Junqi Weng scite author profile

Binders are needed for the pelletization of zeolite catalysts, and the pore network structure of binders can significantly affect the catalytic performance of zeolite catalyst pellets. In this work, a multiscale model directly coupling model equations at crystal, pellet, and reactor levels is proposed to engineer the pore network structure of binders. Benzene alkylation with ethylene catalyzed by ZSM-5 zeolite pellets in a fixed-bed reactor is taken as the model reaction system. The results show that strong diffusion limitations exist in crystals (micropores) and binders (macro-/mesopores). Shrinking the crystal size or adding intracrystalline pores in crystals can reduce the diffusion limitation in micropores but also can enhance the diffusion limitations in macro-/mesopores. An optimal volume fraction of binders can balance diffusion in binders and reaction in crystals and thus results in a maximum conversion of ethylene. The zeolite pellet with a higher binder porosity and a larger binder pore diameter is more favorable, and the influence of binder porosity is stronger than that of the binder pore diameter. In addition, crystallizing the binder into the zeolite phase can largely enhance the catalytic performance of zeolite catalyst pellets, especially when the volume fraction and porosity of the binder are high. This work gives a multiscale model and some useful guidance for developing zeolite catalyst pellets used in industry.

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Numerical determination of fluid‐to‐particle mass and heat transfer coefficients in packed bed reactors

Weng

Zhang

et al. 2022

AIChE Journal

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A method based on particle‐resolved CFD is built and validated, to calculate the fluid‐to‐particle mass and heat transfer coefficients in packed beds of spheres with different tube‐to‐particle diameter ratios (N) and of various particle shapes with N = 5.23. This method is characterized by considering axial dispersion. The mass and heat transfer coefficients increase by 5%–57% and 9%–63% after considering axial dispersion, indicating axial dispersion should be included in the method. The mass and heat transfer coefficients are reduced as N decreases. The catalyst particles without inner holes show higher mass and heat transfer coefficients than the ones with inner holes, because of unfavorable fluid flow in inner holes. The bed of trilobes has the highest mass and heat transfer coefficients, being 85% and 95% higher than the one of spheres. This work provides a versatile method and some useful guidance for the design of packed bed reactors.

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Radially layered configuration for improved performance of packed bed reactors

Weng

Zhang

et al. 2022

Chemical Engineering Science

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Junqi Weng

Engineering Pore Network Structure of Binders for Improved Catalytic Performance of Zeolite Pellets Using a Multiscale Model

Numerical determination of fluid‐to‐particle mass and heat transfer coefficients in packed bed reactors

Radially layered configuration for improved performance of packed bed reactors

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