Thermodynamic balance vs. computational fluid dynamics approach for the outlet temperature estimation of a benchtop spray dryer
Milanesi, Andrea and Rizzuto, Francesco and Rinaldi, Maurizio and Foglio Bonda, Andrea and Segale, Lorena and Giovannelli, Lorella (2022) Thermodynamic balance vs. computational fluid dynamics approach for the outlet temperature estimation of a benchtop spray dryer. Pharmaceutics, 14 (2). 296. ISSN 1999-4923 (https://doi.org/10.3390/pharmaceutics14020296)
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Abstract
The use of design space (DS) is a key milestone in the quality by design (QbD) of pharmaceutical processes. It should be considered from early laboratory development to industrial production, in order to support scientists with making decisions at each step of the product's development life. Presently, there are no available data or methodologies for developing models for the implementation of design space (DS) on laboratory-scale spray dryers. Therefore, in this work, a comparison between two different modeling approaches, thermodynamics and computational fluid dynamics (CFD), to a laboratory spray dryer model have been evaluated. The models computed the outlet temperature (Tout) of the process with a new modeling strategy that includes machine learning to improve the model prediction. The model metrics calculated indicate how the thermodynamic model fits Tout data better than CFD; indeed, the error of the CFD model increases towards higher values of Tout and feed rate (FR), with a final mean absolute error of 10.43 K, compared to the 1.74 K error of the thermodynamic model. Successively, a DS of the studied spray dryer equipment has been implemented, showing how Tout is strongly affected by FR variation, which accounts for about 40 times more than the gas flow rate (Gin) in the DS. The thermodynamic model, combined with the machine learning approach here proposed, could be used as a valid tool in the QbD development of spray-dried pharmaceutical products, starting from their early laboratory stages, replacing traditional trial-and-error methodologies, preventing process errors, and helping scientists with the following scale-up.
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Item type: Article ID code: 79385 Dates: DateEvent27 January 2022Published27 January 2022Published Online21 January 2022AcceptedSubjects: Technology > Mechanical engineering and machinery Department: Faculty of Engineering > Mechanical and Aerospace Engineering
Faculty of Engineering > Design, Manufacture and Engineering ManagementDepositing user: Pure Administrator Date deposited: 31 Jan 2022 15:59 Last modified: 12 Dec 2024 12:40 URI: https://strathprints.strath.ac.uk/id/eprint/79385