Kaibel column: Modeling, optimization, and conceptual design of multi-product dividing wall columns

Rawlings, Edna Soraya; Chen, Qi; Grossmann, Ignacio E.

doi:10.1016/j.compchemeng.2019.03.006

Cited by 18 publications

(3 citation statements)

References 21 publications

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“…While the case study shown here is relatively simple, the IDAES-CMF has been applied to simulating and optimizing complex chemical and energy related processes, such as the removal of CO 2 from power plant flue gas. [38] The IDAES-CMF has also been applied to a range of other problem types, such as conceptual design and process intensification [39] and dynamic real-time optimization and control, [40] and non-linear robust optimization. [41] F I G U R E 1 8 Distribution of capital and operating cost with respect to the uncertainty considered in the kinetic parameters…”

Section: Step 11: Optimization Under Uncertaintymentioning

confidence: 99%

The IDAES process modeling framework and model library—Flexibility for process simulation and optimization

Lee

Ghouse

Eslick

et al. 2021

J Adv Manuf & Process

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Energy systems and manufacturing processes of the 21st century are becoming increasingly dynamic and interconnected, which require new capabilities to effectively model and optimize their design and operations. Such next generation computational tools must leverage state-of-the-art techniques in optimization and be able to rapidly incorporate new advances. To address these requirements, we have developed the Institute for the Design of Advanced Energy Systems (IDAES) Integrated Platform, which builds on the strengths of both process simulators (model libraries) and algebraic modeling languages (advanced solvers). This paper specifically presents the IDAES Core Modeling Framework (IDAES-CMF), along with a case study demonstrating the application of the framework to solve process optimization problems. Capabilities provided by this framework include a flexible, modifiable, open-source platform for optimization of process flowsheets utilizing state-of-the-art solvers and solution techniques, fully open and extensible libraries of dynamic unit operations models and thermophysical property models, and integrated support for superstructure-based conceptual design and optimization under uncertainty.

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Section: Step 11: Optimization Under Uncertaintymentioning

confidence: 99%

The IDAES process modeling framework and model library—Flexibility for process simulation and optimization

Lee

Ghouse

Eslick

et al. 2021

J Adv Manuf & Process

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“…Luyben demonstrated that the energy consumption of distillation columns can increase, instead of decrease, when more stages are used due to the pressure drop increase by the addition of stage(s). Second, in the thermally coupled distillation configurations, like those in dividing wall columns (DWCs) or side rectifier columns, which are appearing economically attractive and have drawn much attention recently, − vapor split must take place, and the distribution of the split vapor flows up into the two corresponding column sections is a direct result of the balance between the pressure drops of the two column sections …”

Section: Introductionmentioning

confidence: 99%

Equation-Oriented Optimization of a Distillation Column Considering Stage Hydraulics

Feng

Luo

Yuan

2020

Ind. Eng. Chem. Res.

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Accurate prediction of pressure drops around trays or packing sections is crucial for the optimal design of distillation columns. However, simultaneous optimization of all operating and structural parameters with the rigorous hydraulics consideration in MESH model is still difficult because of both the convergence for the stage number and integer optimization problem. In the present work, a rigorous equilibrium stage-based pseudotransient distillation model considering stage hydraulics is developed in the equation-oriented environment. By applying the steady-state optimization algorithm assisted by pseudotransient models [Ma, Y.; Luo, Y.; Ma, X.; Yang, T.; Chen, D.; Yuan, X. Fast Algorithms for Equation-Oriented Flowsheet Simulation and Optimization Using Pseudo-Transient Models. Ind. Eng. Chem. Res. 2018, 57 (42), 14124–14142], and the bypass efficiency method [Dowling, A. W.; Biegler, L. T, Rigorous Optimization Based Synthesis of Distillation Cascades without Integer Variables. In Computer-Aided Chemical Engineering; Klemeš, J. J.; Varbanov, P. S.; Lieu, P. Y., Eds.; Elsevier: Amsterdam, Netherlands, 2014; Vol. 33, pp 55–60], the convergence problem and stage number optimization problem are effectively solved. In addition, an optimization framework for DWCs is proposed, which can consider simultaneously tray hydraulic conditions and find the optimal position of the dividing wall by systematically balancing the pressure drops of the column sections in the two sides of the wall.

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“…To handle disturbance and implementation error of DWCs, Luo et al [22] developed an online optimization method assisted with steady-state analysis. In addition, a sequential quadratic method using the mixed integer linear programming problem [23] or MINLP [24] approach was also used for conceptual design of DWCs. However, this kind of method is difficult to implement.…”

mentioning

confidence: 99%

A comprehensive economic optimization methodology of divided wall columns for biopolyol separation

Chen

et al. 2020

R. Soc. open sci.

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Global energetic and environmental crises have attracted worldwide attention in recent years. Biomass is an important direction of development for limiting greenhouse gas emissions and replacing fossil fuel. As downstream products of biomass, some industrially valuable polyols are costly to separate via conventional distillation due to their near volatility. The use of fully heat-integrated divided wall columns (DWCs), which carry energy and equipment investment savings, is a promising technique for purifying biopolyol products. However, the design of DWCs is complex because of the greater freedom of units, so the optimization of all variables is essential to minimize the cost of separation. A response surface methodology (RSM)-based Box-Behnken design (BBD) was proposed and applied to study the interactions between groups of factors and the effects of variables on total annual cost (TAC) savings. The optimization of global variables with RSM was confirmed to be a powerful and reliable method, and the TAC savings reached 41.09% compared to conventional distillation. In short, efficient design, lower costs and energy savings for polyol separation will promote the wide application of environmentally friendly biopolyol.

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Kaibel column: Modeling, optimization, and conceptual design of multi-product dividing wall columns

Cited by 18 publications

References 21 publications

The IDAES process modeling framework and model library—Flexibility for process simulation and optimization

The IDAES process modeling framework and model library—Flexibility for process simulation and optimization

Equation-Oriented Optimization of a Distillation Column Considering Stage Hydraulics

A comprehensive economic optimization methodology of divided wall columns for biopolyol separation

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