• Chỉ mục bởi
  • Năm xuất bản

Optimization of operating conditions for anisole hydrodeoxygenation reaction over Zr-based metal–organic framework supported Pt catalyst

Le Faculty of Chemical Engineering, Industrial University of Ho Chi Minh city, 12 Nguyen Van Bao, Go Vap, Ho Chi Minh City, 70000, Viet Nam|
Jinsoo (55653224900) | Eun Yeol (14037776800); Kim | Seung-Soo (35173247100); Lee | Dieu-Phuong (57201480720); Kim Department of Chemical Engineering, Kangwon National University, 346 Joongang-ro, Gangwon-do, Samcheok, 25913, South Korea| Van Nhieu (57210566811); Phan Department of Chemical Engineering (Integrated Engineering), Kyung Hee University, 1732 Deogyeong-daero, Giheung-gu, Gyeonggi-do, Yongin-si, 17104, South Korea|

Fuel Processing Technology Số , năm 2022 (Tập 238, trang -)

ISSN: 3783820

ISSN: 3783820

DOI: 10.1016/j.fuproc.2022.107477

Tài liệu thuộc danh mục:



Từ khóa: Catalysis; Catalyst supports; Chemical reactors; Metal nanoparticles; Regression analysis; Surface properties; Synthesis (chemical); Anisole; Hydrodeoxygenation; Metalorganic frameworks (MOFs); Molar ratio; Optimization of operating conditions; Optimum conditions; Pt-based catalyst; Response-surface methodology; UiO-67; Molar ratio
Tóm tắt tiếng anh
To optimize the operating conditions for catalytic hydrodeoxygenation (HDO) of anisole in a continuous fixed-bed reactor, the response surface methodology combined with the central composite design was used to maximize the conversion by tuning the molar ratio of H2 to anisole, temperature, and pressure, which are considered key parameters on catalytic reaction. Analysis of variance was used to determine the regression model's compatibility. The catalyst was prepared using a Zr-based metal–organic framework, UiO-67, as a support, which was synthesized under microwave-assisted solvothermal reaction, followed by loading Pt nanoparticles on its surface via a double solvent method. The results demonstrated that the obtained mathematical model accurately predicted the conversion, which was more greatly influenced by temperature in comparison with the H2/anisole molar ratio and pressure in HDO reaction over the 3 wt% Pt/UiO-67 catalyst. Concurrently, the highest conversion of 92.5% was obtained under the optimum conditions: H2/anisole molar ratio of 35.2, reaction temperature of 297.6 °C, and a reaction pressure of 12.8 bar. The relative error was only 1.08% when compared with experimental values obtained under near-optimum conditions. Furthermore, at high temperatures, the reaction pathway followed the demethoxylation trend, yielding cyclohexane and benzene as the main products. © 2022

Xem chi tiết