Weilong Wang

An Overview of Adsorbents in the Rotary Desiccant Dehumidifier for Air Dehumidification

This review discusses the challenges and opportunities for adsorptive dehumidification for rotary desiccant dehumidifiers. As well, it presents an overview of current approaches and emerging technologies in the development of high-performance adsorbents for air dehumidification, including silica materials, activated carbons (ACs), supported haloid-based salts, zeolites, metal organic frameworks (MOFs), etc. The adsorption–desorption characteristics—that is, adsorption isotherms—and adsorption kinetics of different kinds of adsorbents are reviewed and further discussed. Some important issues to further advance the research and development of adsorptive dehumidification for rotary desiccant dehumidifiers are also summarized in this work.

Enhanced specific heat capacity of binary chloride salt by dissolving magnesium for high-temperature thermal energy storage and transfer

Thermal energy storage and transfer technology has received significant attention with respect to concentrating solar power (CSP) and industrial waste heat recovery systems. In this study, we report a novel method to synthesize nanofluids by dissolving magnesium metal in NaCl–CaCl2 eutectic molten salt to enhance the specific heat capacity without the conventional agglomerate effect of nanoparticles. It was found that the solubility of magnesium in the binary molten salt reached 0.075% and 0.185% at 550 °C and 750 °C, respectively. Magnesium did not react with the molten salt but dissolved in it in the form of liquid magnesium metal and did not change the melting temperature of the binary molten salt. The liquid specific heat capacities of nanofluids containing 1.0 wt% and 2.0 wt% magnesium were 1.12 J g−1 °C−1 and 1.15 J g−1 °C−1, which were 105.66% and 108.49% higher than those of the binary chloride salts. Magnesium decreased the upper temperature limit and thermal stability, and the nanofluid was thermally and chemically stable after 50 heating/cooling cycles. These results implied that the resulting nanofluid is a promising candidate material for high-temperature heat storage and transfer applications.