{"title":"铈形态对膜式转化炉甲烷蒸汽转化制氢的影响","authors":"Anjali Baudh, Meenakshi Garjola, Rahul Sharma, Sweta Sharma, Rajesh Kumar Upadhyay","doi":"10.1002/cjce.25396","DOIUrl":null,"url":null,"abstract":"<p>Hydrogen is a potential energy carrier in comparison to conventional fuels due to its high energy content. Methane is an attractive source for ‘on-site’ production of hydrogen by using membrane reformer due to its low cost. However, such reformers are not well studied and high temperature operation of steam methane reforming (SMR) makes the integration with membrane separation difficult. Further, the main product of SMR is CO and H<sub>2</sub> in which CO has an inhibition effect on the membrane separation process. Therefore, it is vital to synthesize a low temperature and low CO selective catalyst for a suitable integration with membrane reformer. Nickel-based catalyst is widely used for SMR due to its low cost and high catalytic activity. CeO<sub>2</sub> is a favoured support as it mobilizes the lattice oxygen and reduces the coke formation and CO selectivity. Though several studies are reported on CeO<sub>2</sub> based support, the effect of CeO<sub>2</sub> surface morphology is not studied for SMR. In the current work, Ni/CeO<sub>2</sub> of different shapes (nanocube and nanorod) are synthesized. The complete characterization of the support was performed. The effect of support shape, calcination temperature, and reduction temperature on SMR activity is found at different operating temperatures. For each condition conversion, CO, CO<sub>2</sub> selectivity, and hydrogen yield are calculated. The results show the CeO<sub>2</sub> morphology has a considerable effect on conversion, CO selectivity, and hydrogen yield. It is found that ceria nanocube calcined at 550°C provides better performance at high temperature.</p>","PeriodicalId":9400,"journal":{"name":"Canadian Journal of Chemical Engineering","volume":null,"pages":null},"PeriodicalIF":1.6000,"publicationDate":"2024-07-09","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Effect of ceria morphology on hydrogen production via methane steam reforming for membrane reformer\",\"authors\":\"Anjali Baudh, Meenakshi Garjola, Rahul Sharma, Sweta Sharma, Rajesh Kumar Upadhyay\",\"doi\":\"10.1002/cjce.25396\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Hydrogen is a potential energy carrier in comparison to conventional fuels due to its high energy content. Methane is an attractive source for ‘on-site’ production of hydrogen by using membrane reformer due to its low cost. However, such reformers are not well studied and high temperature operation of steam methane reforming (SMR) makes the integration with membrane separation difficult. Further, the main product of SMR is CO and H<sub>2</sub> in which CO has an inhibition effect on the membrane separation process. Therefore, it is vital to synthesize a low temperature and low CO selective catalyst for a suitable integration with membrane reformer. Nickel-based catalyst is widely used for SMR due to its low cost and high catalytic activity. CeO<sub>2</sub> is a favoured support as it mobilizes the lattice oxygen and reduces the coke formation and CO selectivity. Though several studies are reported on CeO<sub>2</sub> based support, the effect of CeO<sub>2</sub> surface morphology is not studied for SMR. In the current work, Ni/CeO<sub>2</sub> of different shapes (nanocube and nanorod) are synthesized. The complete characterization of the support was performed. The effect of support shape, calcination temperature, and reduction temperature on SMR activity is found at different operating temperatures. For each condition conversion, CO, CO<sub>2</sub> selectivity, and hydrogen yield are calculated. The results show the CeO<sub>2</sub> morphology has a considerable effect on conversion, CO selectivity, and hydrogen yield. 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引用次数: 0
摘要
与传统燃料相比,氢的能量含量高,是一种潜在的能源载体。甲烷因其低成本而成为利用膜转化器进行 "现场 "制氢的一个有吸引力的来源。然而,对这种重整器的研究并不深入,而且蒸汽甲烷重整(SMR)的高温操作使其难以与膜分离技术相结合。此外,SMR 的主要产物是 CO 和 H2,其中 CO 对膜分离过程有抑制作用。因此,合成一种低温、低 CO 选择性催化剂对与膜转化器的整合至关重要。镍基催化剂因其低成本和高催化活性而被广泛用于 SMR。CeO2 是一种受青睐的支持物,因为它能调动晶格氧,减少焦炭的形成并降低 CO 的选择性。虽然有一些关于基于 CeO2 的支持物的研究报告,但尚未研究 CeO2 表面形态对 SMR 的影响。在目前的工作中,合成了不同形状(纳米立方和纳米棒)的 Ni/CeO2。对支撑物进行了完整的表征。在不同的操作温度下,发现了支撑物形状、煅烧温度和还原温度对 SMR 活性的影响。计算了每种条件下的转化率、CO、CO2 选择性和氢产率。结果表明,CeO2 的形态对转化率、一氧化碳选择性和氢产率有相当大的影响。研究发现,在 550°C 煅烧的纳米氧化铈在高温下具有更好的性能。
Effect of ceria morphology on hydrogen production via methane steam reforming for membrane reformer
Hydrogen is a potential energy carrier in comparison to conventional fuels due to its high energy content. Methane is an attractive source for ‘on-site’ production of hydrogen by using membrane reformer due to its low cost. However, such reformers are not well studied and high temperature operation of steam methane reforming (SMR) makes the integration with membrane separation difficult. Further, the main product of SMR is CO and H2 in which CO has an inhibition effect on the membrane separation process. Therefore, it is vital to synthesize a low temperature and low CO selective catalyst for a suitable integration with membrane reformer. Nickel-based catalyst is widely used for SMR due to its low cost and high catalytic activity. CeO2 is a favoured support as it mobilizes the lattice oxygen and reduces the coke formation and CO selectivity. Though several studies are reported on CeO2 based support, the effect of CeO2 surface morphology is not studied for SMR. In the current work, Ni/CeO2 of different shapes (nanocube and nanorod) are synthesized. The complete characterization of the support was performed. The effect of support shape, calcination temperature, and reduction temperature on SMR activity is found at different operating temperatures. For each condition conversion, CO, CO2 selectivity, and hydrogen yield are calculated. The results show the CeO2 morphology has a considerable effect on conversion, CO selectivity, and hydrogen yield. It is found that ceria nanocube calcined at 550°C provides better performance at high temperature.
期刊介绍:
The Canadian Journal of Chemical Engineering (CJChE) publishes original research articles, new theoretical interpretation or experimental findings and critical reviews in the science or industrial practice of chemical and biochemical processes. Preference is given to papers having a clearly indicated scope and applicability in any of the following areas: Fluid mechanics, heat and mass transfer, multiphase flows, separations processes, thermodynamics, process systems engineering, reactors and reaction kinetics, catalysis, interfacial phenomena, electrochemical phenomena, bioengineering, minerals processing and natural products and environmental and energy engineering. Papers that merely describe or present a conventional or routine analysis of existing processes will not be considered.
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