Mathematical modeling of gas-phase mass transfer in hydrous materials for a total heat exchange ventilator

IF 7.1 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Building and Environment Pub Date : 2024-11-09 DOI:10.1016/j.buildenv.2024.112291
Xin Wang , Hajime Sotokawa , Taisaku Gomyo , Sung-Jun Yoo , Juyeon Chung , Kazuhide Ito
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Abstract

Total heat exchange ventilation systems are effective in achieving energy savings by reducing the ventilation load in buildings, while maintaining a certain amount of fresh outdoor air intake. As the system's elemental materials exchange both latent and sensible heat, hydrophilic chemical compounds may be exchanged simultaneously. Proper control of the exchange of hazardous chemicals and pollutants via these heat exchange elements is an important issue in the development of total heat exchange ventilation systems. In this respect, the development of a numerical model that facilitates repeated sensitivity analysis is important in the development of a new total heat exchanger that has high heat exchange efficiency and suppresses the exchange of polluting chemicals. This study proposes new hygrothermal and chemical compound transfer models for paper-based hydrous materials, which are the main components of total heat exchangers in indoor ventilation systems. Through a series of numerical analyses and experimental measurements, the prediction accuracy of the mathematical model was compared with experimental results for the gas transfer rate in hydrous materials and a building-sized total heat exchanger. The results demonstrated that an increase in water content in hydrous material has a significant impact on the permeability of water-soluble gases, with NH3 and HCHO permeability coefficients increasing by factors of 250 and 20 respectively. Conversely, for low-solubility gases such as CO2, the permeability coefficient only slightly increased at low humidity and remained largely unaffected thereafter. These findings contribute to the advancement of more efficient and safer total heat exchange ventilation systems.
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用于全热交换通风器的含水材料气相传质数学模型
全热交换通风系统在保持一定的室外新鲜空气吸入量的同时,还能减少建筑物的通风负荷,从而有效地节约能源。由于系统的元素材料可以交换潜热和显热,亲水性化合物也可以同时交换。在开发全热交换通风系统时,一个重要的问题就是要适当控制通过这些热交换元件交换的有害化学物质和污染物。在这方面,建立一个便于反复进行敏感性分析的数值模型,对于开发具有高热交换效率和抑制污染化学物质交换的新型全热交换器非常重要。本研究针对室内通风系统中全热交换器的主要组成部分--纸基含水材料,提出了新的湿热和化学复合传质模型。通过一系列数值分析和实验测量,将数学模型的预测精度与含水材料和建筑规模全热交换器中气体传输速率的实验结果进行了比较。结果表明,含水材料中水含量的增加对水溶性气体的渗透性有显著影响,NH3 和 HCHO 的渗透系数分别增加了 250 倍和 20 倍。相反,对于二氧化碳等低溶解度气体,渗透系数在低湿度时仅略有增加,此后基本不受影响。这些发现有助于开发更高效、更安全的全热交换通风系统。
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来源期刊
Building and Environment
Building and Environment 工程技术-工程:环境
CiteScore
12.50
自引率
23.00%
发文量
1130
审稿时长
27 days
期刊介绍: Building and Environment, an international journal, is dedicated to publishing original research papers, comprehensive review articles, editorials, and short communications in the fields of building science, urban physics, and human interaction with the indoor and outdoor built environment. The journal emphasizes innovative technologies and knowledge verified through measurement and analysis. It covers environmental performance across various spatial scales, from cities and communities to buildings and systems, fostering collaborative, multi-disciplinary research with broader significance.
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