Neutralizing Aminesin Boiler Steam and Humidified Indoor Air

A. Gomes, Ye Tao, A. Bhuiyan, Dongjie Guan, F. Memarzadeh
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Abstract

The health and comfort of the indoor population have been impacted by the humidity. While people are increasingly spending more time indoors, the presence of pollutants and lack of proper humidification in indoor air have significant risk factors that may lead to multiple health problems. By applying the right air purification and/or humidification system, the adverse effects of poor indoor air quality can be minimized. Direct steam addition is a common technique to humidify the indoor air of a building. Carbon dioxide or other acidic process contaminants may dissolve in steam or steam condensate that will consequently decrease the pH and make it corrosive for the steam distribution system. To avoid that, neutralizing amines are added to steam that keeps the pH neutral or slightly alkaline(pH 7.5-9.0). However, neutralizing amines have some toxic effects. OSHA, FDA, and NIOSH prescribe maximum concentration limits for them in indoor air. The Central Utility Plant (CUP) of National Institutes of Health (NIH) uses a 50:50 blend of cyclohexylamine and diethylaminoethanol as neutralizing agents for the steam. The CUP at NIH presents the results of monitoring the concentration level of amines through mass balance, online monitoring at specified location of the steam distribution system and field measurement in humidified indoor air at buildings on campus. Through theoretical calculation backed up by field measurement, the amine concentration of indoor air is determined to be well below the FDA regulated limits.
中和锅炉蒸汽和加湿室内空气中的胺
室内人群的健康和舒适受到湿度的影响。虽然人们在室内的时间越来越长,但污染物的存在和室内空气缺乏适当的加湿是可能导致多种健康问题的重大风险因素。通过应用正确的空气净化和/或加湿系统,可以最大限度地减少室内空气质量差的不利影响。直接加蒸汽是一种常用的加湿建筑物室内空气的技术。二氧化碳或其他酸性过程污染物可能会溶解在蒸汽或蒸汽冷凝水中,从而降低pH值并使其对蒸汽分配系统具有腐蚀性。为了避免这种情况,在蒸汽中加入中和胺,使pH值保持中性或微碱性(pH值7.5-9.0)。然而,中和胺有一些毒性作用。OSHA, FDA和NIOSH规定了它们在室内空气中的最大浓度限制。美国国立卫生研究院(NIH)的中央公用事业工厂(CUP)使用50:50的环己胺和二乙胺乙醇混合物作为蒸汽的中和剂。美国国立卫生研究院的CUP通过质量平衡、蒸汽分配系统指定位置的在线监测和校园建筑物加湿室内空气的现场测量来监测胺的浓度水平。通过现场测量支持的理论计算,确定室内空气中的胺浓度远低于FDA规定的限制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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