醋酸
丙烯酸
气味
空调
挥发性有机化合物
室内空气质量
环境科学
化学
脉搏(音乐)
制浆造纸工业
条件作用
滤波器(信号处理)
材料科学
室内空气
废物管理
环境化学
环境工程
傅里叶变换红外光谱
降级(电信)
房间空气分配
滤纸
空气质量指数
瞬态(计算机编程)
冷凝
作者
Haihong Tan,Zelong Wu,Wen Siang Tan,Xiaojiao Li,Tianxiang Sun,Chunfeng Lao,Bailiang Liu,Lidia Morawska,Lina Wang
标识
DOI:10.1021/acsestair.5c00457
摘要
Amid rising global temperatures and the growing demand for air conditioning (AC), reports of transient sour and foul odors are also increasing. Using a novel combination of PTR-TOF-MS and FTIR in laboratory simulations, this study found that shifting AC operation from 16 to 26 °C triggers a rapid pulse release of key OCs, including acetaldehyde, acrolein, acetone, acetic acid, acrylic acid, and propionic acid. Concentrations surged within 5 min (e.g., acetic acid rose 11.06 ppbv), peaked around 12 min (19.20 ppbv), and stabilized after approximately 16 min. Total acetic acid emitted in the first 5 min was 736.18 μg. The primary sources were hydrophilic top coatings, whose VOC emission profiles correspond to operational odors under specific thermo-humidity conditions. Secondary sources included acrylic sealants, which released temperature-dependent acids such as acrylic acid, and filter modules, which partially reduced odors via adsorption. The underlying mechanism is described as “low-temperature condensation and enrichment followed by thermally-induced pulse release” driven by variations in the temperature and humidity. Subsequent optimization cut key VOCs within 5 min, achieving 100% propionic acid and 99.88% acetic acid reduction. This work elucidates the physics-driven origin of AC odors, paving the way for next-generation odor-free AC through source-control engineering.
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