Heat Transfer in the Cooling, Freezing and Post-Freezing of Liquid Food: Modeling and Simulation

Diffusion Foundations Pub Date : 2020-01-10 DOI:10.4028/www.scientific.net/DF.25.37

W. B. D. Barbosa de Lima, L. P. C. Nascimento, R. Lima Dantas, N. Lima Tresena, J.B. Silva Júnior, G. Santos de Lima, A. G. Barbosa de Lima

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引用次数: 5

Abstract

In pursuit of greater practicality in the food preparation, in recent years there has been a considerable growth of researches in the field of cooling and freezing of food. Therefore, the trade in frozen food has been very promising, allowing a great variety of products to the consumers due to the convenience of transportation, storage and use. Cooling and freezing of products are preservation methods used in the food industry to maintain the sensorial attributes and nutritional properties of these products. In this sense, in order to optimize the process and reduce energy costs, this work presents a transient three-dimensional mathematical modeling to describe the heat transfer inside liquid materials with parallelepiped shape including phase change (liquid-solid) term. The governing equation was solved numerically using the finite volume technique with a fully implicit formulation. As an application, the methodology was used to predict heat transfer during cooling, freezing and post-freezing of the Tahiti lemon pulp. Numerical results of the temperature distribution at different process instants are presented and analyzed, and temperature data at the center of the product throughout time were compared to experimental data reported in the literature and a good agreement was obtained.

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液态食品冷却、冷冻和冷冻后的传热:建模与模拟

为了追求食品制备的更大实用性，近年来在食品冷却和冷冻领域的研究有了相当大的增长。因此，冷冻食品贸易一直很有前景，由于运输、储存和使用方便，可以为消费者提供各种各样的产品。产品的冷却和冷冻是食品工业中使用的保存方法，以保持这些产品的感官属性和营养特性。为此，本文提出了一种包含相变(液固)项的平行六面体液体材料内部传热的瞬态三维数学模型，以优化工艺流程，降低能源成本。采用有限体积法，采用全隐式公式对控制方程进行了数值求解。作为应用，该方法被用于预测塔希提柠檬果肉在冷却、冷冻和冷冻后的传热。给出并分析了不同工艺时刻温度分布的数值结果，并将产品中心温度数据与文献报道的实验数据进行了比较，得到了较好的一致性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Diffusion Foundations

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