Abstract
Discouraged by the high-cost and lack of connectivity of indoor air quality (iAQ) measurement equipment, we built a platform that would allow us to investigate what kinds of iAQ evolution information could be collected by a low-cost, distributed sensor network. Our platform measures a variety of iAQ metrics (CO¬2, HCHO, VOC, NO2, O3, Temp., RH), can be flexibly powered by batteries or standard 5W power supplies, and is connected to an infrastructure that supports an arbitrary number of nodes that push data to the cloud and record it in real-time. Some of the sensors used in our nodes generate data in standard units (like ppm or °c), and others provide an analog signal that cannot be directly converted into standard units. To increase the relative precision of measurements taken by different nodes, we placed all 6 pairs of the nodes used in our deployments in the same environment, recorded how they reacted to changing iAQ, and developed calibration functions to synchronize their signals. We deployed the comparatively cross-calibrated nodes to two different buildings on Princeton University’s Campus; a fabrication shop and an office building. In both buildings, we placed nodes at key positions in the ventilation supply chain, providing us with the ability to monitor where indoor air pollutants were being introduced, and when they tended to be introduced – enabling us to monitor the evolution of pollutants temporally and spatially. We find that the occupied space of the fabrication shop of the first building and the open plan office of the second building have higher levels of volatile organic compounds (VOCs) than outside air, indicating that both building's ventilation system is unable to supply enough fresh air to that space to dilute VOCs generated inside. In the second building, we also find indications that other parameters are being driven by set-backs and occupancy. These first deployments demonstrate the ability of low-cost distributed iAQ sensor networks to help researchers identify where and when indoor air pollutants are introduced in buildings.
Highlights
Indoor Air QualityIndoor air pollution presents building occupants with a variety of chronic health risks (Chan et al, 2015)
Using the outlined comparative calibration methodology, we significantly increased the relative precision of the calibrated sensor signals
The Embodied Computation Lab (ECL) deployment showed through the analysis of volatile organic compounds (VOCs) levels over time, and through space, that low-cost distributed sensor clusters can be used to identify where pollutants are being introduced in a simple ventilation supply chain, even at a low spatial resolution
Summary
Indoor air pollution presents building occupants with a variety of chronic health risks (Chan et al, 2015). It has consistently been placed by the US Environmental Protection Agency (EPA) as one of the top five risks to environmental public health (US EPA OAR., 2015). Levels of indoor air pollutants can be two to five times as high as outdoor levels, sometimes reaching 100 times as high (US EPA OAR., 2015) This is alarming when we consider that urban populations spend as much as 90% of their time indoors (Spengler and Sexton, 1983). Given the proportion of their time we spend indoors, it is important that we understand what is in the air we breathe
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
