Software-guided microscale flow calorimeter for efficient acquisition of thermokinetic data

Frede, Timothy Aljoscha; Dietz, Marlene; Kockmann, Norbert

doi:10.1007/s41981-021-00145-6

Cited by 9 publications

(8 citation statements)

References 27 publications

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“…In current research, computational fluid dynamics simulations were integrated into the calorimetry workflow. 54 The aim of further work is to develop an automated workflow from design of experiments to evaluation that is supported by modeling and simulations. Ładosz et al 36 also used a microreactor from Little Things Factory, although this one was designed in-house.…”

Section: ■ Classification Of Calorimetersmentioning

confidence: 99%

“…In addition, the temporal and spatial resolution of the heat flow profile enabled the determination of the mixing time scales of the respective reactors in parallel to the heat of reaction. In current research, computational fluid dynamics simulations were integrated into the calorimetry workflow . The aim of further work is to develop an automated workflow from design of experiments to evaluation that is supported by modeling and simulations.…”

Section: Flow Calorimeters In the Literaturementioning

confidence: 99%

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Advances in Continuous Flow Calorimetry

Frede

Maier

Kockmann

et al. 2022

Org. Process Res. Dev.

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Calorimetric data from chemical reactions such as reaction enthalpy, adiabatic temperature rise, and activation energy are essential for reaction safety and scale-up from laboratory investigations to reactor design and operation. Typically, these data are gained from batch calorimeters with sophisticated setups and elaborate measurement procedures. Continuous flow calorimeters, compared with batch setups, have different mixing and heat transfer characteristics and enable harsh reaction conditions, particularly within microstructured reactors with their enhanced heat transfer capability. This review provides an overview of currently investigated and applied flow calorimeters in research and development in relation to existing concepts. Novel approaches for heat flux measurements as well as integrated sensors are presented. Safety aspects of flow chemistry are a main driver, but additionally, low material consumption is important in early process development. Limitations of the concepts are presented with a comprehensive literature overview of flow calorimetry to show that continuous flow calorimeters form a new tool in process development and safety engineering, particularly with microstructured devices and novel sensing techniques.

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Section: ■ Classification Of Calorimetersmentioning

confidence: 99%

Section: Flow Calorimeters In the Literaturementioning

confidence: 99%

Advances in Continuous Flow Calorimetry

Frede

Maier

Kockmann

et al. 2022

Org. Process Res. Dev.

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“…A commercially available microreactor from Little Things Factory GmbH (Elsoff, Germany) is investigated in the simulations. The LTF-MS reactor from the MR-Lab series is studied in this work, which is the scale-up version of the LTF type-S reactor, which was employed in the microcalorimeter in previous works [14,15,27]. A schematic representation of reactor is shown in Fig.…”

Section: Microreactormentioning

confidence: 99%

Reactor performance estimation in microscale flow calorimeter for rapid characterization of exothermic reactions

2022

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Continuous flow calorimeters are a promising tool in process development and safety engineering, especially for flow chemistry applications to characterize the heat release and kinetic parameters of rapid chemical reactions. In this study, the digital accompaniment of an isoperibolic flow calorimeter for characterization of exothermic reactions is presented. To support experimental planning and evaluation, computational fluid dynamic simulations are carried out for single-phase flow in the microreactor. The residence time distribution is obtained and used for estimation of conversion and temperature profiles along the microreactor channel. This leads to an integration of CFD simulations into the calorimeter’s software-guided workflow reducing the experimental effort regarding the determination of thermokinetic data. The approach is tested for a highly exothermic test reaction, which provides further hints for future investigations. Article highlights • Estimation of conversion and temperature profiles within a microscale calorimeter • Combination of CFD simulations and reactor performance estimation • Approach was tested for highly oxidation of sodium thiosulfate • Estimated conversion and temperature profiles are in good agreement with experimental data Graphical abstract

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“…Until today, only a few flow calorimeters have been described in literature and even fewer are commercially available [3]. Most of them are microreactor-like and work under almost isothermal conditions [3][4][5][6][7][8][9][10]. While micro-calorimeters are suitable to mimic microreactors, they are limited in describing flow chemistry at larger scale.…”

Section: Introductionmentioning

confidence: 99%