Your search keyword '"Zheng‐Hong Luo"' showing total 3 results

1. Physics-informed deep learning for modelling particle aggregation and breakage processes

Author

Zheng-Hong Luo, Fanlin Meng, Xizhong Chen, and Li Ge Wang

Subjects

Mathematical optimization, education.field_of_study, Physics-informed neural network, Artificial neural network, business.industry, General Chemical Engineering, Deep learning, Population, Population balance equation, General Chemistry, Inverse problem, Industrial and Manufacturing Engineering, Breakage, Particle aggregation, Aggregation, Parameter estimation, Environmental Chemistry, Artificial intelligence, Sensitivity (control systems), education, business

Abstract

Particle aggregation and breakage phenomena are widely found in various industries such as chemical, agricultural and pharmaceutical processes. In this study, a physics-informed neural network is developed for solving both the forward and inverse problems of particle aggregation and breakage processes. In this method, the population balance equation is directly embedded in the loss function of a neural network so that the network can be trained efficiently and fulfil physical constraints. For the forward problems, solutions of population balance equations are obtained through the optimization of the neural network where the predictions well match the analytical solutions. In the inverse modelling, the data-driven discovery of model parameters of population balance equations is investigated. The sensitivity regarding the selection of different neural network structures is also investigated. The developed population balance equations embedded with neural network approach is promising for solving inverse problems of particle aggregation and breakage processes with noisy observation data.

Published

2021

2. Modeling for the catalytic coupling reaction of carbon monoxide to diethyl oxalate in fixed-bed reactors: Reactor model and its applications.

Author

Ya-Ping Zhu, Song Tu, and Zheng-Hong Luo

Subjects

*MATHEMATICAL models, *CHEMICAL reactions, *CARBON monoxide, *OXALATES, *FIXED bed reactors, *SIMULATION methods & models, *TEMPERATURE effect

Abstract

A two-dimensional (2D) pseudo-homogeneous reactor model was developed to simulate the performance of fixed bed reactors for catalytic coupling reaction of carbon monoxide to diethyl oxalate. Reactor modeling was performed using a comprehensive numerical model consisting of two-dimensional coupled material and energy balance equations. A power law kinetic model was applied for simulating the catalytic coupling reaction with considering one main-reaction and two side-reactions. The validity of the reactor model was tested against the measured data from different-scale demonstration processes and satisfactory agreements between the model prediction and measured results were obtained. Furthermore, detailed numerical simulations were performed to investigate the effect of major operation parameters on the reactor behavior of fixed bed for catalytic coupling reaction of carbon monoxide to diethyl oxalate, and the result shows that the coolant temperature is the most sensitive parameter. [ABSTRACT FROM AUTHOR]

Published

2012

3. Design of a two-stage fluidized bed reactor for preparation of diethyl oxalate from carbon monoxide.

Author

Chong-Wen Jiang, Zu-Wei Zheng, Ya-Ping Zhu, and Zheng_Hong Luo

Subjects

*FLUIDIZED bed reactors, *OXALATES, *CARBON monoxide, *COUPLING reactions (Chemistry), *FLUID dynamics, *FEASIBILITY studies

Abstract

In this study, a two-stage fluidized bed reactor (TS-FBR) was designed as a new technology to produce diethyl oxalate (DEO) from carbon monoxide (CO) based on the catalytic coupling reaction. Computational fluid dynamics (CFD) approach was adopted to obtain the detailed flow field, the bubble behaviors in the TS-FBR, and further demonstrate the feasibility of the TS-FBR used in producing DEO from CO. Furthermore, the whole preparation process of DEO from CO using the optimum TS-FBR as the central unit is simulated using an advanced software tool, realizing the proper matching of coupling reaction and regeneration reaction. As a result, the realization of the whole preparation process is presented. [ABSTRACT FROM AUTHOR]

Published

2012