CH3OH steam reforming is an attractive way to produce hydrogen with high efficiency. In this study, CuO.xAl(2)O(3) (x = 1, 2, 3, and 4) were fabricated based on the solid-state route, and the calcined samples were employed in methanol steam reforming at atmospheric pres-sure and in the temperature range of 200-450 degrees C. The results revealed that all samples have a high BET area (173-275 m(2) g(-1)), and their crystallinity was reduced by increasing the alumina content in the catalyst formulation. The catalytic activity tests showed that the CH3OH conversion and H-2 selectivity decreased by rising the Al2O3 center dot CuO molar ratio. The methanol conversion enhanced from 13 to 85 by increasing the reaction temper-ature from 200 degrees C to 450 degrees C over the CuO center dot Al2O3 catalyst, due to the higher reducibility of this catalyst at lower temperatures compared to other prepared samples. The influence of calcination temperature (300-500 degrees C), GHSV (28,000-48000 ml h(-1). g(cat)(-1)), feed ratio (C:W = 1:1 to 1:9), and reduction temperature (250-450 degrees C) was also determined on the yield of the chosen sample. The results revealed that the maximum methanol conversion decreased from 90 to 79 by raising the calcination temperature from 300 to 500 degrees C due to the reduction of surface area and sintering of species at high calcination temperatures. (c) 2022 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.
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机译:CH3OH 蒸汽重整是一种极具吸引力的高效制氢方式。本研究基于固态路线制备了CuO.xAl(2)O(3)(x = 1, 2, 3, and 4),并将煅烧后的样品用于200-450°C温度范围内的甲醇蒸汽重整。结果表明,所有样品均具有较高的BET面积(173-275 m(2) g(-1)),并且随着催化剂配方中氧化铝含量的增加而降低结晶度。催化活性测试表明,随着Al2O3中心点CuO摩尔比的升高,CH3OH转化率和H-2选择性降低。由于与其他制备的样品相比,该催化剂在较低温度下的还原性更高,因此通过将反应温度从200°C提高到450°C,甲醇转化率从13%提高到85%。煅烧温度(300-500°C)、GHSV(28,000-48000 ml h(-1))、进料比(C:W = 1:1至1:9)和还原温度(250-450°C)对所选样品收率的影响也得到了测定。结果表明,由于在高煅烧温度下,由于表面积减小和物质烧结,煅烧温度从300°C提高到500°C,甲醇转化率从90%降低到79%。(c) 2022 Hydrogen Energy Publications LLC. 由 Elsevier Ltd. 出版。保留所有权利。
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