References
- Hawlader, M.N.A.; Uddin, M.S.; Ho, J.C.; Teng, A.B.W. Drying characteristics of tomatoes. Journal of Food Engineering 1991, 14, 259–268.
- Ratti, C. Shrinkage during drying of foodstuffs. Journal of Food Engineering 1994, 23(1), 91–105.
- Wang, N.; Brennan, J.G. Changes in structure, density and porosity of potato during dehydration. Journal of Food Engineering 1995, 24(1), 61–76.
- McMinn, W.A.M.; Magee, T.R.A. Physical characteristics of dehydrated potatoes—Part I. Journal of Food Engineering 1997, 33(1), 37–48.
- Krokida, M.K.; Maroulis, Z.B. Effect of drying method on shrinkage and porosity. Drying Technology 1997, 15(10), 2441–2458.
- May, B.K.; Perré, P. The importance of considering exchange surface area reduction to exhibit a constant drying flux period in foodstuffs. Journal of Food Engineering 2002, 54, 271–282.
- Perré, P.; May, B.K. The existence of a first drying stage for potato proved by two independent methods. Journal of Food Engineering 2007, 78 1134–1140.
- Madiouli, J.; Sghaier, J.; Orteu, J.J.; Robert, L.; Lecomte, D.; Sammouda, H. Non-contact measurement of the shrinkage and calculation of porosity during the drying of banana. Drying Technology 2011, 29(12), 1358–1364.
- Groenewold, C.; Möser, C.; Groenewold, H.; Tsotsas, E. Determination of single-particle drying kinetics in an acoustic levitator. Chemical Engineering Journal 2002, 86(1–2), 217–222.
- Schiffter, H.; Lee, G. Single-Droplet evaporation kinetics and particle formation in an acoustic levitator. Part 1: Evaporation of water microdroplets assessed using boundary-layer and acoustic levitation theories. Journal of Pharmaceutical Science 2007, 96(9), 2274–2283.
- Perré, P.; May, B.K. A numerical drying model that accounts for the coupling between transfers and solid mechanics: Case of highly deformable products. Drying Technology 2001, 19, 1629–1643.
- Karunasena, H.C.P.; Senadeera, W.; Brown, R.J.; Gu, Y.T. A particle based model to simulate microscale morphological changes of plant tissues during drying. Soft Matter 2014, 10, 5249–5268.
- Oevermann, M.; Gerber, S.; Behrendt, F. Euler–Lagrange/DEM simulation of wood gasification in a bubbling fluidized bed reactor. Particuology 2009, 7(4), 307–316.
- Perré, P. Experimental device for the accurate determination of wood–water relations on micro-samples. Holzforschung 2007, 61, 419–429.
- Dreisbach, F.; Losch, H. Magnetic suspension balance for simultaneous measurement of a sample and the density of the measuring fluid. Journal of Thermal Analysis and Calorimetry 2000, 62, 515–521.
- Perré, P.; Houngan, A.C.; Jacquin, Ph. Mass diffusivity of beech determined in unsteady-state using a magnetic suspension balance. Drying Technology 2007, 25, 1341–1347.
- Perré, P.; Huber, F. Measurement of free shrinkage at the tissue level using an optical microscope with an immersion objective: Results obtained for Douglas fir (Pseudotsuga menziesii) and spruce (Picea abies), Annals of Forest Science 2007, 64, 255–265.
- Perré, P. MeshPore: A software able to apply image-based meshing techniques to anisotropic and heterogeneous porous media. Drying Technology 2005, 23, 1993–2006.
- van Meel, D.A. Adiabatic convection batch drying with recirculation of air. Chemical Engineering Science 1958, 9, 36–44.
- Ghiaus, A.G.; Margaris, D.P.; Papanikas, D.G. Mathematical modelling of the convective drying of fruits and vegetables. Journal of Food Science 1997, 62, 1154–1157.
- Sereno, A.M.; Medeiros, G.L. A simplified model for the prediction of drying rates for foods. Journal of Food Engineering 1990, 12, 1–11.
- Zhao, Y.; Poulsen, K.P. Diffusion in potato drying. Journal of Food Engineering 1988, 7, 249–262.
- Khan, A.A.; Vincent, J.F.V. Anisotropy of apple parenchyma. Journal of the Science of Food and Agriculture 1990, 52, 455–466.
- Joardder, M.U.; Kumar, C., Brown, R.J.; Karim, M.A. A micro-level investigation of the solid displacement method for porosity determination of dried food. Journal of Food Engineering 2015, 166, 156–164.