References
- Liu, X.; Yang, B. Review and vista on drying theories of porous medium. Journal of China Agricultural University 2005, 10(4), 81–92.
- Naghavi, Z.; Moheb, A.; Ziaei-rad, S. Numerical simulation of rough rice drying in a deep-bed dryer using non-equilibrium model. Energy Conversion and Management 2010, 51(2), 258–264.
- Hu, Z.; Wang, H.; Xie, H.; Wu, F.; Chen, Y.; Cao, S. Mathematical models and model predictive control for crossflow grain drying[J]. Transactions of the Chinese Society for Agricultural Machinery 2009, 25(4), 96–102.
- Bourassa, J.; Ramachandran, R.P.; Paliwal, J.; Cenkowski, S. Drying characteristics and moisture diffusivity of distillers’ spent grains dried in superheated steam. Drying Technology 2015, 33(15–16), 2012–2018.
- Perez, J.H.; Tanaka, F.; Tanaka, F.; Hamanaka, D.; Uchino, T. Three-dimensional numerical modeling of convective heat transfer during shallow-depth forced-air drying of brown rice grains. Drying Technology 2015, 33(11), 1350–1359.
- Abasi, S.; Minaei, S. Effect of drying temperature on mechanical properties of dried corn. Drying Technology 2014, 32(7), 774–780.
- Ranjbaran, M.; Emadi, B.; Zare, D. CFD simulation of deep-bed paddy drying process and performance. Drying Technology 2014, 32(8), 919–934.
- ElGamal, R.; Ronsse, F.; Radwan, S.M.; Pieters, J.G. Coupling CFD and diffusion models for analyzing the convective drying behavior of a single rice kernel. Drying Technology 2014, 32(3), 311–320.
- Zielinska, M. Drying kinetics and physicochemical characteristics of laboratory-prepared corn/wheat distillers grains and solubles dried with superheated steam and hot air. Drying Technology 2015, 33(7), 831–846.
- Lutfy, O.F.; Selamat, H.; Noor, S.B.M. Intelligent modeling and control of a conveyor belt grain dryer using a simplified type 2 neuro-fuzzy controller. Drying Technology 2015, 33(10), 1210–1222.
- Oliveira Rocha, K.S.; Martins, J.H.; Martins, M.A.; Osorio Saraz, J.A.; Lacerda Filho, A.F. Three-dimensional modeling and simulation of heat and mass transfer processes in porous media, an application for maize stored in a flat bin. Drying Technology 2013, 31(10), 1099–1106.
- Tsotsas, E. Multiscale approaches to processes that combine drying with particle formation. Drying Technology 2015, 33(15–16), 1859–1871.
- Sudbrock, F.; Kruggel-Emden, H.; Wirtz, S.; Scherer, V. Convective drying of agitated silica gel and beech wood particle beds experiments and transient DEM-CFD simulations. Drying Technology 2015, 33(15–16), 1808–1820.
- Chen, X.D.; Putranto, A. Reaction engineering approach (REA) to modeling drying problems, recent development and implementations. Drying Technology 2015, 33(15–16), 1899–1910.
- Martinez-Martinez, V.; Gomez-Gil, J.; Stombaugh, T.S.; Montross, M.D. Moisture content prediction in the switchgrass (Panicum virgatum) drying process using artificial neural networks. Drying Technology 2015, 33(14), 1708–1719.
- Segura, L.A.; Badillo, G.M.; Alves-Filho, O. Microstructural changes of apples (Granny Smith) during drying, visual microstructural changes and possible explanation from capillary pressure data. Drying Technology 2014, 32(14), 1692–1698.
- Xiao, B.; Chang, J.; Huang, X.; Liu, X. A moisture transfer model for isothermal drying of plant cellular materials based on the pore network approach. Drying Technology 2014, 32(9), 1071–1081.
- Prakotmak, P.; Soponronnarit, S.; Prachayawarakorn, S. Design of porous banana foam mat to resist moisture migration using a 2-D stochastic pore network and its textural property. Drying Technology 2014, 32(8), 981–991.
- Gavriil, G.; Vakouftsi, E.; Coutelieris, F.A. Mathematical simulation of mass transport in porous media, an innovative method to match geometrical and transport parameters for scale transition. Drying Technology 2014, 32(7), 781–792.
- Dissa, A.O.; Compaore, A.; Tiendrebeogo, E.; Koulidiati, J. An effective moisture diffusivity model deduced from experiment and numerical solution of mass transfer equations for a shrinkable drying slab of microalgae spirulina. Drying Technology 2014, 32(10), 1231–1244.
- Huang, K.; Wang, X.; Liu, X.; Wang, X.; Yang, D. Construction of three-dimensional pore network in bulk grain. Drying Technology 2013, 31(15), 1871–1878.
- Vorhauer, N.; Tran, Q.T.; Metzger, T.; Tsotsas, E.; Prat, M. Experimental investigation of drying in a model porous medium, influence of thermal gradients. Drying Technology 2013, 31(8), 920–929.
- Wu, J.; Huang, S.; Sharp, D.H.; James, Glimm. Multiscale science, a challenge for the twenty-first century. Advances in Mechanics 1998, 28(4), 545–551.
- Perré, P. Multi-scale modeling of drying as a powerful extension of the macroscopic approach, application to solid wood and biomass processing. Drying Technology 2010, 28(8), 944–959.
- Zhang, B.; Xu, D.; Liu, Y.; Chen, H. Review of multi-scale evapotranspiration estimation and spatio-temporal scale expansion[J]. Transactions of the Chinese Society of Agricultural Engineering 2015, 31(6), 8–16.
- Prat, M. Recent advances in pore-scale models for drying of porous media. Chemical Engineering Journal 2002, 86(1–2), 153–164.
- Prat, M. Percolation model of drying under isothermal conditions in porous media. International Journal of Multiphase Flow 1993, 19, 691–704.
- Laurindo, J.B.; Prat, M. Numerical and experimental network study of evaporation in capillary porous media, drying rates. Chemical Engineering Science 1998, 53(12), 2257–2269.
- Segura, L.A.; Toledo, P.G. Pore-level modeling of isothermal drying of pore networks accounting for evaporation, viscous flow and shrinking. Drying Technology 2005, 23(9–11), 2007–2019.
- Yiotis, A.G.; Tsimpanogiannis, I.N.; Stubos, A.K.; Yortsos, Y.C. Pore-network study of characteristic periods in the drying of porous media. Journal of Colloid and Interface Science 2006, 297(2), 738–748.
- Prat, M. On the influence of pore shape, contact angle and film flows on drying of capillary porous media. International Journal of Heat and Mass Transfer 2007, 50(7–8), 1455–1468.
- Xiao, Z.; Yang, D.; Yuan, Y.; Yang, B.; Liu, X. Fractal pore network simulation on the drying of porous media. Drying Technology 2008, 26(6), 651–665.
- Surasani, V.K.; Metzger, T.; Tsotsa, E. A non-isothermal pore network drying model with gravity effect. Transport in Porous Media 2009, 80(3), 431–439.
- Yiotis, A.G.; Tsimpanogiannis, I.N.; Stubos, A.K. Fractal characteristics and scaling of the drying front in porous media, a pore network study. Drying Technology 2010, 28(8), 981–990.
- SanMartin, F.A.; Laurindo, J.B.; Segura, L.A. Pore-scale simulation of drying of a porous media saturated with a sucrose solution. Drying Technology 2011, 29(8), 873–887.
- Huang, X.; Qi, T.; Wang, Z.; Yang, D.; Liu, X. A moisture transmembrane transfer model for pore network simulation of plant materials drying. Drying Technology 2012, 30(15), 1742–1749.
- Shaeri, M.R.; Beyhaghi, S.; Pillai, K.M. On applying an external-flow driven mass transfer boundary condition to simulate drying from a pore-network model. International Journal of Heat and Mass Transfer 2013, 57(1), 331–344.
- Yuan, Y.; Yang, B.; Liu, X. Pore network simulation of slow isothermal drying of porous media [J]. Transactions of the Chinese Society for Agricultural Machinery 2007, 38(7), 62–66.
- Yuan, Y.; Xu, Y.; Liu, X. Numerical simulation and experiment on drying of corn material in bin[J]. Transactions of the Chinese Society for Agricultural Machinery 2009, 40(11), 119–123.
- Zhang, Y.; Li, C.; Ma, X.; Li, J.; Zou, X.; Wang, R. Experiment and numerical simulation of layer resistance parameters in dryer[J]. Transactions of the Chinese Society for Agricultural Machinery 2014, 45(7), 216–221.
- Cao, C.; Zhu, W. Computer simulation of the drying process for agricultural products. Beijing, Agricultural Press of China, 2000.