Enhanced syngas production through dry reforming of methane with Ni/CeZrO2 catalyst: Kinetic parameter investigation and CO2-rich feed simulation

IF 5.5 Q1 ENGINEERING, CHEMICAL Chemical Engineering Journal Advances Pub Date : 2024-10-09 DOI:10.1016/j.ceja.2024.100655

Intan Clarissa Sophiana , Soen Steven , Rawiyah Khairunida’ Shalihah , Ferry Iskandar , Hary Devianto , Elvi Restiawaty , Norikazu Nishiyama , Yogi Wibisono Budhi

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Abstract

Natuna's natural gas reserve, which contains 70 %–v CO₂ and 30 %–v CH_4, opens a prospective method for producing syngas through the dry reforming of methane (DRM). This study used the equation and determination of kinetic parameters in a fixed-bed reactor to develop the operating conditions for the DRM process. The catalyst used was 10 %Ni/CeZrO₂ and followed the Langmuir-Hinshelwood mechanism, with CH₄ dissociation (activation of C–H bonds) on the Ni catalyst as the rate-determining step. According to the results, the simulation and experimental data have error values of ≤ 5 % and RMSE < 0.046. This indicates that the equation and kinetic parameters used in the simulation are valid for reactor modeling. Steady-state modeling was then conducted using a 1D quasihomogeneous model. The feed composition of CO₂:CH₄ = 70:30 (Natuna gas field composition) has optimized results with temperature 700 °C, CH₄ conversion at 92 %, CO₂ conversion at 28 %, and H₂/CO ratio 1.42, and carbon formation at 7.1 mgC/gcat. This study also found that a higher CO₂:CH₄ feed ratio could reduce carbon formation during DRM.

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使用 Ni/CeZrO2 催化剂对甲烷进行干转化，提高合成气产量：动力学参数研究和富含二氧化碳的进料模拟

纳土纳的天然气储量含有 70%-v CO2 和 30%-v CH4，这为通过甲烷干重整（DRM）生产合成气开辟了前景广阔的方法。本研究利用固定床反应器中的方程和动力学参数的确定来制定 DRM 工艺的操作条件。使用的催化剂为 10 %Ni/CeZrO2 并遵循 Langmuir-Hinshelwood 机理，Ni 催化剂上的 CH4 解离（C-H 键活化）是决定速率的步骤。结果表明，模拟数据和实验数据的误差值≤ 5 %，RMSE < 0.046。这表明模拟中使用的方程和动力学参数在反应器建模中是有效的。然后使用一维准均质模型进行了稳态建模。CO2:CH4 = 70:30（纳土纳气田成分）的进料成分产生了最佳结果，温度为 700 °C，CH4 转化率为 92%，CO2 转化率为 28%，H2/CO 比率为 1.42，碳形成率为 7.1 mgC/gcat。该研究还发现，较高的 CO2:CH4 进料比可减少 DRM 过程中的碳形成。

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