FEASIBILITY OF THE USE OF A TIME-TEMPERATURE INTEGRATOR AND A MATHEMATICAL-MODEL TO DETERMINE FLUID-TO-PARTICLE HEAT-TRANSFER COEFFICIENTS

被引：8

作者：

MAESMANS, GJ ^{[1
]}

HENDRICKX, ME ^{[1
]}

DECORDT, SV ^{[1
]}

TOBBACK, P ^{[1
]}

机构：

[1] KATHOLIEKE UNIV LEUVEN,FAC AGR SCI,CTR FOOD SCI & TECHNOL,FOOD PRESERVAT UNIT,HEVERLEE,BELGIUM

来源：

FOOD RESEARCH INTERNATIONAL | 1994年 / 27卷 / 01期

关键词：

TIME-TEMPERATURE-INTEGRATOR; HEAT TRANSFER COEFFICIENT; MATHEMATICAL MODEL; THERMAL PROCESSING; SOLID/LIQUID MIXTURE;

D O I：

10.1016/0963-9969(94)90176-7

中图分类号：

TS2 [食品工业];

学科分类号：

0832 ;

摘要：

The growing interest in mathematical modelling of heat transfer to heterogeneous foods, i.e. foods comprising a liquid and solids, forces food technologists to look for adequate input parameters for these models. Here, possibilities of the combined use of a mathematical model and a Time-Temperature-Integrator (TTI), suggested to determine the fluid-to-particle convective heat transfer coefficient (h(fp)) in conditions which prohibit the use of conventional measurement techniques, is considered theoretically. The relative importance of the kinetic characteristics of the TTI, the carrier material, the location in/on this carrier, the immersion temperature and immersion time are systematically studied for idealized modelled processing conditions. The feasibility of existing TTIs and experimental results previously obtained with this methodology are critically evaluated. This theoretical study indicates that this technique should be used with extreme caution and that the response of each TTI towards different boundary conditions in a specific processing condition should be identified prior to experimentation. The need for such an a priori sensitivity study, specific for each processing condition, TTI and carrier material makes it a cumbersome methodology.

引用

页码：39 / 51

页数：13

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