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Modelización de los sistemas de electrificación ferroviaria, en corriente alterna y continua, con sistemas recuperadores de energía para el estudio de la eficiencia energéticaRatés Palau, Sergio 23 March 2012 (has links)
A detail modelling of railway electrical system with energy storages devices is developed in this thesis in order to analyze most of the implemented railway electrical system. The modelling has been realized from a point of view the design of them as from a point of view of purely energetic efficiency.
In this way, after analyzing of the electric railway systems, it has been developed simple element models that have been grouped in four categories: contact line and return circuit, fix elements, mobile elements and energy recovery and storages devices. The complete systems are built from the simple element models linked. The system of equations of the complete system is no linear, and it is solved means of numeric methods.
Then, it is shown the structure of Rsim software that has been developed completely as a part of this work, to conclude with two examples of the application of Rsim. The first example belongs an alternative current railway electrification and the second example is a direct current railway electrification.
Keywords: DC railway system, AC railway system, railway modeling, energetic efficiency, reverse substations, energy storage devices, unbalance, rail potential, stray currents.
A detail modelling of railway electrical system with energy storages devices is developed in this thesis in order to analyze most of the implemented railway electrical system. The modelling has been realized from a point of view the design of them as from a point of view of purely energetic efficiency.
In this way, after analyzing of the electric railway systems, it has been developed simple element models that have been grouped in four categories: contact line and return circuit, fix elements, mobile elements and energy recovery and storages devices. The complete systems are built from the simple element models linked. The system of equations of the complete system is no linear, and it is solved means of numeric methods.
Then, it is shown the structure of Rsim software that has been developed completely as a part of this work, to conclude with two examples of the application of Rsim. The first example belongs an alternative current railway electrification and the second example is a direct current railway electrification.
Keywords: DC railway system, AC railway system, railway modeling, energetic efficiency, reverse substations, energy storage devices, unbalance, rail potential, stray currents.
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Liga de magnésio como material para bateria de alta densidade energéticaMunhoz, Igor Polezi January 2014 (has links)
Orientador: Prof. Dr. Jorge Tomioka / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Engenharia Elétrica, 2014. / No contexto energético, as mudanças climáticas e as crescentes crises energéticas
aumentaram as preocupações e as pesquisas na área de acumuladores de energia, visando
alcançar melhorias no cenário energético e ambiental global. Ao mesmo tempo, a sociedade
tornou-se dependente do consumo de energia elétrica, sendo que falhas no fornecimento não são permitidas. Portanto, observa-se a necessidade da energia ofertada ser de boa qualidade e, principalmente, não sofrer interrupções. Atrelado a esses fatores, a bateria de Magnésio ¿ Ar passou a ser considerada uma fonte promissora de energia elétrica, principalmente pela abundância de Magnésio (sétimo elemento mais presente no planeta), por não poluir o meio ambiente, ser barata e possuir energia especifica elevada. Essas características transformam esse acumulador em um potencial substituto para outras tecnologias. No entanto, a bateria demagnésio possui desvantagens que precisam ser vencidas por meio de pesquisas para alavancar o seu uso comercial massivo. Sob essa perspectiva, neste trabalho propõe-se o estudo da liga de magnésio AZ91 para aplicação em baterias de Magnésio ¿ Ar, por meio de ensaios de porosidade e de dureza, como também análise microestrutural e mensuração do potencial de circuito aberto e das curvas de polarização potenciodinâmica, utilizando-se uma célula eletroquímica de três eletrodos e um potenciostato em diferentes tempos de imersão da liga AZ91 na solução eletrolítica de NaCl 0,1 M. A porosidade da peça, observada no microscópio óptico com ampliação de 50 vezes, revelou que em cada fase de solidificação existem poros de tamanhos diferentes, com distribuição específica. Conforme o processo de resfriamento ocorre, nota-se a presença de poros maiores. Relacionado à porosidade, a dureza apresentou valores maiores na fase inicial de solidificação, onde a porosidade é menor. Por meio da análise microestrutural, foi possível verificar a presença de dendritas, com uma complexa dispersão de segunda fase na liga (alumínio), porosidades e inclusões. As medidas de potencial de circuito aberto indicam uma tendência de resistência à corrosão em temposmaiores de contato da amostra com a solução de NaCl. Não foi possível observar passivação aparente na amostra, nem pontos de corrosão localizada (pite) nas curvas de polarização potenciodinâmica. As variações no potencial de corrosão apontaram uma maior resistência à corrosão em tempos de imersão maiores; contudo, os valores estáveis de densidade de corrente de corrosão demonstram que a velocidade de corrosão permaneceu constante, sendo que a camada de óxido formada não contribuiu na proteção do material. Para a aplicação em baterias de magnésio, esses resultados conferem uma limitação da liga AZ91, pois a camada de óxido formada pode prejudicar o funcionamento do dispositivo em processos de descarga intermitente. As principais formas de controlar a eficiência da bateria de Magnésio ¿ Ar são por meio da composição da liga, da oxigenação, do pH, da temperatura e da concentração de
sais NaCl no eletrólito. / In the energy sector, weather changes and rising energy crisis raised concerns and research in
energy accumulators to achieve improvements in overall environmental and energy scenario.
At the same time, society has become dependent on electricity consumption, so failures in
supply are not tolerated. Therefore, the energy needs to have a good quality, and not suffer
interruptions. Coupled to these factors, the battery Magnesium ¿ Air has been considered a
promising source of electricity, mainly by the abundance of magnesium (seventh-most
element present on the planet), not to pollute the environment, be cheap and have high
specific energy. These characteristics transform this accumulator in a potential substitute for
other technologies. However, the magnesium battery has disadvantages that need to be
overcome through research to leverage their massive commercial use. From this point of
view, this study proposes the characterization of magnesium alloy AZ91 for application in
batteries Magnesium ¿ Air, testing the porosity and hardness, as well as microstructural
analysis, and the measurement of the open potential circuit and the potentiodynamic
polarization, in various immersion times using an electrochemical cell with three electrodes.
The porosity of the part, observed in the optical microscope, revealed that at each stage of
solidification, the pores have different sizes and distribution. As the cooling process occurs,
could observe the presence of larger pores. Associated to the porosity, hardness values were
higher in the initial phase of solidification, where the porosity was less. Through
microstructural analysis was verified the presence of dendrites, with a complex dispersion of
second phase in the alloy (aluminum), porosity and inclusions. The open potential circuit
indicated a tendency for corrosion resistance in greater immersion time in the solution of
NaCl. In all cases, the potentiodynamic polarization curves did not exhibit apparent passivity,
or points of localized corrosion (pitting). The changes in corrosion potential showed greater
resistance to corrosion in immersion times larger, however, the steady state values of
corrosion current density demonstrated that the corrosion rate remained constant and the
oxide layer formed did not protect the material. For use in magnesium batteries, these results
provided a limitation of the AZ91 alloy, because the oxide layer can disturb the functioning of
the device in cases of intermittent discharge. The main ways to control the battery efficiency
Magnesium ¿ Air are through the alloy composition, oxygenation, pH, temperature and salt
concentration of NaCl in the electrolyte.
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