Abstract
Acoustics can cause particles/droplets to agglomerate in the air medium, thereby accelerating gravity sedimentation. To assess the microphysical characteristics and environmental isotope effects of micro-droplet groups under the action of acoustic waves, an air chamber experimental platform was established, and 100 groups of controlled experiments were conducted. The characteristic particle size, size spectrum, isotope values, corresponding linear relationships with hydrogen and oxygen, and d values were analyzed. The isotope exchange equation between the micro-droplet groups and environmental water vapor inside the air chamber was investigated. The results showed that the peak size values of the micro-droplet groups increased under the action of acoustic waves. The characteristic particle size (D90) showed a “trigger effect” with the acoustic operation with a positive deviation in the size spectrum and isotope exchange between the micro-droplet groups and environmental water vapor. The relative variations in theoretical values for different sedimentation conditions were consistent with those of the experimental results. Environment isotopes could be used to trace the acoustic agglomeration process of micro-droplets in the future.
Highlights
The air chamber was composed of a cylindrical plexiglass tube and a conical bottom plate
The response of the micro-droplet groups to90the acoustic waves can be divided stabilised, and when the acoustic device was turned off, D90 decreased with time and into stabilised
The microphysical characteristics and environmental isotope effects of micro-droplet groups an air chamber exposed to acoustic waves were studied the in microphysical characteristics and environmental isotopethrough effects of indoor experiments, the variations in size and isotopes of the micro-droplets on the acoustic micro-droplet groups in an air chamber exposed to acoustic waves were studied through field and natural conditions were compared, the isotope equation between indoor experiments, the variations in size andand isotopes of the exchange micro-droplets on the acousthe micro-droplet groups and environmental water vapor were established
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Atmospheric aerosol particles are of great concern because of their adverse effects on human health and the environment [1,2,3,4,5,6,7,8]. For PM2.5 and PM10 , the removal of fine particles has attracted the extensive attention of scholars [9,10,11]. Owing to severe environmental pollution and increasingly strict environmental standards, acoustic agglomeration has been proposed as a potential method to remove fine particles and has been proven to have good dust removal efficiency, in high-temperature and high-pressure environments [12,13]
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