海藻酸钙水凝胶/硅胶/聚乙烯吡咯烷酮/膨胀石墨复合干燥剂的热特性和吸湿性能

Xin Xiao , Zhengliang Han , Yunfeng Wang , Ming Li
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摘要

固体干燥剂除湿系统可以利用低品位能源进行再生处理,减少电能消耗,从而节约能源,减少碳排放。干燥剂的选择会极大地影响系统的除湿性能。本研究以海藻酸钙水凝胶(CAH)为基质,加入硅胶(SG)、聚乙烯吡咯烷酮(PVP)和膨胀石墨(EG),合成了复合干燥剂,命名为 CAH/SG/EG。随后,对样品的特性进行了分析,并建立了一个除湿系统,以揭示不同工作条件对除湿性能的影响。结果表明,在所有样品中,CAH/SG/20 wt.% EG 具有最佳的吸附动力学。在 25 °C、70 % 相对湿度(RH)条件下,其吸湿能力高达 1.009 g/g,吸湿率为 0.0179 g/(g-min)。特别是在相对湿度为 30% 时,其水分吸附能力仍能达到 0.44 g/g,显示出在较低相对湿度下也有很好的吸附能力。同时,随着 EG 的添加,复合材料的导热系数从 0.449 W/(m-K) 逐渐增加到 0.716 W/(m-K),增加了约 60%。此外,CAH/SG/20 wt.% EG 的除湿性能高于 CAH/SG,而且系统的除湿性能随着进气含湿量、进气温度和进气流量的增加分别呈上升、下降和下降趋势。
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Thermal characterization and moisture adsorption performance of calcium alginate hydrogel/silica gel/polyvinylpyrrolidone/expanded graphite composite desiccant
Solid desiccant dehumidification system can use low-grade energy for regeneration process and reduce the electrical energy consumption, thus saving energy and reducing carbon emissions. The choice of desiccant can significantly affect the dehumidification performance of the system. In the present study, the composite desiccant was synthesized by adding silica gel (SG), polyvinylpyrrolidone (PVP) and expanded graphite (EG) with calcium alginate hydrogel (CAH) as the matrix, named CAH/SG/EG. Subsequently, the characteristics of the samples were analyzed, and a dehumidification system was built to reveal the effects of different working conditions on the dehumidification performances. The results show that CAH/SG/20 wt.% EG has the optimal adsorption kinetics among all samples. Its moisture adsorption capacity reaches up to 1.009 g/g at 25 °C and 70 % relative humidity (RH), and its adsorption rate is 0.0179 g/(g·min). Especially, its moisture adsorption capacity can still reach 0.44 g/g at 30 % RH, showing a good adsorption capacity at lower RH. Simultaneously, the thermal conductivity of composites gradually increases from 0.449 W/(m·K) to 0.716 W/(m·K) with the addition of EG, increasing by about 60 %. In addition, the dehumidification performance of CAH/SG/20 wt.% EG is higher than that of CAH/SG, and the dehumidification performance of the system shows an ascending, descending and descending trends with the increase of inlet air moisture content, inlet air temperature and inlet air flow, respectively.
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