1. Effect of impurities of CH3OH, CH3COOH, and KOH on aqueous phase reforming of glycerol over mesoporous Ni–Cu/CeO2 catalyst.
- Author
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Wu, Kai, Dou, Binlin, Zhang, Hua, Liu, Dashuai, Chen, Haisheng, and Xu, Yujie
- Subjects
CATALYSTS ,GLYCERIN ,HYDROGEN evolution reactions ,DEHYDRATION reactions ,CATALYST poisoning ,CARBON dioxide - Abstract
Impurities are inevitable in crude glycerol, a by-product of biodiesel, which has a great influence on aqueous phase reforming (APR). This work investigates three impurities (CH 3 OH, CH 3 COOH, and KOH) in the aqueous phase reforming of glycerol (GAPR) using a mesoporous Ni–Cu/CeO 2 catalyst at three temperatures. The experiment results indicate that the increase of temperature is beneficial to the conversion of glycerol into gas products, but not favor to the proportion of H 2 in the gas phase. The presence of CH 3 OH almost has not affected the total gas volume, while CH 3 COOH and KOH decreased and increased the gas volume, respectively. The deactivation of the catalyst occurs under acidic conditions because the active phase Ni on the catalyst surface is lost in the hydrogen evolution reaction. KOH has the greatest influence on the gas phase composition, which greatly increases the H 2 production and the proportion of H 2. The results of liquid-phase solution analysis show that the addition of CH 3 COOH promoted the dehydration of glycerol, which is contrary to the results obtained by adding KOH. CH 3 OH, as the final product of glycerol dehydrogenation and decarbonization, is added to the initial solution, which will be conducive to the dehydration reaction. The addition of CaO can increase the H 2 production in the APR of glycerol solution containing impurities. • Mesoporous Ni–Cu/CeO 2 was successfully synthesized to APR of glycerol. • Effects of impurities of CH 3 OH, CH 3 COOH, and KOH on APR of glycerol were determined. • CH 3 COOH and KOH decreased and increased gas production from APR, respectively. • Deactivation of Mesoporous Ni–Cu/CeO 2 in APR occurred under acidic conditions. • Enhanced WGS and reduced methanation were achieved by in-situ CO 2 removal. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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