera o inverso do tempo necessário para o precipitado atingir seu tamanho máximo como proporcional à taxa de crescimento, ficou próximo daquele obtido utilizando-se a equação de Johnson-Mehl-Avrami, indicando que esse método pode ser utilizado para o cálculo da energia de ativação do processo cinético. Os valores da energia de ativação associados ao processo de precipitação de Ag, obtidos por métodos não isotérmicos, ficaram razoavelmente próximos daqueles encontrados na literatura e os valores assim obtidos associados à solubilização de Ag foram maiores do que aqueles encontrados na literatura...(Resumo completo, clicar acesso eletrônico abaixo) / Abstract: In this work, the Ag-rich phase precipitation kinetics in the Cu-7wt.%Al-4wt.%Ag alloy, was studied using the Johnson-Mehl-Avrami isothermal kinetic model and the Kissinger and Ozawa non-isothermal kinetic models. The Ag-rich phase precipitation reaction was followed by microhardness changes measurements with quenching temperature and with aging time, and also by dilatometric measurements. The identification and characterization of the phases present at the considered temperatures and times were made by optical and scanning electronic microscopy, energy dispersive X-ray analysis and X-ray diffractometry. The results showed that the Ag-rich precipitates formation corresponds to a diffusion controlled process at the matrix grain boundaries, in the temperatures range from 400 to 600 oC. The activation energy value for the precipitates formation, calculated using the Johnson-Mehl-Avrami equation, is close to that found in the literature, thus confirming that the process is diffusion controlled. The activation energy value for the growing of Ag-rich precipitates, obtained considering that the inverse of the time to reach the precipitates maximum size is proportional to the growing rate, is close to that found using the Johnson-Mehl-Avrami equation, indicating that this method is useful to evaluate the activation energy for the kinetic process. The activation energy values obtained by non-isothermal methods and associated to the precipitation process were very close to those found in the literature, and the values associated to Ag dissolution were greater than those reported in the literature. This discrepancy may be associated to the presence of Al, and the Al-Ag interaction may be disturbing the diffusion process. / Mestre Movimento. Precipitação (Química) Difusão. Método isotérmico. Método não-isotérmico. Físico-química. Cu-Al-Ag alloys. eng Non-isothermal method. eng Isothermal method. eng

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