Numeriсal model of the influenсe of ultrasoniс сross fields on the formation of smoke partiсle agglomerates

A method for calculating the behavior and formation of smoke particle agglomerates in cross ultrasonic fields is proposed. The proposed method takes into account: the convergence of agglomerates taking into account the moments of flow forces from the gas flow; rotation of agglomerates due to the moments of forces from the flow around the gas flow; a phase shift between ultrasonic cross fields, which leads to rotation of the resulting vibrational velocity vector and, consequently, to an increase in the effective collision cross-sectional area due to the rotation of the agglomerates. A description of the morphology and position of agglomerates is constructed when representing the agglomerate as a solid body, typical for solid-phase aerosols in the form of smoke. An equation for the dynamics of translational and rotational motion of an agglomerate is obtained taking into account the interaction of particles. The statement about the presence of rotational motion with a limited angular velocity proportional to the sound pressure level is proven, with a phase shift of cross fields equal to 90 degrees. By means of numerical experiments the critical value of the phase shift angle was established, at which the pseudo-rotational motion (change in the rotation angle in a limited range, the width of which is less than 180 degrees) passes into rotational motion (the agglomerate makes a full revolution at an angle of 360 degrees). The critical phase shift depends (weakly) on the sound pressure level and is from 82 to 85 degrees. The transition to rotational motion will increase the efficiency of forming larger agglomerates due to an increase in the average cross-section during particle collisions, caused by the difference in the sizes of agglomerates along different axes. It was established that for the practical implementation of increasing the efficiency of smoke deposition, the most appropriate and feasible is ultrasonic action in cross fields with a frequency difference much lower than the fundamental frequency (from about 100 Hz to 200 Hz). Such action is much easier to implement compared to maintaining a constant phase shift between the cross fields and increases the collision cross-sectional area up to several times.