Abstract
Fine particulate matter (PM) is associated with an increased risk of respiratory and cardiovascular diseases. Fine PM absorbs water molecules at high relative humidity, and then their size grows. Such hygroscopic growth causes a large error when monitoring PM concentrations. To lower the relative humidity, monitors use an indirect heating device, which is large and consumes large amounts of power. The problem with conventional particle separators is that their efficiency depends on temperature and humidity, and their traditional structure, which lets air flow downward. As such, this paper addresses these problems and presents a PM monitor with a new type of dryer that is free from these problems. The proposed monitor requires less energy and has an efficient dehumidifier and a new structure in which air flows upward. The presented experiments were conducted to compare the proposed device with a reference monitor managed by a governmental institute, and to evaluate the effect of the dehumidifier, the relative precision of the proposed devices, and the correlation with the reference monitor. The experimental results showed that the proposed monitor satisfies the U.S. EPA indicators for class III monitors.
Highlights
Four main methods are used for measuring the concentration of particulate matter (PM): gravimetric monitor, beta-radiation attenuation monitor (BAM), tapered element oscillating microbalance (TEOM), and optical particle monitor (OPM)
BAMs indirectly measure the weight of PM using the beta radiation attenuation
BAMs collect atmospheric air during one hour and measure the amount of attenuation of beta radiation that passes through the filter accumulated with PM
Summary
Four main methods are used for measuring the concentration of particulate matter (PM): gravimetric monitor, beta-radiation attenuation monitor (BAM), tapered element oscillating microbalance (TEOM), and optical particle monitor (OPM). BAMs indirectly measure the weight of PM using the beta radiation attenuation. BAMs collect atmospheric air during one hour and measure the amount of attenuation of beta radiation that passes through the filter accumulated with PM. The time resolution of BAM is typically an hour. A BAM model, such as Met One BAM 1020, requires a one-hour cycle, which consists of 4∼8 min for beta measurement, 42 min for air sampling, and 2 min for tape and nozzle movements [1]. Some of the BAM models can provide an output every minute [2]
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