The mechanisms controlling heat and mass transfer on frying of beefburgers. III. Mass transfer evolution during frying

Bea Kovácsné Oroszvári, Elena Bayod, Ingegerd Sjöholm, Eva Tornberg

    Research output: Contribution to journalArticlepeer-review

    Abstract

    The effects of five different meat raw materials used for making beefburgers on the evolution of mass transfer (total, water and fat losses), patty diameter shrinkage and porosity were studied during frying from the frozen state (-20 degrees C) to a centre temperature of 72 degrees C in a double-sided pan fryer. The normalised water losses increased linearly with increasing average temperature at a degree of 0.4% degrees C-1 during cooking, which suggests that the availability of water is not a restricting factor. The fat content governs both the amount and the initial time of the fat release during frying. Apart from the fattiest beefburger, having a shrinkage of 22%, the shrinkage increased linearly from 0 to 10-12% for all types of meats during the frying. High porosity with a maximum value of about 35% was achieved in the heat treated burgers and was especially evident after crust formation and with high water and fat losses. As a result of the thermal denaturation and contraction of the meat proteins, a flow of water and fat is created moving towards the centre of the patty, which in turn speeds up the heat transfer. The water and fat drip leaves the patty through the circumference of the burger. (c) 2005 Elsevier Ltd. All rights reserved.
    Original languageEnglish
    Pages (from-to)169-178
    JournalJournal of Food Engineering
    Volume76
    Issue number2
    DOIs
    Publication statusPublished - 2006

    Subject classification (UKÄ)

    • Food Engineering

    Free keywords

    • beefburger
    • mass and heat transfer
    • frying
    • contraction
    • porosity

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