Fully Automated Workstation for Liquid−Liquid Equilibrium Measurements

Kuzmanovic, B.; Delden, M.L. van; Kuipers, and Norbert J. M.; Haan, A.B. de

doi:10.1021/je0340452

Cited by 19 publications

(18 citation statements)

References 5 publications

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“…Conventional experiments for the characterization of LLEs are time-consuming and need large sample volumes . Recent methods overcome these disadvantages by using smaller sample volumes and automation. , However, these methods employ standard analytical methods like gas or high-performance liquid chromatography which take a long time per sample and are therefore often the bottleneck in these new automated approaches. Additionally, an internal standard is needed in many cases, which increases the overall consumption of chemicals .…”

Section: Introductionmentioning

confidence: 99%

Efficient Determination of Liquid–Liquid Equilibria Using Microfluidics and Raman Microspectroscopy

Thien

Peters

Brands

et al. 2017

Ind. Eng. Chem. Res.

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Experimental liquid–liquid equilibrium (LLE) data are indispensable for many applications ranging from extraction column design to water partitioning of organics in the environment. However, conventional LLE experiments are time-consuming and need large sample volumes. Therefore, a measurement setup is presented for the time and material efficient determination of LLE data. The measurement setup combines the advantages of microfluidics and Raman microspectroscopy: The small dimensions of the used H-cell microchannel lead to rapid equilibration and small sample consumption; Raman microspectroscopy allows for rapid in situ quantification of all components. The measurement setup has successfully been validated by measuring the LLE of the ternary system cyclohexane–methanol–toluene. Excellent agreement with the literature data has been achieved. Thus, the developed setup allows for the efficient determination of liquid–liquid equilibria in multicomponent mixtures.

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Section: Introductionmentioning

confidence: 99%

Efficient Determination of Liquid–Liquid Equilibria Using Microfluidics and Raman Microspectroscopy

Thien

Peters

Brands

et al. 2017

Ind. Eng. Chem. Res.

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“…The jacketed glass cells and applied procedure for the measurement of the distribution ratio of the components between the aqueous and organic phase are already described in our earlier papers [11,18,19]. Hence, only the specific details for this case are given here.…”

Section: Extraction Equilibrium Measurementsmentioning

confidence: 99%

Reactive extraction of carboxylic acids from apolar hydrocarbons using aqueous solutions of sodium hydrogen carbonate with back-recovery using carbon dioxide under pressure

Kuzmanovic

Kuipers

Haan

et al. 2005

Separation and Purification Technology

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“…Common experimental methods and description of apparatuses used in determining the LLE data have been discussed in detail . A fully automated workstation, which allows more measurements to be performed per day, has been developed for LLE measurements …”

Section: Application In Conceptual Designmentioning

confidence: 99%

Visualization of High-Dimensional Liquid−Liquid Equilibrium Phase Diagrams

Harjo

Wibowo³

2004

Ind. Eng. Chem. Res.

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Liquid−liquid extraction is usually used along with other separation processes for the recovery of pure components. It is desirable that the liquid−liquid equilibrium (LLE) phase behavior, which is the thermodynamic basis for liquid−liquid extraction, be represented in a phase diagram. This is because the visualization of process limitations has a crucial role in the construction of feasible separation schemes for achieving the overall separation objective. However, because most applications involve multicomponent mixtures, visualization of the LLE phase diagram in its entirety becomes difficult or even impossible. Therefore, a visualization approach to represent high-dimensional LLE phase diagrams based on projections and cuts to reduce dimensionality is proposed. In such an approach, the liquid−liquid immiscibility regions are represented as a collection of projected tie lines. By superimposing the resulting diagram with any other map of process boundaries in composition space, such as a solid−liquid equilibrium phase diagram, one can clearly observe the possible use of liquid−liquid extraction in crossing the boundaries, an option that is not apparent when only numerical data are presented. Two common separation scenarios are used to demonstrate the applicability and advantages of this approach, particularly in illustrating the close interactions of liquid−liquid extraction with distillation and crystallization.

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Fully Automated Workstation for Liquid−Liquid Equilibrium Measurements

Cited by 19 publications

References 5 publications

Efficient Determination of Liquid–Liquid Equilibria Using Microfluidics and Raman Microspectroscopy

Efficient Determination of Liquid–Liquid Equilibria Using Microfluidics and Raman Microspectroscopy

Reactive extraction of carboxylic acids from apolar hydrocarbons using aqueous solutions of sodium hydrogen carbonate with back-recovery using carbon dioxide under pressure

Visualization of High-Dimensional Liquid−Liquid Equilibrium Phase Diagrams

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