A computational study of particle deposition patterns from a circular laminar jet

Abstract

Particle deposition patterns on the plate of inertial impactor with circular laminar jet are investigated numerically with a Lagrangian solver implemented within the framework of the OpenFOAM CFD package. Effects of taper angle of the nozzle channel and jet-to-plate distance are evaluated. The results show that tapered nozzle tends to deposit more particles toward the circular spot edge than straight nozzle. At jet Reynolds number Re = 1132, a tapered nozzle deposits particles to form a pattern with a high density ring toward the deposition spot edge, especially for particle Stokes number St > St50, which is absent with a straight nozzle. Increasing the jet-to-plate distance tends to reduce the value of particle density peak near deposition spot edge. Reducing Re to 283 (e.g., for 300 ccm flow through a 1.5 mm diameter jet nozzle) yields particle deposition patterns without the high density ring at the deposition spot edge when the same tapered nozzle is used. The particle deposition patterns with the straight nozzle at Re = 283 exhibit further reduced particle density around the spot edge such that the particle density profile appears more or less like a Gaussian function. In general, the effect of reducing Re on particle deposition pattern seems to be similar to increasing the jet-to-plate distance. The computed particle deposition efficiency η shows the fact that very fine particles with extremely small values of St near the jet axis always impact the center of plate, indicating that the value of η does not approach zero with a substantial reduction of St. Such a "small particle contamination" typically amounts to 10\% of small particles (with St < 0.1) at Re 1000 and 5\% at Re 300, which may not be negligible in data analysis with inertial impactor measurement.