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Experimental and modeling assessment of a novel automotive cabin PM 2.5 removal system

2018; Taylor & Francis; Volume: 52; Issue: 11 Linguagem: Inglês

10.1080/02786826.2018.1490694

1521-7388

Joshua Vande Hey, Hannah Sonderfeld, Antoine P. R. Jeanjean, Rikesh Panchal, R. J. Leigh, Mark Allen, Mark A. Dawson, P. S. Monks,

Air Quality Monitoring and Forecasting

Poor air quality inside vehicles and its impact on human health is an issue requiring attention, with drivers and passengers facing levels of air pollution potentially greater than street-side outdoor air. This paper assesses the potential effectiveness of a car cabin filtration system to remove fine particulate matter PM2.5 and improve air quality for car passengers. The study was conducted as a practical evaluation coupled to a model implementation. First, the effectiveness of PM2.5 filter material was investigated in a chamber experiment under a range of environmental and loading conditions using a realistic automotive auxiliary scrubber. Second, implementation of such a system was evaluated in a full air flow 3D computational fluid dynamical model configured for a realistic cabin and ventilation system, and related to the chamber results through a simple decay model. Additionally, performance of low-cost dust sensors was evaluated as potential cabin monitoring devices. The experiment and modeling support the feasibility of a robust system which could be integrated into automotive designs in a straightforward manner. Results suggest that an auxiliary scrubber in the rear of the cabin alone would provide suboptimal performance, but that by incorporating a PM2.5 filter into the main air handling system, cabin PM2.5 concentrations could be reduced from 100 µg m−3 to less than 25 µg m−3 in 100 s and to 5 µg m−3 in 250 s. A health impact assessment for hypothetical occupational driver populations using such technology long term showed considerable reductions in indicative PM2.5 attributable mortality.Copyright © 2018 The Authors. Published with license by Taylor & Francis Group, LLC