Process Optimization of Para-xylene Crystallization Separation Process via Morphology Approach, Multi-dimensional Population Balance Equation, and Equation-Oriented Models

Zhenxing Cai; Hui Zhao; Pingxin Li; Xiaobo Chen; Chaohe Yang

doi:10.1021/acsomega.3c00069

Process Optimization of Para-xylene Crystallization Separation Process via Morphology Approach, Multi-dimensional Population Balance Equation, and Equation-Oriented Models

ACS Omega. 2023 Mar 31;8(14):12899-12910. doi: 10.1021/acsomega.3c00069. eCollection 2023 Apr 11.

Authors

Zhenxing Cai¹, Hui Zhao¹, Pingxin Li¹, Xiaobo Chen¹, Chaohe Yang¹

Affiliation

¹ State Key Laboratory of Heavy Oil Processing, China University of Petroleum Huadong, Qingdao 266580, China.

Abstract

An activity coefficient-based model was proposed to predict pertinent saturated concentrations in organic solid-liquid equilibrium, and the binary parameters of xylene mixtures were experimentally obtained. Also, a novel monocular 3D reconstruction technique was developed to measure crystal size and applied to derive the kinetics of nucleation and growth of para-xylene crystals. Subsequently, a multi-dimensional population balance equation was used to predict the particle size distribution in the crystallizer and an algorithm was designed to simulate and optimize the economic benefit of the crystallization separation process. Consequently, it became possible to predict the optimal coolant flowrate and inlet temperature, as well as the feed flowrate for a crystallization process with given operating conditions and device parameters.