Continuous slug flow crystallization: Impact of design and operating parameters on product quality

[Display omitted] •Plug-flow-like RTD for slug flow crystallizer holds for whole operating window.•Innovative cooling concept enables smooth cooling from 50 to 31°C.•Reproducible product quality and no fouling by using seed crystals.•Crystal growth of 240μm despite residence time of 10min due to hig...

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Veröffentlicht in:	Chemical engineering research & design 2021-06, Vol.170, p.290-303
Hauptverfasser:	Termühlen, Maren, Etmanski, Matthias Markus, Kryschewski, Ines, Kufner, Anne Cathrine, Schembecker, Gerhard, Wohlgemuth, Kerstin
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Sprache:	eng
Schlagworte:	Agglomeration Alanine Continuous crystallization Cooling Cooling rate Crystal size distribution Crystallization Design parameters Diameters Flow stability Flow velocity Heat transfer Nucleation Particle size distribution Plug flow Product quality Quality control Residence time distribution Single crystals Slug flow Slug flow crystallization Solid phases Studies Supersaturation Time measurement
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creator	Termühlen, Maren Etmanski, Matthias Markus Kryschewski, Ines Kufner, Anne Cathrine Schembecker, Gerhard Wohlgemuth, Kerstin
description	[Display omitted] •Plug-flow-like RTD for slug flow crystallizer holds for whole operating window.•Innovative cooling concept enables smooth cooling from 50 to 31°C.•Reproducible product quality and no fouling by using seed crystals.•Crystal growth of 240μm despite residence time of 10min due to high cooling rate.•Less agglomeration for high volume flow rates. A slug flow crystallizer for cooling crystallization with focus on enhanced product quality control in terms of narrow particle size distribution (PSD) was designed and characterized. Emphasis was put on slug flow stability while maintaining a convex shape of slugs to make use of the advantage of a narrow residence time distribution. Measurements of the latter one showed plug-flow-like behavior for the liquid and solid phase independent of the operating conditions within the range investigated. A tube-in-tube temperature concept led to smooth cooling from 50 to 31°C avoiding supersaturation peaks. Seeded cooling crystallization of aqueous l-alanine solution successfully led to reproducible product PSDs avoiding secondary nucleation. Thereby the crystals’ median diameter was increased by 240μm. Within a residence time of 10.5min only, a relative process yield of approximately 83% was achieved. To identify optimized operating conditions for narrow PSD and reduced agglomeration, the effect of total volume flow rate, slug length, and cooling rate on the PSD and agglomeration degree was quantified. A high flow rate (40mLmin−1) and a high cooling rate (3.6Kmin−1) reduced agglomeration to its minimum and shifted the size distribution of single crystals without its broadening by in average 90μm.
doi_str_mv	10.1016/j.cherd.2021.04.006
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A slug flow crystallizer for cooling crystallization with focus on enhanced product quality control in terms of narrow particle size distribution (PSD) was designed and characterized. Emphasis was put on slug flow stability while maintaining a convex shape of slugs to make use of the advantage of a narrow residence time distribution. Measurements of the latter one showed plug-flow-like behavior for the liquid and solid phase independent of the operating conditions within the range investigated. A tube-in-tube temperature concept led to smooth cooling from 50 to 31°C avoiding supersaturation peaks. Seeded cooling crystallization of aqueous l-alanine solution successfully led to reproducible product PSDs avoiding secondary nucleation. Thereby the crystals’ median diameter was increased by 240μm. Within a residence time of 10.5min only, a relative process yield of approximately 83% was achieved. To identify optimized operating conditions for narrow PSD and reduced agglomeration, the effect of total volume flow rate, slug length, and cooling rate on the PSD and agglomeration degree was quantified. A high flow rate (40mLmin−1) and a high cooling rate (3.6Kmin−1) reduced agglomeration to its minimum and shifted the size distribution of single crystals without its broadening by in average 90μm.</description><identifier>ISSN: 0263-8762</identifier><identifier>EISSN: 1744-3563</identifier><identifier>DOI: 10.1016/j.cherd.2021.04.006</identifier><language>eng</language><publisher>Rugby: Elsevier B.V</publisher><subject>Agglomeration ; Alanine ; Continuous crystallization ; Cooling ; Cooling rate ; Crystal size distribution ; Crystallization ; Design parameters ; Diameters ; Flow stability ; Flow velocity ; Heat transfer ; Nucleation ; Particle size distribution ; Plug flow ; Product quality ; Quality control ; Residence time distribution ; Single crystals ; Slug flow ; Slug flow crystallization ; Solid phases ; Studies ; Supersaturation ; Time measurement</subject><ispartof>Chemical engineering research & design, 2021-06, Vol.170, p.290-303</ispartof><rights>2021 Institution of Chemical Engineers</rights><rights>Copyright Elsevier Science Ltd. 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A slug flow crystallizer for cooling crystallization with focus on enhanced product quality control in terms of narrow particle size distribution (PSD) was designed and characterized. Emphasis was put on slug flow stability while maintaining a convex shape of slugs to make use of the advantage of a narrow residence time distribution. Measurements of the latter one showed plug-flow-like behavior for the liquid and solid phase independent of the operating conditions within the range investigated. A tube-in-tube temperature concept led to smooth cooling from 50 to 31°C avoiding supersaturation peaks. Seeded cooling crystallization of aqueous l-alanine solution successfully led to reproducible product PSDs avoiding secondary nucleation. Thereby the crystals’ median diameter was increased by 240μm. Within a residence time of 10.5min only, a relative process yield of approximately 83% was achieved. To identify optimized operating conditions for narrow PSD and reduced agglomeration, the effect of total volume flow rate, slug length, and cooling rate on the PSD and agglomeration degree was quantified. 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subjects	Agglomeration Alanine Continuous crystallization Cooling Cooling rate Crystal size distribution Crystallization Design parameters Diameters Flow stability Flow velocity Heat transfer Nucleation Particle size distribution Plug flow Product quality Quality control Residence time distribution Single crystals Slug flow Slug flow crystallization Solid phases Studies Supersaturation Time measurement
title	Continuous slug flow crystallization: Impact of design and operating parameters on product quality
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