Empirical Models of Sigmoid and Non-Sigmoid Hydration and Moisture Sorption Curves

IF 5.3 2区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY

Food Engineering Reviews Pub Date : 2022-12-22 DOI:10.1007/s12393-022-09328-w

Micha Peleg

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Abstract

There are several published empirical mathematical models to describe the water content vs. time relationships in dry or dried-food spontaneous hydration, or in deliberate rehydration, similar to or the same as those originally proposed for water vapor sorption kinetics. Most of these models come in one of two forms: for non-sigmoid and for sigmoid relationships. Some, notably the stretched exponential (“Weibullian”) with an adjusted shape parameter, can describe both. All the empirical hydration models are rarely, if ever, unique, and most of them can be used interchangeably for a given set of experimental data. It is proposed to add an expanded version of a particular popular hydration model of non-sigmoid curves so that it, too, can describe both kinds of hydration patterns. Either model would facilitate the mathematical description of systems or processes where a non-sigmoid hydration pattern turns into a sigmoid one, or vice versa. In principle, variants of these two model types can be used to describe water loss or drying curves, at least qualitatively.

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s型和非s型水化吸湿曲线的经验模型

有几个已发表的经验数学模型来描述干燥或干燥食品的自发水化或故意再水化中含水量与时间的关系，类似或相同于最初提出的水蒸气吸附动力学。这些模型大多有两种形式:非s型关系和s型关系。有些，特别是带有调整形状参数的拉伸指数(“威布尔指数”)，可以同时描述这两种情况。所有的经验水化模型，如果有的话，很少是唯一的，并且它们中的大多数可以互换用于给定的一组实验数据。它被提议添加一个扩展版本的特别流行的水化模型的非s型曲线，使它，也可以描述两种水化模式。这两种模型都有助于对非s型水化模式转变为s型水化模式的系统或过程进行数学描述，反之亦然。原则上，这两种模型类型的变体可以用来描述失水或干燥曲线，至少定性的。

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来源期刊

Food Engineering Reviews FOOD SCIENCE & TECHNOLOGY-

CiteScore

14.20

自引率

1.50%

发文量

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.