Impactos das Tecnologias na Engenharia Química 3最新文献

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AVALIAÇÃO DE ÓLEOS DE SOJA COM DIFERENTES ORIGENS NA PRODUÇÃO DO BIODIESEL VIA ROTA METÍLICA 甲基法生产生物柴油中不同来源大豆油的评价

Impactos das Tecnologias na Engenharia Química 3

Pub Date : 2017-07-01 DOI: 10.5151/CHEMENG-COBEQIC2017-250

M. R. Wolf, I. S. T. Perassi, N. Assis, F. V. Pereira

引用次数: 0

INIBIDOR DE CORROSÃO OBTIDO POR LIXIVIAÇÃO DE CIGARRO APÓS SEU CONSUMO 香烟消费后浸出得到的缓蚀剂

Impactos das Tecnologias na Engenharia Química 3

Pub Date : 2017-07-01 DOI: 10.5151/CHEMENG-COBEQIC2017-188

M. G. Peraça, L. Machado, L. M. Rodrigues

引用次数: 0

Zn-ZIF EM TECIDO APLICADO NO PROCESSO DE CAPTURA DE CH4 Zn-ZIF在CH4捕获过程中的应用

Impactos das Tecnologias na Engenharia Química 3

Pub Date : 2017-07-01 DOI: 10.5151/CHEMENG-COBEQIC2017-086

G. Gil, G. O. Lima, Lucas Mendes Pedro, V. S. Lima, Fabrício Maestá Bezerra, M. P. Moisés

RESUMO – O composto metalorgânico Zn-ZIF-8 foi sintetizado e impregnado em tecido de algodão para aplicação no processo de captura de metano (CH4) devido sua capacidade de adsorção e armazenamento de gases. Como o CH4 aparece como um dos principais gases responsáveis pelo efeito estufa, reduzir sua emissão é de fundamental importância no controle dos problemas ambientais. A área específica da Zn-SIF-8 impregnada no tecido foi de 574,3 mg (BET) e área de microporos (t-Plot) de 553,9 mg. A fixação do material no tecido foi confirmada por DRX do tecido, da MOF e da MOF impregnada no tecido. Portanto neste trabalho foi avaliado a eficiência da Zn-ZIF em tecido, a 25 oC e 1 bar, no processo de captura de metano sendo adsorvido 680 cm do gás por área (m) do tecido.

摘要合成了金属有机化合物Zn-ZIF-8，并将其浸渍在棉织物上，用于甲烷捕获(CH4)过程，因为它具有吸附和储存气体的能力。由于CH4是造成温室效应的主要气体之一，减少其排放对控制环境问题至关重要。Zn-SIF-8在组织中的比表面积为574.3 mg (BET)，微孔面积为553.9 mg (t-Plot)。通过x射线衍射(xrd)、MOF和MOF浸渍证实了材料在组织中的固定。因此，本研究评估了锌-ZIF在25℃和1 bar条件下在织物中吸附680 cm气体的甲烷捕获过程中的效率。

引用次数: 0

DETERMINAÇÃO EXPERIMENTAL DA CURVA DE POLARIZAÇÃO DE UMA CÉLULA A COMBUSTÍVEL TIPO PEM PEM型燃料电池极化曲线的实验测定

Impactos das Tecnologias na Engenharia Química 3

Pub Date : 2017-07-01 DOI: 10.22533/AT.ED.31919010422

Roque Machado de Senna, T. Santos, Henrique Senna, Marcelo Linardi

The electric energy generation presents itself as a great mankind challenge due to its enormous potential pollutant, especially when coming from fossil fuels. In the world, in 2013, as shown in BEN 2016, only 13.5% of the energy matrix was renewable fuels made up being in Brazil 41.2%. Based on these statistics it can be affirmed that the energy production in Brazil is still fossil fuels predominant. One of the alternatives that deserves special mention is the fuel cells (CAC) technology, since they are sustainable and non-polluting devices that oxidize electrochemically the fuel, usually hydrogen, generating electric energy and heat. This work is aim to show the procedures to test a unitary CAC of solid electrolyte ETEK_HP, a Náfion (PTFE) membrane with a 115 μm thickness composed and the electrode being a platinum catalyst with a 0,4mg / cm2 load at the anode and 0.6 mg / cm2 at the cathode, supported on carbon. The optimum CAC operating point by the MEA efficiency was 433 mV @ 1, 120 mA, with linear characteristic and it is not significantly subject to the activation and mass transfer phenomena. It is noted that between 365 mV and 558 mV the density was above 0.45 W / cm2 and consequently the CAC power above 11 W. The oxygen and hydrogen consumption were more efficient above 800 mV.

电力发电由于其巨大的潜在污染，特别是来自化石燃料的电力发电对人类构成了巨大的挑战。在世界范围内，2013年，如BEN 2016所示，能源矩阵中只有13.5%是可再生燃料，其中巴西为41.2%。基于这些统计数据，可以肯定的是，巴西的能源生产仍然以化石燃料为主。其中一个值得特别提及的替代品是燃料电池(CAC)技术，因为它们是可持续的、无污染的设备，通过电化学氧化燃料(通常是氢)，产生电能和热能。这项工作的目的是展示测试固体电解质ETEK_HP的单一CAC的程序，ETEK_HP是一种厚度为115 μm的Náfion (PTFE)膜，电极是铂催化剂，阳极负载为0.4 mg / cm2，阴极负载为0.6 mg / cm2，由碳支撑。MEA效率的最佳CAC工作点为433 mV @ 1,120 mA，具有线性特性，不受活化和传质现象的显著影响。在365 mV和558 mV之间，密度大于0.45 W / cm2，因此CAC功率大于11 W。在800mv以上，氧和氢的消耗效率更高。

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引用次数: 0

DESENVOLVIMENTO DE BIODIGESTOR E AVALIAÇÃO DO DESEMPENHO PARA TRATAMENTO DE RESÍDUO SÓLIDO ORGÂNICO 有机固体废物处理生物消化池的开发及性能评价

Impactos das Tecnologias na Engenharia Química 3

Pub Date : 2017-07-01 DOI: 10.5151/CHEMENG-COBEQIC2017-310

F. S. Pio, L. T. Santana, L. Correia, F. D. Castro

引用次数: 0

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