Capillary Pressure in Unsaturated Food Systems: Its Importance and Accounting for It in Mathematical Models

IF 5.3 2区 农林科学 Q1 FOOD SCIENCE & TECHNOLOGY
Yash Shah, Pawan Singh Takhar
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Abstract

Capillary pressure plays a critical role in driving fluid flow in unsaturated porous (pores not saturated with liquids but also containing air/gas) structures. The role and importance of capillary pressure have been well documented in geological and soil sciences but remain largely unexplored in the food literature. Available mathematical models for unsaturated food systems have either ignored the capillary-driven flow or combined it with the diffusive flow. Such approaches are bound to impact the accuracy of models. The derivation of the microscale definition of capillary pressure is overviewed, and the limitations of using the microscale definition at the macroscale are discussed. Next, the factors affecting capillary pressure are briefly reviewed. The parametric expressions for capillary pressure as a function of saturation and temperature, developed originally for soils, are listed, and their application for food systems is encouraged. Capillary pressure estimation methods used for food systems are then discussed. Next, the different mathematical formulations for food systems are compared, and the limitations of each formulation are discussed. Additionally, examples of hybrid mixture theory–based multiscale models for frying involving capillary pressure are provided. Capillary-driven liquid flow plays an important role in the unsaturated transport during the processing of porous solid foods. However, measuring capillary pressure in food systems is challenging because of the soft nature of foods. As a result, there is a lack of available capillary pressure data for food systems which has hampered the development of mechanistic models. Nevertheless, providing a fundamental understanding of capillary pressure will aid food engineers in designing new experimental studies and developing mechanistic models for unsaturated processes.

Abstract Image

不饱和食物系统中的毛细管压力:其重要性及其在数学模型中的计算
毛细压力在非饱和孔隙(不含液体但含有空气/气体的孔隙)结构中起着驱动流体流动的关键作用。毛细管压力的作用和重要性已经在地质和土壤科学中得到了很好的记载,但在食品文献中仍未得到充分的探讨。现有的不饱和食物系统数学模型要么忽略了毛细管驱动流动,要么将其与扩散流动结合起来。这种方法必然会影响模型的准确性。概述了毛细管压力微尺度定义的推导过程,并讨论了在宏观尺度上使用微尺度定义的局限性。其次,对影响毛细压力的因素进行简要综述。列出了毛细管压力作为饱和度和温度函数的参数表达式,这些表达式最初是为土壤开发的,并鼓励它们在食品系统中的应用。然后讨论了用于食品系统的毛细管压力估计方法。接下来,比较了粮食系统的不同数学公式,并讨论了每种公式的局限性。此外,还给出了考虑毛细压力的基于混合理论的油炸多尺度模型的算例。在多孔固体食品加工过程中,毛细管驱动的液体流动在不饱和运输中起着重要作用。然而,由于食物的软性质,测量食物系统中的毛细管压力是具有挑战性的。因此,粮食系统缺乏可用的毛细管压力数据,这阻碍了机制模型的发展。然而,提供对毛细管压力的基本理解将有助于食品工程师设计新的实验研究和开发不饱和过程的机制模型。
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来源期刊
Food Engineering Reviews
Food Engineering Reviews FOOD SCIENCE & TECHNOLOGY-
CiteScore
14.20
自引率
1.50%
发文量
27
审稿时长
>12 weeks
期刊介绍: Food Engineering Reviews publishes articles encompassing all engineering aspects of today’s scientific food research. The journal focuses on both classic and modern food engineering topics, exploring essential factors such as the health, nutritional, and environmental aspects of food processing. Trends that will drive the discipline over time, from the lab to industrial implementation, are identified and discussed. The scope of topics addressed is broad, including transport phenomena in food processing; food process engineering; physical properties of foods; food nano-science and nano-engineering; food equipment design; food plant design; modeling food processes; microbial inactivation kinetics; preservation technologies; engineering aspects of food packaging; shelf-life, storage and distribution of foods; instrumentation, control and automation in food processing; food engineering, health and nutrition; energy and economic considerations in food engineering; sustainability; and food engineering education.
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