Global optimization of multicomponent distillation configurations: 1. Need for a reliable global optimization algorithm

Nallasivam, Ulaganathan; Shah, Vishesh H.; Shenvi, Anirudh A.; Tawarmalani, Mohit

doi:10.1002/aic.13875

Cited by 27 publications

(30 citation statements)

References 28 publications

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“…Both aspects, however, are beyond the scope of this paper. Inaccuracies induced by the solution method are exemplified by the following case: It is easily possible to discard a good design option when a gradientbased optimization algorithm applied to a nonconvex problem terminates in a poor local optimum, also see [17]. This last problem can be addressed by making decisions based on globally optimal solutions, which is possible by applying deterministic global optimization algorithms as demonstrated in this work.…”

mentioning

confidence: 93%

Deterministic global optimization in conceptual process design of distillation and melt crystallization

Kunde

Michaels

Mićović

et al. 2016

Chemical Engineering and Processing: Process Intensification

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mentioning

confidence: 93%

Deterministic global optimization in conceptual process design of distillation and melt crystallization

Kunde

Michaels

Mićović

et al. 2016

Chemical Engineering and Processing: Process Intensification

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“…The total vapor duty requirement calculation at minimum reflux for any configuration is formulated as a nonlinear programming (NLP) problem based on vapor duty estimation using Underwood's method; and NLP optimization solvers such as GAMS/BARON guarantee that each configuration is solved to global optimality . For illustration purposes, we focus on ideal saturated liquid feed mixture separations.…”

Section: Comparing Performances Of Hmp Configurations With the Ftc Comentioning

confidence: 99%

Minimum energy of multicomponent distillation systems using minimum additional heat and mass integration sections

2018

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Heat and mass integration to consolidate distillation columns in a multicomponent distillation configuration can lead to a number of new energy efficient and cost-effective configurations. In this work, a powerful and simple-to-use fact about heat and mass integration is identified. The newly developed heat and mass integrated configurations, which we call as HMP configurations, involve first introducing thermal couplings to all intermediate transfer streams, followed by consolidating columns associated with a lighter pure product reboiler and a heavier pure product condenser. A systematic method of enumerating all HMP configurations is introduced. The energy savings of HMP configurations is compared with the well-known fully thermally coupled (FTC) configurations. HMP configurations can have very similar and sometimes even the same minimum total vapor duty requirement as the FTC configuration is demonstrated, while using far less number of column sections, intermediate transfer streams, and thermal couplings than the FTC configurations. Figure 3. (a) A configuration derived from the configuration in Figure 2c by introducing thermal couplings at all submixtures; (b) A HMP configuration that is thermodynamically equivalent to the configuration in Figure 3a.Note that the thermal coupling at submixture DEF of Figure 7a is converted into a liquid-only transfer stream19 in Figure 7b, indicated by the curved arrow.Figure 9. (a) One possible operable dividing wall column drawn from the FTC configuration of Figure 8a using the methodology of Madenoor Ramapriya et al. 24,25 Notice that this dividing wall column uses three dividing walls and nine intermediate transfer streams; (b) one possible operable dividing wall column version synthesized from the HMP configuration of Figure 8b; (c) one possible operable dividing wall column version synthesized from the HMP configuration of Figure 8c. Notice that both dividing wall columns of Figures 8b, c use only 2 dividing walls and 5 intermediate transfer streams.

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“…We compared the overall minimum vapor requirement of these two operating‐modes of the FTC DWC for 120 ideal saturated liquid feed mixtures; given by eight unique relative volatility combinations of easy/difficult separation between any two components (Table ), along with 15 representative feed compositions (Table ) that were chosen to span the composition space. For each of these ideal feed mixtures, the two operating‐modes (Figures b and 8) are optimized (with a tolerance of 0.001 for convergence using BARON) using the Global Minimization Algorithm, an approach that determines the globally minimum total vapor requirement of a distillation configuration based on the Underwood's equations, under assumptions of infinite trays and constant relative volatilities between components. The pure products are assumed to be withdrawn as saturated liquids.…”

Section: Heat Duty Of Easy‐to‐operate Dwcs With Only Liquid Transfersmentioning

confidence: 99%

Thermal coupling links to liquid‐only transfer streams: An enumeration method for new FTC dividing wall columns

Ramapriya

Tawarmalani

2015

AIChE Journal

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Novel dividing wall columns (DWCs) can be obtained by converting thermal couplings to liquid-only transfer streams. Here, we develop a simple four-step method to generate a complete set of DWCs containing n 2 2 dividing walls, for a given n-component fully thermally coupled (FTC) distillation. Among the novel DWCs, some easy-to-operate DWCs possess the property that the vapor flow in every section of the DWC can be controlled during operation by means that are external to the column. We develop a simple method to enumerate all such easy-to-operate DWCs. We expect that the easy-to-operate DWCs can be operated close-to-optimality; leading to a successful industrial implementation of the n-component (n ! 3) FTC distillation in the form of a DWC. As an illustration, we show figures of all easy-to-operate DWCs with two dividing walls for the four-component FTC distillation.

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Global optimization of multicomponent distillation configurations: 1. Need for a reliable global optimization algorithm

Cited by 27 publications

References 28 publications

Deterministic global optimization in conceptual process design of distillation and melt crystallization

Deterministic global optimization in conceptual process design of distillation and melt crystallization

Minimum energy of multicomponent distillation systems using minimum additional heat and mass integration sections

Thermal coupling links to liquid‐only transfer streams: An enumeration method for new FTC dividing wall columns

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