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J. Stichlmair

Bio: J. Stichlmair is an academic researcher. The author has contributed to research in topics: Distillation & Pressure drop. The author has an hindex of 3, co-authored 3 publications receiving 314 citations.

Papers
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Journal ArticleDOI
TL;DR: In this article, a generalized model was developed for the prediction of pressure drop and flooding in packed columns in which gas and liquid flow countercurrently, and validated for a wide variety of packings, both random and structured.

254 citations

Journal ArticleDOI
TL;DR: Etude experimentale de la faisabilite de la distillation pour differents melanges ternaires (diagramme de phase et schema de l'installation for chaque cas)
Abstract: Etude experimentale de la faisabilite de la distillation pour differents melanges ternaires (diagramme de phase et schema de l'installation pour chaque cas)

46 citations

Journal Article
TL;DR: Etude experimentale de la faisabilite de la distillation pour differents melanges ternaires (diagramme de phase et schema de l'installation for chaque cas)
Abstract: Etude experimentale de la faisabilite de la distillation pour differents melanges ternaires (diagramme de phase et schema de l'installation pour chaque cas)

43 citations


Cited by
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Journal ArticleDOI
TL;DR: In this article, a second generation rate-based multistage separation unit operation model in Aspen Plus is proposed to model CO2 capture with aqueous monoethanolamine (MEA) solution.
Abstract: Rate-based process modeling technology has matured and is increasingly gaining acceptance over traditional equilibrium-stage modeling approaches. [Taylor et al. Chem. Eng. Prog. 2003, 99, 28−39] Recently comprehensive pilot plant data for carbon dioxide (CO2) capture with aqueous monoethanolamine (MEA) solution have become available from the University of Texas at Austin. The pilot plant data cover key process variables including CO2 concentration in the gas stream, CO2 loading in lean MEA solution, liquid to gas ratio, and packing type. In this study, we model the pilot plant operation with Aspen RateSep, a second generation rate-based multistage separation unit operation model in Aspen Plus. After a brief review on rate-based modeling, thermodynamic and kinetic models for CO2 absorption with the MEA solution, and transport property models, we show excellent match of the rate-based model predictions against the comprehensive pilot plant data and we validate the superiority of the rate-based models over t...

262 citations

Journal ArticleDOI
TL;DR: In this paper, a review of well-known fundamental work on the analysis of VLE diagrams is presented, along with a survey of less-known published results, especially from the Russian literature.

169 citations

Journal ArticleDOI
TL;DR: In this article, the experimental tests and the theoretical analysis on the chemical dehumidification of air by a liquid desiccant and desicant regeneration in an absorption/desorption column with random packing are presented.

162 citations

Journal ArticleDOI
TL;DR: In this paper, the authors review the most significant and physically sound models published in the literature for countercurrent liquid-supercritical fluid extraction and SFE of solid matrices, such as the linear driving force, shrinking core, broken and intact cells, and the combination of BIC and shrinking core models.
Abstract: The supercritical fluid extraction (SFE) of liquids and solid materials is gaining increasing interest and commercial application in last decades, most particularly under the recent concept of green chemistry and biorefinery. Hence, it is fundamental to provide adequate modeling of the SFE, in order to optimize operating conditions and simulate the global process. This work intends to review the most significant and physically sound models published in the literature for countercurrent liquid-supercritical fluid extraction and SFE of solid matrices, such as the linear driving force, shrinking core, broken and intact cells, and the combination of BIC and shrinking core models. The main assumptions and mass transfer expressions are presented and discussed.

160 citations

Journal ArticleDOI
TL;DR: In this article, the authors present practical solutions (in the case of entrainers which add no azeotropes) to two problems of industrial relevance: given a binary azeotrope which we want to separate into pure components, and a set of candidate entrainer, how do we determine which one is the best?
Abstract: In this article, we present practical solutions (in the case of entrainers which add no azeotropes) to two problems of industrial relevance: Given a binary azeotrope which we want to separate into pure components, and a set of candidate entrainers, how do we determine which one is the best? Also, for each of these entrainers, what is the flowsheet of the feasible separation sequence(s)? We obtain these solutions by analyzing in details the mechanisms by which heavy, intermediate and light entrainers make separation feasible, using the new notions of equivolatility curves, of isovolatility curves and of local volatility order. We show that the second question finds an easy solution from the volatility order diagram. This analysis shows that a good entrainer is a component which “breaks” the azeotrope easily (i.e., even when its concentration is small) and yields high relative volatilities between the two azeotropic constituents. Because these attributes can be easily identified in an entrainer from the equivolatility curve diagram of the ternary mixture azeotropic component #1 — azeotropic component #2 — entrainer, we can easily compare entrainers by examining the corresponding equivolatility curve diagrams. Finally, we demonstrate the validity and limits of this method with examples.

143 citations