Swelling of couscous grains under saturated conditions

The article presents a grain-scale experimental approach for the study of a model that swells granular food material. During the swelling phase, both the evolution of particle size using image analysis and the spatially resolved field of diffusion coefficient of water inside the grains were studied...

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Bibliographic Details
Published in:Journal of food engineering 2022-04, Vol.319, p.110910, Article 110910
Main Authors: De Richter, Sébastien Kiesgen, Gaudel, Naïma, Gaiani, Claire, Pascot, Arthur, Ferrari, Maude, Jenny, Mathieu
Format: Article
Language:English
Subjects:
Atmospheric and Oceanic Physics
Couscous grains
Fluid Dynamics
Fluid mechanics
General Physics
Geophysics
Mechanics
MRI measurements
Ocean, Atmosphere
Physics
Sciences of the Universe
Swelling
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Summary:The article presents a grain-scale experimental approach for the study of a model that swells granular food material. During the swelling phase, both the evolution of particle size using image analysis and the spatially resolved field of diffusion coefficient of water inside the grains were studied using MRI measurements. A concentrically penetration of water in the cross section of the grains was shown on images. The experimental results were compared to classical models from the literature used to predict the swelling of polymeric materials. A simple first-order kinetic equation was shown to be adequate to describe the size evolution during swelling. Thus, the results suggested that the swelling dynamics was a water uptake-limiting mechanism because of the existence of a gelatinous layer at the grain surface formed during the manufacturing process, as previously reported in the literature. [Display omitted] •MRI is an effective tool to investigate water distribution in granular food materials.•Water diffusion coefficient in grains is heterogeneously distributed in space.•Classical diffusive models from the literature cannot predict swelling dynamics.•Results suggest that the swelling dynamics is a water uptake-limiting mechanism.
ISSN:0260-8774
1873-5770
DOI:10.1016/j.jfoodeng.2021.110910