Thermal Food Processing

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Ohmic Heating for Food Processing 465 8. I Castro, JA Teixeira, AA Vicente. The influence of field strength, sugar and solid content on electrical conductivity of strawberry products. Journal of Food Process Engineering 26: 17–29, 2003. 9. DL Parrott. Use of OH for aseptic processing of food particulates. Food Technology 45: 68–72, 1992. 10. HJ Kim, YM Choi, TCS Yang, IA Taub, P Tempest, P Skudder, G Tucker, DL Parrott. Validation of OH for quality enhancement of food products. Food Technology 50: 253–261, 1996. 11. PJ Skuder. OH in food processing. Asian Food Journal 4: 10–11, 1989. 12. HY Cho, AE Yousef, SK Sastry. Growth kinetics of Lactobacillus acidophilus under ohmic heating. Biotechnology and Bioengineering 49: 334–340, 1996. 13. WH Hayt. Engineering Electromagnetics, 4th ed. New York: McGraw-Hill, 1981. 14. SK Sastry, S Palaniappan. Mathematical modelling and experimental studies on ohmic heating of liquid-particle mixtures in a static heater. Journal of Food Engineering 15: 241–261, 1992. 15. SK Sastry. A model for heating of liquid-particle mixtures in a continuous flow ohmic heater. Journal of Food Process Engineering 15: 263–278, 1992. 16. S Orangi, SK Sastry, Q Li. A numerical investigation of electroconductive heating in solid-liquid mixtures. International Journal of Heat and Mass Transfer 41: 2211–2220, 1998. 17. IJ Kopelman. Transient Heat Transfer and Thermal Properties in Food Systems. Ph.D. dissertation, Michigan State University, East Lansing, 1966. 18. SK Sastry, Q Li. Modelling the ohmic heating of foods. Food Technology 50: 246–249, 1996. 19. AAP de Alwis, K Halden, PJ Fryer. Shape and conductivity effects in the ohmic heating of foods. Chemical Engineering Research and Design 67: 159–168, 1989. 20. PJ Fryer, Z Li. Electrical resistance heating of foods. Journal of Food Science and Technology 4: 364–369, 1993. 21. Anon. Theory and Application of Electrolytic Conductivity Measurement. Foxboro, MA: The Foxboro Company, 1982 (unpublished). 22. SK Sastry, S Palaniappan. Ohmic heating of liquid-particle mixtures. Food Technology 45: 64–67, 1992. 23. MR Zareifard, HS Ramaswamy, M Trigui, M Marcotte. Ohmic heating behaviour and electrical conductivity of two-phase food systems. Innovative Food Science and Emerging Technologies 4: 45–55, 2003. 24. SK Sastry, JT Barach. Ohmic and inductive heating. Journal of Food Science 65: 42–46, 2000. 25. I Castro, JA Teixeira, AA Vicente. The Influence of Food Additives on the Electrical Conductivity of a Strawberry Pulp. Paper presented at Proceedings of the 32nd Annual Food Science and Technology Research Conference, University College Cork, Cork, Ireland, 2002. 26. S Palaniappan, SK Sastry. Modelling of electrical conductivity of liquid-particle mixtures. Food and Bioproducts Processing, Part C, Transactions of the Institution of Chemical Engineers 69: 167–174, 1991. 27. WC Wang, SK Sastry. Salt diffusion into vegetable tissue as a pretreatment for ohmic heating: electrical conductivity profiles and vacuum infusion studies. Journal of Food Engineering 20: 299–309, 1993. 28. M Lima, SK Sastry. The effects of ohmic frequency on hot-air drying and juice yield. Journal of Food Engineering 41: 115–119, 1999.
466 Thermal Food Processing: New Technologies and Quality Issues 29. I Castro, JA Teixeira, S Salengke, SK Sastry, AA Vicente. Ohmic heating of strawberry products: electrical conductivity measurements and degradation kinetics. Innovative Food Science and Emerging Technologies 5: 27–36, 2004. 30. JW Larkin, SH Spinak. Safety considerations for ohmically heated, aseptically processed, multiphase low-acid food products. Food Technology 50: 242–245, 1996. 31. WR Fu, CC Hsieh. Simulation and verification of two-dimensional ohmic heating in static system. Journal of Food Science 64: 946–949, 1999. 32. SK Sastry, S Salengke. Ohmic heating of solid-liquid mixtures: a comparison of mathematical models under worst-case heating conditions. Journal of Food Process Engineering 29: 441–458, 1998. 33. WG Khalaf, SK Sastry. Effect of fluid viscosity on the ohmic heating rate of solidliquid mixtures. Journal of Food Engineering 27: 145–158, 1996. 34. AAP de Alwis, PJ Fryer. The use of network theory in the finite-element analysis of coupled thermo-electric fields. Communications of Applied Numerical Methods 6: 61–66, 1990. 35. L Zhang, PJ Fryer. Models for the electrical heating of solid-liquid food mixtures. Chemical Engineering Science 48: 633–642, 1993. 36. Y Benabderrahmane, JP Pain. Thermal behaviour of a solid/liquid mixture in an ohmic heating sterilizer: slip phase model. Chemical Engineering Science 55: 1371–1384, 2000. 37. C Lareo, CA Branch, PJ Fryer. The flow behaviour of solid-liquid food mixtures. In: Proceedings of Institute of Chemical Engineers Symposium: Food Process Engineering, 1994, Bath, U.K., pp. 203–210. 38. C Lareo. The Vertical Flow of Solid-Liquid Food Mixtures. Ph.D. dissertation, Department of Chemical Engineering, University of Cambridge, Cambridge, U.K., 1995. 39. S Liu, JP Pain, J Procter, AAP de Alwis, PJ Fryer. An experimental study of particle flow velocities in solid-liquid food mixtures. Chemical Engineering Communications 124: 97–114, 1993. 40. PG Fairhurst. Contribution to the Study of the Flow Behaviour of Large Nearly Neutrally Buoyant Spheres in Non-Newtonian Media: Application to HTST Processing. Ph.D. dissertation, Département de Génie Chimique, Université de Technologie de Compiègne, Compiègne, France, 1998. 41. PG Fairhurst, JP Pain. Passage time distributions for high solid fraction solidliquid food mixtures in horizontal flow: unimodal size particle distributions. Journal of Food Engineering 39: 345–357, 1999. 42. AA Lacey. Thermal runaway in a non-local problem modelling ohmic heating. Part I. Model derivation and some special cases. European Journal of Applied Mathematics 6: 127–144, 1995. 43. AA Lacey. Thermal runaway in a non-local problem modelling ohmic heating. Part II. General proof of blow-up and asymptotes of runaway. European Journal of Applied Mathematics 6: 201–224, 1995. 44. AA Lacey, DE Tzanetis, PM Vlamos. Behaviour of a non-local reactive convection problem modelling ohmic heating of food. The Quarterly Journal of Mechanics and Applied Mathematics 52: 623–644, 1999. 45. CP Please, DW Schwendeman, PS Hagan. Ohmic heating of foods during aseptic processing. IMA Journal of Mathematics for Business and Industry 5: 283–301, 1994. 46. NI Kavallaris, DE Tzanetis. An ohmic heating non-local diffusion-convection problem for the Heaviside function. ANZIAM Journal 44: E114–E142, 2002.
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Thermal Food Processing
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87. Polysaccharide Association Stru
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133. Handbook of Frozen Foods, edit
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Published in 2006 by CRC Press Tayl
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Various alternative thermal process
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Professor Sun is a fellow of the In
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Antonio Martínez Instituto de Agro
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Contents Part I: Modeling of Therma
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Chapter 17 Pressure-Assisted Therma
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1 CONTENTS Thermal Physical Propert
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Thermal Physical Properties of Food
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2 CONTENTS Heat and Mass Transfer i
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Heat and Mass Transfer in Thermal F
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74 Thermal Food Processing: New Tec
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5 CONTENTS Modeling Thermal Process
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Modeling Thermal Processing Using C
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6 CONTENTS Thermal Processing of Me
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Thermal Processing of Meat Products
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7 CONTENTS Thermal Processing of Po
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Thermal Processing of Poultry Produ
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9 CONTENTS Thermal Processing of Da
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Thermal Processing of Dairy Product
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10 CONTENTS UHT Thermal Processing
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UHT Thermal Processing of Milk 301
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11 CONTENTS Thermal Processing of C
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Thermal Processing of Canned Foods
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12 CONTENTS Thermal Processing of R
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Thermal Processing of Ready Meals 3
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Infrared Heating 517 T l (K) N l /
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Infrared Heating 519 Temperature (
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Infrared Heating 521 and thawing ti
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Infrared Heating 523 15. T Takeo. F
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Infrared Heating 525 55. CM Liu, N
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622 Index Aspergillus niger, 448 At
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628 Index dielectric properties of,
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630 Index Joule heating, see Ohmic
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638 Index Tea, 451, 510 Temperature
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640 Index Wax beans, 398, 411 Web s
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