Numerical Investigation of the Chilling of Food Products by Air-Mist Spray
Spray chilling using air-mist nozzles has received
much attention in the food processing industry because of the
benefits it has shown over forced air convection. These benefits
include an increase in the heat transfer coefficient and a reduction in
the water loss by the product during cooling. However, few studies
have simulated the heat transfer and aerodynamics phenomena of the
air-mist chilling process for optimal operating conditions. The study
provides insight into the optimal conditions for spray impaction, heat
transfer efficiency and control of surface flooding. A computational
fluid dynamics model using a two-phase flow composed of water
droplets injected with air is developed to simulate the air-mist
chilling of food products. The model takes into consideration
droplet-to-surface interaction, water-film accumulation and surface
runoff. The results of this study lead to a better understanding of the
heat transfer enhancement, water conservation, and to a clear
direction for the optimal design of air-mist chilling systems that can
be used in commercial applications in the food and meat processing
industries.
[1] G. Alvarez, and D. Flick, "Analysis of Heterogeneous Cooling of
Agricultural Products Inside Bins - Part I: Aerodynamic Study,"
Journal of Food Engineering, vol. 39, no. 3, pp. 227-237, 1999.
[2] G. Alvarez, and D. Flick, "Analysis of Heterogeneous Cooling of
Agricultural Products Inside Bins - Part II: Thermal Study," Journal of
Food Engineering, vol. 39, no. 3, pp. 239-245, 1999.
[3] F. A. Ansari, and S. Y. Khan, "Application Concept of Variable
Effective Surface Film Conductance for Simultaneous Heat and Mass
Transfer Analysis during Air Blast Cooling of Food," Energy
Conversion and Management, vol. 40, no. 5, pp. 567-574, 1999.
[4] S. Chuntranuluck, C. M. Wells, and A. C. Cleland, "Prediction of
Chilling Times of Foods in Situations Where Evaporative Cooling is
Significant - Part 2. Experimental Testing," Journal of Food
Engineering, vol. 37, no. 2, pp. 127-141, 1998.
[5] C. Dirita, M. V. De Bonis, and G. Ruocco, "Analysis of Food Cooling
by Jet Impingement Including Inherent Conduction," Journal of Food
Engineering, vol. 81, no. 1, pp. 12-20, 2007.
[6] I. Allais, G. Alvarez, and D. Flick, "Modeling Cooling Kinetics of a
Stack of Spheres During Mist Chilling," Journal of Food Engineering,
vol. 72, no. 2, pp. 197-209, 2006.
[7] I. Allais, and G. Alvarez, "Analysis of Heat Transfer During Mist
Chilling of a Packed Bed of Spheres Simulating Foodstuffs," Journal of
Food Engineering, vol. 49, no. 1, pp. 37-47, 2001.
[8] P. M. Abdul Majeed, P.M., "Analysis of Heat Transfer during Hydrair
Cooling of Spherical Food Products," International Journal of Heat and
Mass Transfer, vol. 24, pp. 323-333, 1981.
[9] P. Mallikarjunan, and G. S. Mittal, "Heat and Mass Transfer during Beef
Carcass Chilling - Modeling and Simulation," Journal of Food
Engineering, vol. 23, no. 2, pp. 277-292, 1994.
[10] A. Kuitche, and J. D. Daudin, "Modeling of Temperature and Weight
Loss Kinetics during Meat Chilling for Time-Variable Conditions using
an Analytical-Based Method - I. The Model and its Sensitivity to
Certain Parameters," Journal of Food Engineering, vol. 28, no. 1, pp.
55-84, 1996.
[11] S. D. M. Jones, and W. M. Robertson, "The Effects of Spray-Chilling
Carcasses on the Shrinkage and Quality of Beef," Meat Science, vol. 24,
no. 3, pp. 177-188, 1988.
[12] K. J. Kinsella, J. J. Sheridan, T. A. Rowe, F. Butler, A. Delgado, A. Q.
Ramirez, I. S. Blair, and D. A. McDowell, "Impact of a Noval Spray-
Chilling System on Surface Microflora, Water Activity and Weight Loss
during Beef Carcass Chilling," Food Microbiology, vol. 23, no. 5, pp.
483-490, 2006.
[13] P. E. Strydom, and E. M. Buys, "The Effects of Spray-Chilling on
Carcass Mass Loss and Surface Associated Bacteriology," Meat Science,
vol. 39, no. 2, pp. 265-276, 1995.
[14] M. Fabbri, S. Jiang, and V. K. Dhir, "Comparative Study of Spray and
Multiple Micro Jets Cooling for High Power Density Electronic
Applications," Proceedings of IMECE-03, 2003 ASME International
Mechanical Engineering Congress and Exposition, Washington, D.C.
[15] J. J. Spillman, "Spray Impaction, Retention and Adhesion: an
Introduction to Basic Characteristics," Pesticide Science, vol. 15, no. 2,
pp. 97-106, 1984.
[16] M. Schatzmann, "Wind Tunnel Modeling of Fog Droplet Deposition on
Cylindrical Obstacles," Journal of Wind Engineering and Industrial
Aerodynamics, vol. 83, no. 1, pp. 371-380, 1999.
[17] R. J. Issa, and S. C. Yao, "A Numerical Model for Spray-Wall
Impactions and Heat Transfer at Atmospheric Conditions," Journal of
Thermophysics and Heat Transfer, vol. 19, no. 4, pp. 441-447, 2005.
[18] R. J. Issa, and S. C. Yao, "Modeling of the Mist Dynamics and Heat
Transfer at Various Ambient Pressures," 2004 ASME Heat
Transfer/Fluids Engineering Summer Conference.
[19] D. W. Stanton, and C. J. Rutland, "Multi-Dimensional Modeling of Thin
Liquid Films and Spray-Wall Interactions Resulting from Impinging
Sprays," Int. J. Heat Mass Transfer, vol. 41, no. 20, pp. 3037-3054,
1998.
[1] G. Alvarez, and D. Flick, "Analysis of Heterogeneous Cooling of
Agricultural Products Inside Bins - Part I: Aerodynamic Study,"
Journal of Food Engineering, vol. 39, no. 3, pp. 227-237, 1999.
[2] G. Alvarez, and D. Flick, "Analysis of Heterogeneous Cooling of
Agricultural Products Inside Bins - Part II: Thermal Study," Journal of
Food Engineering, vol. 39, no. 3, pp. 239-245, 1999.
[3] F. A. Ansari, and S. Y. Khan, "Application Concept of Variable
Effective Surface Film Conductance for Simultaneous Heat and Mass
Transfer Analysis during Air Blast Cooling of Food," Energy
Conversion and Management, vol. 40, no. 5, pp. 567-574, 1999.
[4] S. Chuntranuluck, C. M. Wells, and A. C. Cleland, "Prediction of
Chilling Times of Foods in Situations Where Evaporative Cooling is
Significant - Part 2. Experimental Testing," Journal of Food
Engineering, vol. 37, no. 2, pp. 127-141, 1998.
[5] C. Dirita, M. V. De Bonis, and G. Ruocco, "Analysis of Food Cooling
by Jet Impingement Including Inherent Conduction," Journal of Food
Engineering, vol. 81, no. 1, pp. 12-20, 2007.
[6] I. Allais, G. Alvarez, and D. Flick, "Modeling Cooling Kinetics of a
Stack of Spheres During Mist Chilling," Journal of Food Engineering,
vol. 72, no. 2, pp. 197-209, 2006.
[7] I. Allais, and G. Alvarez, "Analysis of Heat Transfer During Mist
Chilling of a Packed Bed of Spheres Simulating Foodstuffs," Journal of
Food Engineering, vol. 49, no. 1, pp. 37-47, 2001.
[8] P. M. Abdul Majeed, P.M., "Analysis of Heat Transfer during Hydrair
Cooling of Spherical Food Products," International Journal of Heat and
Mass Transfer, vol. 24, pp. 323-333, 1981.
[9] P. Mallikarjunan, and G. S. Mittal, "Heat and Mass Transfer during Beef
Carcass Chilling - Modeling and Simulation," Journal of Food
Engineering, vol. 23, no. 2, pp. 277-292, 1994.
[10] A. Kuitche, and J. D. Daudin, "Modeling of Temperature and Weight
Loss Kinetics during Meat Chilling for Time-Variable Conditions using
an Analytical-Based Method - I. The Model and its Sensitivity to
Certain Parameters," Journal of Food Engineering, vol. 28, no. 1, pp.
55-84, 1996.
[11] S. D. M. Jones, and W. M. Robertson, "The Effects of Spray-Chilling
Carcasses on the Shrinkage and Quality of Beef," Meat Science, vol. 24,
no. 3, pp. 177-188, 1988.
[12] K. J. Kinsella, J. J. Sheridan, T. A. Rowe, F. Butler, A. Delgado, A. Q.
Ramirez, I. S. Blair, and D. A. McDowell, "Impact of a Noval Spray-
Chilling System on Surface Microflora, Water Activity and Weight Loss
during Beef Carcass Chilling," Food Microbiology, vol. 23, no. 5, pp.
483-490, 2006.
[13] P. E. Strydom, and E. M. Buys, "The Effects of Spray-Chilling on
Carcass Mass Loss and Surface Associated Bacteriology," Meat Science,
vol. 39, no. 2, pp. 265-276, 1995.
[14] M. Fabbri, S. Jiang, and V. K. Dhir, "Comparative Study of Spray and
Multiple Micro Jets Cooling for High Power Density Electronic
Applications," Proceedings of IMECE-03, 2003 ASME International
Mechanical Engineering Congress and Exposition, Washington, D.C.
[15] J. J. Spillman, "Spray Impaction, Retention and Adhesion: an
Introduction to Basic Characteristics," Pesticide Science, vol. 15, no. 2,
pp. 97-106, 1984.
[16] M. Schatzmann, "Wind Tunnel Modeling of Fog Droplet Deposition on
Cylindrical Obstacles," Journal of Wind Engineering and Industrial
Aerodynamics, vol. 83, no. 1, pp. 371-380, 1999.
[17] R. J. Issa, and S. C. Yao, "A Numerical Model for Spray-Wall
Impactions and Heat Transfer at Atmospheric Conditions," Journal of
Thermophysics and Heat Transfer, vol. 19, no. 4, pp. 441-447, 2005.
[18] R. J. Issa, and S. C. Yao, "Modeling of the Mist Dynamics and Heat
Transfer at Various Ambient Pressures," 2004 ASME Heat
Transfer/Fluids Engineering Summer Conference.
[19] D. W. Stanton, and C. J. Rutland, "Multi-Dimensional Modeling of Thin
Liquid Films and Spray-Wall Interactions Resulting from Impinging
Sprays," Int. J. Heat Mass Transfer, vol. 41, no. 20, pp. 3037-3054,
1998.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:61042", author = "Roy J. Issa", title = "Numerical Investigation of the Chilling of Food Products by Air-Mist Spray", abstract = "Spray chilling using air-mist nozzles has received
much attention in the food processing industry because of the
benefits it has shown over forced air convection. These benefits
include an increase in the heat transfer coefficient and a reduction in
the water loss by the product during cooling. However, few studies
have simulated the heat transfer and aerodynamics phenomena of the
air-mist chilling process for optimal operating conditions. The study
provides insight into the optimal conditions for spray impaction, heat
transfer efficiency and control of surface flooding. A computational
fluid dynamics model using a two-phase flow composed of water
droplets injected with air is developed to simulate the air-mist
chilling of food products. The model takes into consideration
droplet-to-surface interaction, water-film accumulation and surface
runoff. The results of this study lead to a better understanding of the
heat transfer enhancement, water conservation, and to a clear
direction for the optimal design of air-mist chilling systems that can
be used in commercial applications in the food and meat processing
industries.", keywords = "Droplets impaction efficiency, Droplet size, Heat
transfer enhancement factor, Water runoff.", volume = "2", number = "11", pages = "1251-10", }
