Tahun 2000. Part IV processing by the removal of heat



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Fig. 21.8 Time–temperature integrator.

(After Fields and Prusik (1983).)



21.3.3 Thawing

When food is thawed in air or water, surface ice melts to form a layer of water. Water has a lower thermal conductivity and a lower thermal diffusivity than ice (Chapter 1) and the surface layer of water therefore reduces the rate at which heat is conducted to the frozen interior. This insulating effect increases as the layer of thawed food grows thicker. (In contrast, during freezing, the increase in thickness of ice causes heat transfer to accelerate.) Thawing is therefore a substantially longer process than freezing when temperature differences and other conditions are similar.

During thawing (Fig. 21.9), the initial rapid rise in temperature (AB) is due to the absence of a significant layer of water around the food. There is then a long period when the temperature of the food is near to that of melting ice (BC). During this period any cellular damage caused by slow freezing or recrystallisation, results in the release of cell constituents to form drip losses. This causes loss of water-soluble nutrients; for example beef loses 12% thiamine, 10% riboflavin, 14% niacin, 32% pyridoxine and 8% folic acid (Pearson et al., 1951) and fruits lose 30% of the vitamin C. Details of changes to foods during thawing are described by Fennema (1975a).

In addition, drip losses form substrates for enzyme activity and microbial growth. Microbial contamination of foods, caused by inadequate cleaning or blanching (Chapters

3 and 10) has a pronounced effect during this period. In the home, food is often thawed using a small temperature difference (for example 25–40ºC, compared with 50–80ºC for commercial thawing). This further extends the thawing period and increases the risk of contamination by spoilage and pathogenic micro-organisms. Commercially, foods are often thawed to just below the freezing point, to retain a firm texture for subsequent processing.

Some foods are cooked immediately and are therefore heated rapidly to a temperature which is sufficient to destroy micro-organisms. Others (for example ice cream, cream and frozen cakes) are not cooked and should therefore be consumed within a short time of thawing.

When food is thawed by microwave or dielectric heaters (Chapter 18), heat is generated within the food, and the changes described above do not take place. The main considerations in thawing are:
 to avoid overheating

 to minimise thawing times

 to avoid excessive dehydration of the food.


Fig. 21.9 Temperature changes during thawing.

(After Fennema and Powrie (1964).)


Commercially, foods are thawed in a vacuum chamber by condensing steam, at low temperatures by warm water (approximately 20ºC) or by moist air which is recirculated over the food. Details of the types and method of operation of thawing equipment are described by Jason (1981).


21.4 Acknowledgements
Grateful acknowledgement is made for information supplied by: Air Products plc, Basingstoke, Hampshire RG24 8YP, UK; APV Jackstone Ltd, Thetford, Norfolk IP24

3RP, UK; Frigoscandia Equipment, Bedford MK42 7EF, UK; BOC Ltd, London SW19

3UF, UK; The Distillers Co. Ltd, Reigate, Surrey RH2 9QE, UK; LifeLines Technology

Inc., USA.




21.5 References
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BOGH-SORENSEN, L. (1984) The TTT-PPP concept. In: P. Zeuthen, J. C. Cheftel, C. Eriksson, M. Lul, H.

Leniger, P. Linko, G. Varela and G. Vos (eds) Thermal Processing and Quality of Foods. Elsevier

Applied Science, Barking, Essex, pp. 511–521.

BURGER, I. H. (1982) Effect of processing on nutritive value of food: meat and meat products. In: M.

Rechcigl (ed.) Handbook of the Nutritive Value of Processed Food, Vol. 1. CRC Press, Boca Raton,

Florida, pp. 323–336.

CANO, M. P. (1996) Vegetables. In: L. E. Jeremiah (ed.) Freezing Effects on Food Quality. Marcel Dekker,

New York, pp. 247–298.

CLELAND, A. C. and EARLE, R. L. (1982) Int. J. Refrig. 5, 134.

DESROSIER, W. and DESROSIER, N. (1978) Technology of Food Preservation, 4th edn. AVI, Westport,

Connecticut, pp. 110–151.

DEVINE, C. E., BELL, R. G., LOVATT, S., CHRYSTALL, B. B. and JEREMIAH, L. E. (1996) Red meat. In: L. E. Jeremiah

(ed.) Freezing Effects on Food Quality. Marcel Dekker, New York, pp. 51–84.

EARLE, R. L. (1983) Unit Operations in Food Processing, 2nd edn. Oxford University Press, Oxford, pp.

78–84.


EVANS, J. and JAMES, S. (1993) Freezing and meat quality. In: A. Turner (ed.) Food Technology

International Europe. Sterling Publications International, London, pp. 53–56.
FENNEMA, O. R. (1975a) Freezing preservation, In: O. R. Fennema (ed.) Principles of Food Science, Part 2,

Physical principles of food preservation. Marcel Dekker, New York, pp. 173–215.

FENNEMA, O. R. (1975b) Effects of freeze-preservation on nutrients. In: R. S. Harris and E. Karmas (eds)



Nutritional Evaluation of Food Processing. AVI, Westport, Connecticut, pp. 244–288.

FENNEMA, O. R. (1982) Effect of processing on nutritive value of food: freezing. In: M. Rechcigl (ed.)



Handbook of the Nutritive Value of Processed Food, Vol. 1. CRC Press, Boca Raton, Florida, pp.

31–44.


FENNEMA, O. R. (1996) Water and ice. In: O. R. Fennema (ed.) Food Chemistry, 3rd edn. Marcel Dekker,

New York, pp. 17–94.

FENNEMA, O. R. and POWRIE, W. D. (1964) Adv. Food Res. 13, 219.

FIELDS, S. C. and PRUSIK, T. (1983) Time–temperature monitoring using solid-state chemical indicators.



16th International Congress of Refrigeration, Paris, 1983.

GARTHWAITE, A. (1995) Fish raw material. In: R. J. Footitt and A. S. Lewis (eds) The Canning of Fish and



Meat. Blackie Academic and Professional, pp. 17–43.

GRAHAM, J. (1984) Planning and Engineering Data, 3, Fish freezing. FAO Fisheries Circular No 771.

FAO, Rome.

GUADAGNI, D. G. (1968) In: J. Hawthorne and E. J. Rolfe (eds) Low Temperature Biology of Foodstuffs.

Pergamon Press, Oxford, pp. 399–412.

HEAP, R. D. (1997) Environment, law and choice of refrigerants. In: A. Devi (ed.) Food Technology



International Europe. Sterling Publications International, London, pp. 93–96.

HOLDSWORTH, S. D. (1987) Physical and engineering aspects of food freezing. In: S. Thorne (ed.)



Developments in Food Preservation, Vol. 4. Elsevier Applied Science, Barking, Essex, pp. 153–

204.


JACKSON, A. T. and LAMB, J. (1981) Calculations in Food and Chemical Engineering. Macmillan, London,

pp. 50–64.

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31, Aberdeen AB9 8DG.

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International Europe. Sterling Publications International, London, pp. 85–88.

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JUL, M. (1984) The Quality of Frozen Foods. Academic Press, London, pp. 44–80, 156–251.

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Ltd, London SW19 3UF.

LENIGER, H. A. and BEVERLOO, W. A. (1975) Food Process Engineering. D. Reidel, Dordrecht, pp. 351–398.

LONDAHL, G. and KARLSSON, B. (1991) Initial crust freezing of fragile products. In: A. Turner (ed.) Food

Technology International Europe. Sterling Publications International, London, pp. 90–91.

MERYMAN, H. T. (1963) Food Process 22, 81.

MILLER, J. (1998) Cryogenic food freezing systems. Food Proc. 67 (8), 22–23.

NORWIG, J. F. and THOMPSON, D. R. (1984) Review of dyhydration during freezing. Trans. ASAE 1619–1624.

OLSON, R. L. (1968) Objective tests for frozen food quality. In: J. Hawthorn and E.J. Rolfe (eds) Low

Temperature Biology of Foodstuffs. Pergamon Press, Oxford, pp. 381–397.

OLSSON, P. (1984) TT-integrators – some experiments in the freezer chain. In: P. Zeuthen, J. C. Cheftel, C.

Eriksson, M. Lul, H. Leniger, P. Linko, G. Varela and G. Vos (eds) Thermal Processing and

Quality of Foods. Elsevier Applied Science, Barking, Essex, pp. 782–788.

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SIK. Swedish Food Institute, Gothenburg.

PEARSON, A. M., BURNSIDE, J. E., EDWARDS, H. M., GLASSOCK, R. R., CUNHA, T. J. and NOVAK, A. F. (1951) Vitamin

losses in drip obtained upon defrosting frozen meat. Food Res. 16, 86–87.

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Preservation. Marcel Dekker, New York, pp. 259–284.

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International Europe. Sterling Publications International, London, pp. 145–149.

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22

Freeze drying and freeze concentration

The advantages of dried and concentrated foods compared to other methods of preservation are described in Chapters 6, 13 and 15. The heat used to dry foods or concentrate liquids by boiling removes water and therefore preserves the food by a reduction in water activity (Chapter 1). However, the heat also causes a loss of sensory characteristics and nutritional qualities. In freeze drying and freeze concentration a similar preservative effect is achieved by reduction in water activity without heating the food, and as a result nutritional qualities and sensory characteristics are better retained. However, both operations are slower than conventional dehydration, evaporation or membrane concentration. Energy costs for refrigeration are high and, in freeze drying, the production of a high vacuum is an additional expense. This, together with a relatively high capital investment, results in high production costs for freeze-dried and freeze- concentrated foods. Nijhuis (1998) has reviewed the relative costs of freeze drying and radio frequency drying (Chapter 18). Freeze drying is the more important operation commercially and is used to dry expensive foods which have delicate aromas or textures (for example coffee, mushrooms, herbs and spices, fruit juices, meat, seafoods, vegetables and complete meals for military rations or expeditions) for which consumers are willing to pay higher prices for superior quality. In addition, microbial cultures for use in food processing (Chapter 7) are freeze dried for long-term storage prior to inoculum generation. Freeze concentration is not widely used in food processing but has found some applications such as pre-concentrating coffee extract prior to freeze drying, increasing the alcohol content of wine and preparation of fruit juices, vinegar and pickle liquors.




22.1 Freeze drying (lyophilisation)
The main differences between freeze drying and conventional hot air drying are shown in

Table 22.1.
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