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基于活性炭的物理吸附剂和先进复合吸附剂的吸湿性能及热性能的比较评估

Comparative Assessment of Hygroscopic Properties and Thermal Performance of Activated Carbon-Based Physical Adsorbents and Advanced Composite Adsorbents.

作者信息

Wei Siyu, Fan Zhengpeng, Zhang Songyu, Xiao Yutong, Wang Chunhao, Peng Shanbi, Zhang Xueying

机构信息

Safety, Environment and Technology Supervision Research Institute, PetroChina Southwest Oil and Gas Field Company, Chengdu 610041, China.

School of Civil Engineering and Geomatics, Southwest Petroleum University, Chengdu 610500, China.

出版信息

Materials (Basel). 2025 May 14;18(10):2280. doi: 10.3390/ma18102280.

DOI:10.3390/ma18102280
PMID:40429015
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12112874/
Abstract

The water adsorption property was shown to be the critical process limiting the thermal output in the adsorption heat storage driven by the air humidity process, which was different for the physical adsorbent and the physical/chemical adsorbent. In this study, coconut shell-based activated carbon (CAC), a hierarchically porous material that is both low-cost and mass-producible, was utilized as a physical adsorbent and as a matrix for loading calcium chloride (CAC/Ca). The incorporation of calcium chloride in CAC, with a 24% content, resulted in a 4~102% increase in water uptake capacity. The water uptake dynamics of high-thickness adsorbents are inhibited, especially for CAC/Ca. In the context of the adsorption test conducted within a fixed-bed reactor, an increase in air velocity was observed to facilitate water vapor supply, thereby culminating in higher output temperatures for both CAC and CAC/Ca, indicating a higher hydration conversion. The maximum discharge powers of CAC/Ca increased from 2 kW/m to 20 kW/m, with the air velocity increasing from 0.5 m/s to 2.5 m/s. The heat-release densities of CAC and CAC/Ca at the air velocity of 2.5 m/s were 156 kJ/kg and 547 kJ/kg, respectively.

摘要

水吸附特性被证明是限制空气湿度驱动的吸附蓄热中热输出的关键过程,这对于物理吸附剂和物理/化学吸附剂而言是不同的。在本研究中,椰壳基活性炭(CAC),一种低成本且可大规模生产的分级多孔材料,被用作物理吸附剂以及负载氯化钙的基质(CAC/Ca)。在CAC中加入24%含量的氯化钙,导致吸水能力提高了4%至102%。高厚度吸附剂的吸水动力学受到抑制,尤其是对于CAC/Ca。在固定床反应器内进行的吸附试验中,观察到空气流速的增加有助于水蒸气供应,从而使CAC和CAC/Ca的输出温度更高,表明水合转化率更高。随着空气流速从0.5米/秒增加到2.5米/秒,CAC/Ca的最大放电功率从2千瓦/平方米增加到20千瓦/平方米。在2.5米/秒的空气流速下,CAC和CAC/Ca的放热密度分别为156千焦/千克和547千焦/千克。

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本文引用的文献

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2
Simultaneous impregnation and microencapsulation of CaCl using silica gel and methyl cellulose for thermal energy storage applications.使用硅胶和甲基纤维素对氯化钙进行同步浸渍和微胶囊化以用于热能存储应用。
Sci Rep. 2024 Mar 26;14(1):7183. doi: 10.1038/s41598-023-50672-6.
3
Softness of hydrated salt crystals under deliquescence.
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Nat Commun. 2023 Feb 25;14(1):1090. doi: 10.1038/s41467-023-36834-0.
4
Discovery of Salt Hydrates for Thermal Energy Storage.用于热能储存的盐水合物的发现
J Am Chem Soc. 2022 Nov 30;144(47):21617-21627. doi: 10.1021/jacs.2c08993. Epub 2022 Nov 17.
5
Adsorption of water on an MgSO4 (100) surface: a first-principles investigation.水在 MgSO4(100)表面的吸附:第一性原理研究。
Chemphyschem. 2013 Jun 24;14(9):1969-76. doi: 10.1002/cphc.201300077. Epub 2013 Apr 29.