Adsorption Isotherm and Kinetics of Water Vapor Adsorption Using Novel Super-Porous Hydrogel Composites

H. Mittal, Ali Al-Alili, S. Alhassan
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引用次数: 3

Abstract

Deliquescent salts have high water vapor adsorption capacity, but they dissolve in water by forming crystalline hydrates. That restricts their use in different water vapor adsorption applications. However, this limitation can be overcome by incorporating deliquescent salts within a polymer matrix which will keep the salt solution in place. Furthermore, if the polymer matrix used is also capable of adsorbing water vapor, it will further improve the overall performance of desiccant system. Therefore, in this work, we are proposing the synthesis and use of a highly effective new solid polymer desiccant material, i.e. superporous hydrogel (SPHs) of poly(sodium acrylate-co-acrylic acid (P(SA-co-AA)), and subsequently its composite with deliquescent salt, i.e. calcium chloride (CaCl2), to adsorb water vapors from humid air without the dissolution of the salt in the adsorbed water. Parental PAA-SPHs matrix alone exhibited an adsorption capacity of 1.02 gw/gads which increased to 3.35 gw/gads after incorporating CaCl2 salt in the polymer matrix. Both materials exhibited type-III adsorption isotherm and the experimental isotherm data fitted to the Guggenheim, Anderson and Boer (GAB) isotherm model. However, the adsorption kinetics followed linear driving force model which suggested that this extremely high adsorption capacity was due to the diffusion of water molecules into the interconnected pores of SPHs via capillary channels followed by the attachment of adsorbed water molecules to the CaCl2 salt present in the polymer matrix. Furthermore, the adsorbents were used successively for six cycles of adsorption with a very little loss in adsorption capacity. Therefore, the proposed polymer desiccant material overcomes the problem of dissolution of deliquescent salts and opens the doors for a new class of highly effective solid desiccant material.
新型超多孔水凝胶复合材料水蒸气吸附等温线及动力学研究
潮解盐具有较高的水蒸气吸附能力,但溶于水时形成结晶水合物。这限制了它们在不同的水蒸气吸附应用中的使用。然而,这一限制可以通过在聚合物基质中加入潮解盐来克服,这将使盐溶液保持原位。此外,如果所使用的聚合物基质也能够吸附水蒸气,将进一步提高干燥剂系统的整体性能。因此,在这项工作中,我们建议合成和使用一种高效的新型固体聚合物干燥剂材料,即聚(丙烯酸钠-共丙烯酸(P(SA-co-AA))的超孔水凝胶(SPHs),并随后将其与潮解盐,即氯化钙(CaCl2)复合,以吸附潮湿空气中的水蒸气而不会溶解在吸附水中。单独亲本PAA-SPHs基质的吸附容量为1.02 gw/gads,加入CaCl2盐后,吸附容量增加到3.35 gw/gads。两种材料均表现出iii型吸附等温线,实验等温线数据符合Guggenheim, Anderson and Boer (GAB)等温线模型。然而,吸附动力学遵循线性驱动力模型,这表明这种极高的吸附能力是由于水分子通过毛细管通道扩散到SPHs的互连孔中,然后吸附的水分子附着在聚合物基质中的CaCl2盐上。此外,在吸附容量损失很小的情况下,连续使用了6次吸附剂。因此,所提出的聚合物干燥剂材料克服了潮解盐的溶解问题,为一类新型高效固体干燥剂材料打开了大门。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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