Performance investigation of the solar direct-driven wood regenerator in liquid desiccant air-conditioning systems

Liquid desiccant air-conditioning (LDAC) systems are one of the most promising alternatives to conventional air conditioning systems due to the high energy efficiency. The most energy-consuming part of LDAS system is desiccant regeneration, while traditional regeneration methods often fail to balance the energy grade and energy efficiency. Inspired by solar heat localization for seawater desalination, the regeneration performance of this novel method has been investigated. Here, we fabricated a wood-based regenerator by drilling holes and spaying Chinese ink, which features high sunlight absorption and strong water transportation ability. Owing to the high hydraulic conductivity of drilled holes and low thermal conductivity of wood substrate, liquid desiccant can be regenerated efficiently with a low-temperature rise. Even for 40 wt% CaCl2 solution at 30 degrees C, the regeneration rate and efficiency can reach 0.64 kg.m(-2) .h(-1) and 43.2 %. Comparisons between solar interfacial regeneration method and other traditional regeneration methods were also conducted. Results show that the solar interfacial method can significantly improve the regeneration rate at the same temperature. Given the low manufacturing cost and operating cost, high regeneration rate and efficiency, superior salt-rejecting property, and low-temperature rise, the wood regenerators based on solar interfacial regeneration show great potential in LDAC systems. (C) 2022 Elsevier B.V. All rights reserved.

Automated summary

Liquid desiccant air-conditioning (LDAC) systems are a promising alternative to conventional air conditioning systems due to their high energy efficiency. This study investigates the regeneration performance of a novel method inspired by solar heat localization for seawater desalination. By fabricating wood-based regenerators and utilizing the solar interfacial regeneration method, efficient regeneration of liquid desiccant is achieved. The results show that the solar interfacial method significantly improves the regeneration rate compared to traditional methods at the same temperature.