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- Title
Effect of ammonia on gasification performances of phenol in supercritical water.
- Authors
Wang, Yuzhen; Zhu, Yitong; Liu, Zhuan; Fang, Changqing; Yang, Jianqiao; Guo, Yanfeng; Wang, Shuzhong
- Abstract
Highlights • Effects of ammonia on the gasification pathways of phenol were analyzed. • Higher temperature promoted the hydrogen production and degradation of phenol. • The gasification efficiencies increased linearly in the first 10 s, and then stabilize. • Ammonia prevented the gasification of phenol, especially at higher concentrations. • Stable nitrogen polycyclic compounds were generated for the mixture of phenol and ammonia. Abstract The solutions of phenol and the mixture of phenol and ammonia were gasified in a continuous supercritical water reactor to evaluate the influences of ammonia on the hydrogen production and the degradation pathways of phenol. The effects of temperature (560–640 °C), reaction time (2–20 s) and concentration of ammonia (500–2000 mg/L) on gaseous distributions, gasification efficiencies and reactants removal efficiencies were investigated. In addition, the effects of ammonia on the kinds of intermediate products were analyzed. Results showed that the increasing temperature greatly promoted the hydrogen production and degradation of phenol. Longer reaction time gave a positive effect on gasification efficiencies in 10 s, while the effect was little when the reaction time longer than 10 s. Ammonia prevented the production of hydrogen and the degradation of phenol, which was mainly due to the generation of more stable nitrogen polycyclic compounds. The possible degradation pathways for the mixture of phenol and ammonia were proposed.
- Subjects
AMMONIA; PHENOL; SUPERCRITICAL water; HIGH temperatures; HYDROGEN production
- Publication
Chemical Engineering Research & Design: Transactions of the Institution of Chemical Engineers Part A, 2018, Vol 136, p242
- ISSN
0263-8762
- Publication type
Article
- DOI
10.1016/j.cherd.2018.04.042