142 Meat refrigeration tunnels are of simpler construction but are restricted by the length of belt necessary to achieve the cooling time required and on the space available in most factories. Spiral freezers are therefore a more viable alter native 7.3 Contact freezers Contact freezing methods are based on heat transfer by contact between products and metal surfaces, which in turn are cooled by either primary or secondary refrigerants. Contact freezing offers several advantages over air cooling, i.e. there is much better heat transfer and significant energy savings However, the need for regularly shaped products with large flat surfaces is a major hindrance Modern plate cooling systems differ little in principle from the first contact freezer patented in 1929 by Clarence Birdseye. Essentially the refrigerant(Fig. 7. 2). A hydraulic cylinder is used to bring the freezing plates into pressure contact with the product. These plates can be either horizontal or vertical Good heat transfer is dependent on product thickness, good contact and the conductivity of the product. Plate freezers are often limited to a maximum thickness of 50-70mm Good contact is a prime requirement. Air paces in packaging and fouling of the plates can have a significant effect on cooling time, for example a water droplet frozen on the plate can lengthen the freezing time in the concerned tray by as much as 30-60% General advantages of plate freezers over air-blast carton fre Hydraulic ram Product Fig. 7.2. Example of a horizontal plate freezer
tunnels are of simpler construction but are restricted by the length of belt necessary to achieve the cooling time required and on the space available in most factories. Spiral freezers are therefore a more viable alternative. 7.3 Contact freezers Contact freezing methods are based on heat transfer by contact between products and metal surfaces, which in turn are cooled by either primary or secondary refrigerants. Contact freezing offers several advantages over air cooling, i.e. there is much better heat transfer and significant energy savings. However, the need for regularly shaped products with large flat surfaces is a major hindrance. Modern plate cooling systems differ little in principle from the first contact freezer patented in 1929 by Clarence Birdseye. Essentially the product is pressed between hollow metal plates containing a circulating refrigerant (Fig. 7.2). A hydraulic cylinder is used to bring the freezing plates into pressure contact with the product. These plates can be either horizontal or vertical. Good heat transfer is dependent on product thickness, good contact and the conductivity of the product. Plate freezers are often limited to a maximum thickness of 50–70 mm. Good contact is a prime requirement.Air spaces in packaging and fouling of the plates can have a significant effect on cooling time, for example a water droplet frozen on the plate can lengthen the freezing time in the concerned tray by as much as 30–60%. General advantages of plate freezers over air-blast carton freezers include: 142 Meat refrigeration Hydraulic ram Freezing plate Product Separated plates Closed plates Fig. 7.2. Example of a horizontal plate freezer
Freezing of meat 143 Freezing is either faster for the same refrigerant evaporating tempera- ture, or can take place at a higher evaporating temperature for a given freezing time. Product temperatures are easier to control, especially for smaller cuts Power consumption is significantly reduced -savings of at least 30% nd possibly 50% or more, may be expected because air-circulating fans are not required and because higher evaporating temperatures can be used for the same effective cooling medium temperature. In many cases, less building space is required The product remains uniform and flat after freezing, unlike air-blast frozen cartons which often bulge. The flat cartons result in stable loads, giving up to 30% higher space utilisation in cold stores. For transport, the stable pallets facilitate unitised loading, and some 8-10% more product can be loaded into a container Disadvantages of plate freezers relate mainly to cost aspects Capital costs are significantly higher than for equivalent air-blast freezers. Manually loaded plate freezers are comparable in cost to auto- matic air-blast tunnel freezers. Fully automatic plate freezers are more High circulation rates of liquid refrigerant are required; this results in additional costs for larger accumulators and higher capacity pumps For manual plate freezers, simultaneous loading and unloading may require higher labour input than for a batch air freezer Each plate must be loaded with product of the same thickness Damp cartons can stick to plates or cause jams when ice forms. Air infiltration must be minimised to prevent frost build up on plates. Freezing unpacked meat has significant advantages because of the sub- stantially shorter freezing times( Fleming et al., 1996). Twice as many freez ng cycles per day can be achieved with the bare product Table 7. 4) Overall costs for plate freezing can be comparable to those for air-blast freezing. De Jong(1994)carried out a cost analysis(Table 7.5)for a beef plant using either plate or air blast freezers in New Zealand which assumed Table 7. 4 Predicted freezing time of meat blocks in a plate freezer operating at -30C Thickness(mm) Freezing time(h) Cycles per day Cartoned Bare Cartoned Bare ource: Fleming et al., 1996