Modeling kinetics of thermal degradation of nutrients for food quality or kinetics of microbial reduction for food safety requires reliable estimates of the thermal properties. Thermophysical properties, especially thermal conductivity and specific heat, are important in establishing thermal processes for food manufacturing, especially at higher processing temperatures. Hence, in this study, a novel instrument (TPCell) was designed and developed using principles of intrinsic verification and inverse heat conduction. An intrinsic verification method was developed to ascertain the parameter identifiability in the model and to check the accuracy of the numerical codes used to solve the partial differential equation for heat conduction. The concept of intrinsic sum was introduced, which is sum of all the scaled sensitivity coefficients in the model. The intrinsic sum was derived using dimensionless derivation of scaled sensitivity coefficients. The design of the instrument was based on the insight gained from the dimensionless scaled sensitivity coefficients and the intrinsic sum. With the instrument, thermal conductivity can be measured from room temperature to higher processing temperature of 140 °C. Several food materials were tested using the instrument. Sweet potato puree thermal conductivity was measured to be 0.539 W/m°C at 20 °C and 0.574 W/m°C at 140 °C. The experimental time with TPCell is less than a minute, as compared to 5-6 hours with quasi-isothermal method employed by currently available instruments. TPCell has advantages over traditional methods, as it avoids the decomposition of materials that result when achieving the quasi-isothermal state at higher temperatures. Temperature-dependent thermal properties were used to estimate the kinetic parameters of nutrient degradation during aseptic and conventional retort processing. Vitamin C and thiamin were selected as model nutrients for degradation study. Sweet potato puree was used as a food matrix. Aseptic processing had 50% higher retention of Vitamin C as compared to retort processing. Thiamin retention could not be quantified, as it survived well in aseptic as well as retort processing. The rate of reaction for ascorbic acid in aseptic processing and retort processing was 0.0073 min-1 and 0.0114 min-1 at a reference temperature of 127 °C, respectively. The activation energy for ascorbic acid in aseptic processing and retort processing was 26.62 KJ/g-mol and 3.43 KJ/g-mol, respectively. The kinetic parameter of thiamin could not be estimated due to insufficient degradation in aseptic as well as in retort processing.
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机译:为食品质量建模营养素热降解动力学或为食品安全建模微生物还原动力学需要对热性质进行可靠的估算。热物理性质,特别是热导率和比热,对于建立食品制造的热过程(特别是在较高的加工温度下)非常重要。因此,在这项研究中,使用固有验证和逆热传导原理设计和开发了一种新型仪器(TPCell)。开发了一种内在的验证方法,以确定模型中的参数可识别性,并检查用于求解热传导偏微分方程的数字代码的准确性。引入了本征和的概念,即模型中所有比例灵敏度系数的和。使用标度灵敏度系数的无量纲推导得出内在和。仪器的设计基于从无量纲缩放的灵敏度系数和内在求和得出的见解。使用该仪器,可以测量从室温到更高的140°C处理温度的热导率。使用该仪器测试了几种食品原料。测得甘薯泥的热导率在20°C下为0.539 W / m°C,在140°C下为0.574 W / m°C。 TPCell的实验时间不到一分钟,而当前可用仪器采用的准等温方法则为5-6小时。 TPCell优于传统方法,因为它避免了在较高温度下达到准等温状态时所产生的材料分解。与温度有关的热特性被用于估计无菌和常规杀菌罐加工过程中营养物质降解的动力学参数。选择维生素C和硫胺素作为模型营养素进行降解研究。甘薯泥被用作食物基质。与杀菌处理相比,无菌处理的维生素C保留量高50%。硫胺素的保留不能量化,因为它在无菌和蒸煮过程中都能很好地存活。在127°C的参考温度下,无菌处理和re处理中抗坏血酸的反应速率分别为0.0073 min-1和0.0114 min-1。无菌处理和杀菌处理中抗坏血酸的活化能分别为26.62 KJ / g-mol和3.43 KJ / g-mol。由于在无菌以及蒸煮过程中降解不充分,无法估计硫胺素的动力学参数。
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