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A Mass-Temperature Decoupled Discretization Strategy for Large-Scale Molecular-Level Kinetic Model
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  • Zhengyu Chen,
  • Dong Guan,
  • Xiaojie Zhang,
  • Ying Zhang,
  • Suoqi Zhao,
  • Quan Shi,
  • Chunming Xu,
  • Linzhou Zhang
Zhengyu Chen
China University of Petroleum Beijing

Corresponding Author:zychen_cup@163.com

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Dong Guan
China University of Petroleum Beijing
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Xiaojie Zhang
China University of Petroleum Beijing
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Ying Zhang
China University of Petroleum Beijing
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Suoqi Zhao
China University of Petroleum
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Quan Shi
China University of Petroleum-Beijing
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Chunming Xu
Chinese University of Petroleum
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Linzhou Zhang
China University of Petroleum Beijing
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Abstract

The molecular conversion of complex mixture involves a large number of species and reactions. The corresponding kinetic model is consist of a series of ordinary differential equations (ODEs) with severe stiffness, leading to an exponentially growing computational time. To reduce the computational time, we proposed a mass-temperature decoupled discretization strategy for a large-scale molecular-level kinetic model. The method separates the mass balance and heat balance calculations in the rigorous adiabatic reactor model and divided the reactor into several isothermal segments. After discretization, the differential equations for heat balance can be replaced by algebraic equations between nodes. We used a molecular-level diesel hydrotreating kinetic model as the case to validate the proposed method. We investigated the effects of temperature estimation methods and node number on the accuracy of the model. A good agreement between the discretization model and rigorous model was observed while the computational time was significantly shortened
Feb 2022Published in Chemical Engineering Science volume 249 on pages 117348. 10.1016/j.ces.2021.117348