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中国精品科技期刊2020
孙辉,张渤,周江鸿,等. 佛手叶粉微波干燥动力学模型的建立及品质特性分析[J]. 食品工业科技,2025,46(3):1−10. doi: 10.13386/j.issn1002-0306.2024010189.
引用本文: 孙辉,张渤,周江鸿,等. 佛手叶粉微波干燥动力学模型的建立及品质特性分析[J]. 食品工业科技,2025,46(3):1−10. doi: 10.13386/j.issn1002-0306.2024010189.
SUN Hui, ZHANG Bo, ZHOU Jianghong, et al. Establishment of Microwave Drying Dynamic Model for Foshou Leaves Powder and Analysis of Quality Characteristics[J]. Science and Technology of Food Industry, 2025, 46(3): 1−10. (in Chinese with English abstract). doi: 10.13386/j.issn1002-0306.2024010189.
Citation: SUN Hui, ZHANG Bo, ZHOU Jianghong, et al. Establishment of Microwave Drying Dynamic Model for Foshou Leaves Powder and Analysis of Quality Characteristics[J]. Science and Technology of Food Industry, 2025, 46(3): 1−10. (in Chinese with English abstract). doi: 10.13386/j.issn1002-0306.2024010189.

佛手叶粉微波干燥动力学模型的建立及品质特性分析

Establishment of Microwave Drying Dynamic Model for Foshou Leaves Powder and Analysis of Quality Characteristics

  • 摘要: 为优化佛手叶粉的干燥效率与品质,以干基含水率、失水速率及感官评分等评估指标,探讨了间歇干燥模式、微波功率、装载量对干燥特性和感官品质的影响。旨在确定最佳干燥条件,并比较了热风与微波干燥后佛手叶粉在微观结构、色泽、叶绿素含量、吸湿性、溶解性及茶多酚含量等方面的差异。结果显示,20、30 s的间歇模式下的佛手叶粉品质最佳,时间较短,确定为最优干燥模式。微波功率和装载量对干燥速率产生显著影响,提高微波功率可有效缩短干燥时间,特别是缩短恒速干燥阶段;而在减速阶段,载重量对干燥速率的影响较小。在微波功率385,载重量20 g时,感官综合评分达到最高(16.5)。通过对比3种数学模型模拟干燥动力学过程,发现佛手叶水分比与干燥时间均存在非线性关系。但Page和Wang-Singh模型拟合效果显著,且Wang-Singh模型预测准确性更高,最佳拟合函数为MR =(0.0011+0.0058X1+0.0037X2)t2-(0.086+0.1544X1+0.086X2)t+1。与热风干燥相比,佛手老叶在最优干燥条件下制备的佛手叶超微粉呈疏松细小颗粒结构,色泽亮绿,感官品质(16.9)更优,润湿性和溶解性有所提升,且茶多酚叶绿素保留率偏高。以上结果能够为佛手老叶的精深加工提供了科学指导。

     

    Abstract: To enhance the drying efficiency and quality of Foshou leaf powder, this investigation assessed the effects of intermittent drying modes, microwave power, and load amount on its drying attributes and sensory qualities, utilizing dry basis moisture content, rate of dehydration, and sensory evaluations as benchmarks. The objective was to identify the most favorable drying conditions while also comparing the variances in microstructure, color, chlorophyll concentration, hygroscopicity, solubility, and polyphenol levels between Foshou leaf powders dried using hot air and microwave techniques. The findings demonstrated that the intermittent drying modes of 20 and 30 seconds yielded the highest quality Foshou powder, establishing these conditions as optimal. Notably, microwave power and the quantity of material loaded were determinants of drying speed, with an increase in microwave power notably shortening the drying duration, especially during the constant-rate phase of drying. Conversely, the effect of the load amount on drying speed was less pronounced during the falling-rate phase. Optimal sensory quality, scoring 16.5, was observed at a microwave setting of 385 watts with a 20 g load. Through the comparison of three mathematical models to simulate drying kinetics, a nonlinear relationship between the moisture ratio of Foshou leaves and the drying time was observed. The Page and Wang-Singh models were particularly effective, with the Wang-Singh model providing superior predictive accuracy. The most accurate fitting function determined was MR=(0.0011+0.0058X1+0.0037X2)t2-(0.086+0.1544X1+0.086X2)t+1. In comparison to hot air drying, the Foshou leaf powder produced under optimal microwave drying conditions showcased a looser and finer particle structure, a vibrant green hue, and enhanced sensory properties, alongside improved wettability, solubility, and a higher preservation of chlorophyll and polyphenols. These insights offer valuable scientific direction for the advanced processing of Foshou leaves, highlighting the potential of microwave drying in augmenting the quality of leaf powders.

     

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