基于集总参数模型的室内PM2.5浓度预测

谢伟; 樊越胜; 王欢; 张鑫; 田国记; 司鹏飞

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中国环境科学 ›› 2020, Vol. 40 ›› Issue (2) : 539-545.

大气污染与控制

基于集总参数模型的室内PM_2.5浓度预测

谢伟¹, 樊越胜², 王欢², 张鑫², 田国记², 司鹏飞^3,4

作者信息 +

Pre-valuation of indoor PM_2.5 concentration based on lumped parameter model

XIE Wei¹, FAN Yue-sheng², WANG Huan², ZHANG Xin², TIAN Guo-ji², SI Peng-fei^3,4

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文章历史 +

摘要

基于颗粒物浓度集总参数模型建立室内PM_2.5预测模型，同时对模型中的关键参数穿透率、沉降率理论模型进行理论计算.以常州市某住宅建筑为例，通过动态模型对穿透率和沉降率模型进行实验验证，实验采样时间为2017年3月~2018年1月.根据实验数据计算换气次数在0.31~0.89h^-1范围内PM_2.5通过维护结构的穿透率为0.78~0.97，室内PM_2.5沉降率为0.3~0.69h^-1.本模型能较好地适用于自然通风、机械通风等不同通风工况室内颗粒物浓度预测.当室外PM_2.5浓度在135~150μg/m³变化时，使用过滤效率为82%的新风系统可维持室内PM_2.5浓度值在40~46μg/m³.

Abstract

Experiments and theoretical analysis were conducted in a residential building in Changzhou to study particle penetration efficiency and deposition rate through establishing lumped parameter model of indoor PM_2.5 concentration. Meanwhile, the accuracy of those models were tested and verified by experiments using a dynamic model, and the collection time from March 2017 to January 2018. According to the experimental data, the result of PM_2.5 penetration efficiency was 0.78 to 0.97, while for deposition rate, it was 0.3 to 0.69h^-1 when air exchange rate ranged from 0.31 to 0.89h^-1. The models could be well applied to indoor particle prediction under different ventilation methods such as natural ventilation, mechanical ventilation, etc. The indoor PM_2.5 concentration ranged from 40 to 46μg/m³ by using fresh air system with 82% filtration efficiency, while outdoor PM_2.5 concentration was 135 to 150μg/m³.

导出引用

谢伟, 樊越胜, 王欢, 张鑫, 田国记, 司鹏飞. 基于集总参数模型的室内PM_2.5浓度预测[J]. 中国环境科学. 2020, 40(2): 539-545

XIE Wei, FAN Yue-sheng, WANG Huan, ZHANG Xin, TIAN Guo-ji, SI Peng-fei. Pre-valuation of indoor PM_2.5 concentration based on lumped parameter model[J]. China Environmental Science. 2020, 40(2): 539-545

中图分类号： X513

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