Experimental methods in chemical engineering: Micro‐reactors

Macchi, Arturo; Plouffe, Patrick; Patience, Gregory S.; Roberge, Dominique M.

doi:10.1002/cjce.23525

Cited by 26 publications

(19 citation statements)

References 101 publications

(98 reference statements)

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“…Pharmaceutical applications belong mostly to the blue cluster including drug delivery, cancer, in vivo, in vitro, tissue distribution, and skeletal muscle. Continuous flow chemistry has been applying RTD to monitor and optimize the contact time and design micro‐mixers …”

Section: Applicationsmentioning

confidence: 99%

Experimental methods in chemical engineering: Residence time distribution—RTD

2020

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Reactor performance, solids‐(gas)‐mixing, flow through porous media, distillation columns, or through granulators improve as the fluid dynamics approach ideal plug flow. The residence time distribution (RTD) is a diagnostic measure of how close fluid flow approaches ideal conditions. The technique introduces a step change to the inlet concentration—a Dirac‐δ function, Heaviside step function, or a rectangular pulse (bolus)—while high frequency detectors monitor the concentration along the vessel and/or at the exit. The effluent concentration profile spreads due to the variance in the process lines leading to the vessel and at the exit, the detector response, and the system. We quantify how much each of these contributes to the overall variance in a fluidized bed with 9 g of fluid cracking catalyst in 8 mm diameter quartz tubes. The injection variance is lowest for a GC sample loop configuration, compared to a 3‐way valve or 4‐way valve geometry. RTD measurements detect bypassing due to dead zones in vessels and the axial‐dispersion model and continuous stirred‐tank model to characterize deviation from plug flow. However, when the contribution to variance from the ancillary lines and detector is large compared to the system, the uncertainty in the model parameters is high. Research on RTD fundamentals concentrate on boundary conditions while, here, we focus on experimental errors: mechanical, physicochemical mathematical, and instrumental.

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Section: Applicationsmentioning

confidence: 99%

Experimental methods in chemical engineering: Residence time distribution—RTD

2020

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“…Macchi et al [ 36 ] recently reviewed microreactor design, technical features, challenges, and points of technological uncertainty within the scope of continuous synthesis of fine chemicals and pharmaceuticals, ranging from laboratory applications to commercial scale. They observe that despite the fact that the pharmaceutical industry is increasingly applying flow chemistry technologies to the synthesis of their products, the commercial application of intensified/miniaturized continuous flow technologies remain limited mostly due to lack of information and technology.…”

Section: Process Intensification and Microreactorsmentioning

confidence: 99%

“…In the literature there are several examples of reviews dedicated to PI that are technology specific. Examples include static mixers, [15][16][17] cavitational reactors, [18] flow reactors, [19][20][21][22][23][24] membrane gas separation and reactors, [25][26][27] intensified separations, [28,29] microengineered reactors, [30][31][32][33][34][35][36][37] microwave-assisted chemistry, [22,38,39] and low frequency ultrasound processes, [40][41][42] to cite a few. There are, however, fewer reviews on PI as an innovative approach to chemical engineering design in general, each focusing on different aspects of it.…”

Section: Introductionmentioning

confidence: 99%

Process intensification connects scales and disciplines towards sustainability

Boffito

Rivas

2020

Can J Chem Eng

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Process intensification (PI) has been established as a cluster of technologies able to produce more with less. While scientists around the globe advocate for new semantics that are increasingly tied to the notion of sustainability, what does the literature data say about PI? A Vosviewer bibliometric map of PI displays it as closely linked to the subjects of design, optimization, gas-to-liquid technologies, mass transfer, catalysis, and kinetics. We analyze the relationship between PI and these subjects while identifying misconceptions about the intensifying potential of some of them, as is the case for process optimization. We provide examples and summarize the recent technological trends for all these cases. Finally, we provide an outlook on the future of PI in which we identify elements that will be key to accelerate the adoption of PI technologies at the commercial scale.

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“…We propose a toolbox concept to select reactor types in order to optimize reactive conditions and then scale up, with relative confidence, through the clinical phases of pharmaceuticals. Research in the field is concentrated into five clusters: catalysis and kinetics; nano‐particles; systems and microfluidics; chemistry and organic synthesis; and mass transfer and micro‐channels …”

mentioning

confidence: 99%

Issue Highlights

2019

Can J Chem Eng

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The bulk chemical industry continues to build bigger plants but micro-reactors represent a paradigm shift in manufacturing: they contribute to process intensification-productivity an order of magnitude (and more) greater in a smaller footprint-with sub-millimetre lateral dimensions that reduce heat and mass transfer boundary layers. We propose a toolbox concept to select reactor types in order to optimize reactive conditions and then scale up, with relative confidence, through the clinical phases of pharmaceuticals. Research in the field is concentrated into five clusters: catalysis and kinetics; nano-particles; systems and microfluidics; chemistry and organic synthesis; and mass transfer and micro-channels. [1]

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Experimental methods in chemical engineering: Micro‐reactors

Cited by 26 publications

References 101 publications

Experimental methods in chemical engineering: Residence time distribution—RTD

Experimental methods in chemical engineering: Residence time distribution—RTD

Process intensification connects scales and disciplines towards sustainability

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