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引用次数: 0
摘要
本研究旨在开发一种新型微波一体化旋流流化床干燥系统。为此,为了更好地了解该系统的干燥性能、能耗及其对产品质量参数的影响,以绿茶为原料进行了实验。并对该系统进行了数学建模和能量分析。分别在100、300、600和800 W微波功率下进行干燥试验,并计算了干燥过程中一些关键参数,如无因次含水率、含水率和干燥速率。此外,还估算了系统的比能耗(SEC)、比抽湿率和热效率。因此,在所有微波功率下,得到的最佳干燥曲线方程为改进的midli - kuucuk模型。在800 W功率下,产品的最高水提物、最大咖啡因和最小总灰分分别为43.83%、2.2%和5.94%。在800 W时,系统的最小SEC、最大比水分提取率和最大能源效率分别为11.4 KWh kg−1、0.088 kg KWh−1和23.7%。
A Novel Swirling Flow Fluidized Bed Microwave Drying Process
This study aims to develop a novel microwave integrated-swirling flow-fluidized bed drying system. In this regard, for better understanding the drying performance and energy consumption of this novel system and its effect on the product quality parameters, the experiments were performed by using green tea leaves. Also, mathematical modeling and energy analysis was performed for this novel system. Drying experiments were carried out for 100, 300, 600, and 800 W microwave powers and some critical drying parameters such as dimensionless moisture ratio, moisture content, and drying rate were computed. Moreover, specific energy consumption (SEC), specific moisture extraction rate, and thermal efficiency of the system were estimated. Accordingly, the best drying curve equation was obtained as Improved Midilli-Kucuk model for all microwave powers. Moreover, the highest water extract, the maximum caffeine, and the minimum total ash of the product were determined to be 43.83%, 2.2%, and 5.94%, respectively, at 800 W power. Minimum SEC, maximum specific moisture extraction rate, and maximum energy efficiency of the system were estimated as 11.4 KWh kg−1, 0.088 kg KWh−1, and 23.7% at 800 W, respectively.
期刊介绍:
This international research journal focuses on the engineering aspects of post-production handling, storage, processing, packaging, and distribution of food. Read by researchers, food and chemical engineers, and industry experts, this is the only international journal specifically devoted to the engineering aspects of food processing. Co-Editors M. Elena Castell-Perez and Rosana Moreira, both of Texas A&M University, welcome papers covering the best original research on applications of engineering principles and concepts to food and food processes.
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