Thermodynamic Modeling of the Gas-Antisolvent (GAS) Process for Precipitation of Finasteride

Q4 Chemical Engineering

Journal of Chemical and Petroleum Engineering Pub Date : 2020-08-12 DOI:10.22059/JCHPE.2020.300747.1311

M. Najafi, N. Esfandiari, B. Honarvar, Z. A. Aboosadi

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引用次数: 3

Abstract

Experimental study the effect of GAS system conditions on the particle size distribution of finasteride (FNS) requires a thermodynamic model for the volume expansion process. In this study, the phase behavior of the binary system including carbon dioxide and Dimethyl sulfoxide and a ternary system comprising carbon dioxide, dimethyl sulfoxide, and Finasteride was studied. The Peng-Robinson equation of state was employed for evaluation of the fluid phases and a fugacity expression to represent the solid phase. By developing an accurate predictive model, the GAS operating conditions can be optimized to produce particles with no need for a large number of experiments. First, the critical properties of the FNS were evaluated by the group contribution methods. The method of Marrero and Gani was also selected to predict the normal boiling point, critical temperature, and critical pressure. The correlation of Edmister was chosen for the prediction of the acentric factor. The lowest pressures for the ternary system at 308, 318, 328 and 338 K were 7.49, 8.13, 8.51 and 9.03 MPa, respectively. The precipitation of the dissolved finasteride happened at these operating pressures.

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非那雄胺气-反溶剂(GAS)沉淀过程的热力学模型

实验研究气体系统条件对非那雄胺(FNS)粒径分布的影响需要建立体积膨胀过程的热力学模型。本文研究了二氧化碳和二甲亚砜二元体系以及二氧化碳、二甲亚砜和非那雄胺三元体系的相行为。用Peng-Robinson状态方程表示流体相，用逸度表达式表示固相。通过建立准确的预测模型，可以优化GAS的操作条件，从而在不需要大量实验的情况下产生粒子。首先，利用群贡献法对FNS的关键性能进行了评价。还选择了Marrero和Gani方法来预测正常沸点、临界温度和临界压力。选择Edmister的相关系数来预测离心因子。在308、318、328和338 K时，三元体系的最低压力分别为7.49、8.13、8.51和9.03 MPa。溶解的非那雄胺的沉淀发生在这些操作压力下。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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