模拟干燥室空气湿度比对真空冷冻干燥中材料蒸发速率的影响

I. Buana, E. Kosasih
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引用次数: 0

摘要

在干燥过程中,有几个参数会影响蒸发率。除压力和温度外,干燥室的空气湿度也会影响蒸发率。为了解空气湿度对真空冷冻干燥机(VFD)系统中蒸发率的影响程度,需要进行计算和模拟。真空冷冻干燥机中的蒸发是在低于水的三相点的蒸发条件下通过升华进行的。重量为 2x10-2 千克的冰被用作干燥材料,以表征温度为 -10oC 的 VFD 过程。冰的温度和工作压力都选在低于三相点的条件下,以便发生升华蒸发。加热干燥室的温度变化为(20、25、30)(oC),压力变化为(0.5、0.4、0.3)(kPa)。空气湿度比在 (300, 200, 100, 10, 1, 0.1, 0.01, 0.001) (kg H2O/kg dry air) 下变化。模拟在烘干室中进行,冰块因与室温的温差而受热,热量通过辐射和扩散传递。热量用于通过升华蒸发冰。升华后冰的温度接近湿球温度,并保持恒定,直到冰完全蒸发。通过模拟可知,将烘干室的空气湿度比从 300(千克水/千克干空气)改为 0.001(千克水/千克干空气)将使蒸发率提高 6.2% - 9.5%。在 P∞=0.3kPa、T∞=30oC 时,蒸发率增加了 6.2%。蒸发率的增加使干燥时间缩短了 0.42 小时。当压力 P∞=0.5kPA, T∞=20oC 时,蒸发率增加了 9.5%,从而使干燥时间缩短了 1.03 小时。模拟结果表明,提高蒸发率和缩短干燥时间有可能提高变频驱动装置的能效。蒸发率的提高受工作温度和压力的影响。模拟证实,当干燥室温度升高、气压降低时,蒸发率会增加。
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Simulation of the Effect of Air Humidity Ratio in the Drying Room on the Rate of Material Evaporation in Vacuum Freeze Drying
In the drying process there are several parameters that influence the evaporation rate. Apart from pressure and temperature, air humidity in the drying room has been shown to influence the evaporation rate. To find out how much influence air humidity has on the evaporation rate in a Vacuum Freeze Dryer (VFD) system, calculations and simulations need to be carried out. Evaporation in a VFD occurs by sublimation at evaporation conditions below the triple point of water. Ice weighing 2x10-2 kg was used as dry material to characterize the VFD process at a temperature of -10oC. The ice temperature and operating pressure are selected at conditions below the triple point so that sublimation evaporation occurs. The temperature of the drying room for heating was varied, namely (20, 25, 30)(oC) and pressure (0.5, 0.4, 0.3)(kPa). Air humidity ratio, varies at (300, 200, 100, 10, 1, 0.1, 0.01, 0.001) (kg H2O/kg dry air). The simulation is carried out in a drying room, the ice receives heat due to the temperature difference with room temperature, heat transfer occurs by radiation and diffusion. Heat is used to evaporate the ice through sublimation. The temperature of the ice upon sublimation is close to the wet bulb temperature and remains constant until the ice has completely evaporated. From the simulation it is known that changing the air humidity ratio in the drying room from 300 (kg H2O/kg dry air) to 0.001 (kg H2O/kg dry air) will increase the evaporation rate between 6.2% - 9.5%. The evaporation rate increased by 6.2% was obtained at P∞=0.3kPa, T∞=30oC. This increase in evaporation rate shortened the drying time by 0.42 hours. The evaporation rate increased by 9.5% at a pressure of P∞=0.5kPA, T∞=20oC thereby shortening the drying time by 1.03 hours. Simulations show that increasing the evaporation rate and shortening the drying time has the potential to increase the energy efficiency of the VFD. The increase in evaporation rate is influenced by operating temperature and pressure. Simulations confirmed that the evaporation rate increased when the drying chamber temperature was increased and the air pressure was decreased.
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来源期刊
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
2.40
自引率
0.00%
发文量
176
期刊介绍: This journal welcomes high-quality original contributions on experimental, computational, and physical aspects of fluid mechanics and thermal sciences relevant to engineering or the environment, multiphase and microscale flows, microscale electronic and mechanical systems; medical and biological systems; and thermal and flow control in both the internal and external environment.
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