Heat and mass transfer in vacuum drying process of fructooligosaccharides syrup

IF 1.6 4区农林科学

International Journal of Food Engineering Pub Date : 2023-08-30 DOI:10.1515/ijfe-2022-0264

Lijuan Zhao, Hui Xie, Yuxuan Liu, Chenxi Ran, Zhonghua Wu

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引用次数: 0

Abstract

Abstract Fructooligosaccharides (FOS) is a functional food additive. FOS syrup produced by biological methods can be easily transported, stored and used after drying. In this study, the effects of operating pressure, heating temperature and initial moisture content of FOS syrup on the drying characteristics during vacuum drying were studied. With a visual system, the state changes of the material during the drying process were recorded. The specific heat, viscosity and thermal conductivity of the FOS at different temperatures and moisture contents were measured. From the perspective of drying characteristics, the whole drying process can be divided into four periods: the increasing drying rate period AB, the first falling drying rate period BC, the second falling drying rate period CD and the third falling drying rate period DE. The heat transfer mode in AB and BC was boiling heat transfer, with the material viscosity less than 267.9 Pa·s. In CD period, the heat transfer mode was convection heat transfer with the material viscosity of 267.9 Pa·s to 501.6 Pa·s. In DE period, the material viscosity was greater than 501.6 Pa·s and did not have fluidity, and the heat transfer mode was heat conduction. A multivariate model for the convection heat transfer coefficient was obtained based on the heat balance. The maximum error between the simulation value by the model and the experimental value of the material moisture content during the vacuum drying process was 4.18 %.

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低聚果糖糖浆真空干燥过程中的传热传质

摘要低聚果糖(FOS)是一种功能性食品添加剂。生物法生产的果寡糖糖浆易于运输、储存和干燥后使用。在真空干燥过程中，研究了操作压力、加热温度和果糖浆初始含水量对果糖浆干燥特性的影响。用视觉系统记录了物料在干燥过程中的状态变化。测定了不同温度和含水率下FOS的比热、粘度和导热系数。从干燥特性来看，整个干燥过程可分为4个阶段:干燥速率增加期AB、第一干燥速率下降期BC、第二干燥速率下降期CD和第三干燥速率下降期DE。AB和BC阶段的传热方式均为沸腾传热，物料粘度小于267.9 Pa·s。CD期换热方式为对流换热，物料粘度为267.9 Pa·s ~ 501.6 Pa·s。DE期物料粘度大于501.6 Pa·s，不具有流动性，传热方式为热传导。基于热平衡理论，建立了对流换热系数的多元模型。真空干燥过程中物料含水率的模型模拟值与实验值的最大误差为4.18 %。

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来源期刊

International Journal of Food Engineering 农林科学-食品科技

CiteScore

3.20

自引率

0.00%

发文量

审稿时长

3.8 months

期刊介绍： International Journal of Food Engineering is devoted to engineering disciplines related to processing foods. The areas of interest include heat, mass transfer and fluid flow in food processing; food microstructure development and characterization; application of artificial intelligence in food engineering research and in industry; food biotechnology; and mathematical modeling and software development for food processing purposes. Authors and editors come from top engineering programs around the world: the U.S., Canada, the U.K., and Western Europe, but also South America, Asia, Africa, and the Middle East.