Batch distillation performance improvement through vessel holdup redistribution—Insights from two case studies

IF 3 Q2 ENGINEERING, CHEMICAL Digital Chemical Engineering Pub Date : 2024-09-16 DOI:10.1016/j.dche.2024.100187

Surendra Beniwal, Sujit S. Jogwar

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Abstract

Middle vessel batch distillation (MVBD) is an energy-efficient configuration for separation of a ternary mixture. This paper focuses on improving the performance of this configuration through dynamic optimization of vessel holdup. Initially, a performance measure accounting for separation and energy efficiency is defined to characterize an operational policy. Subsequently, this measure is maximized by dynamically redistributing holdup in the three (top, middle and bottom) vessels. With the help of two case studies, the impact of various policy decisions and market conditions (such as initial feed distribution and relative cost of products and energy) on the optimal operating policy is analyzed. Specifically, the improvement obtained via holdup redistribution is explained with the help of fundamental concepts of distillation. Lastly, the performance of the proposed approach is compared with some of the existing methods and validated through rigorous simulations.

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通过容器容积再分配提高批量蒸馏性能--两个案例研究的启示

中间容器分批蒸馏（MVBD）是一种用于分离三元混合物的节能配置。本文的重点是通过动态优化容器容积来提高这种配置的性能。首先，定义了分离和能效的性能指标，以描述操作策略的特征。随后，通过动态地重新分配三个（顶部、中部和底部）容器中的滞留量来最大化这一指标。在两个案例研究的帮助下，分析了各种政策决定和市场条件（如初始进料分配以及产品和能源的相对成本）对最优运行政策的影响。具体而言，借助蒸馏的基本概念解释了通过滞留再分配获得的改进。最后，将所提出方法的性能与现有的一些方法进行了比较，并通过严格的模拟进行了验证。

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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来源期刊

Digital Chemical Engineering

CiteScore

3.10

自引率

0.00%

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