High-speed imaging and coumarin dosimetry of horn type ultrasonic reactors: influence of probe diameter and amplitude

TL;DR

This study introduces a novel high-speed imaging and coumarin dosimetry approach to analyze vapor fields and chemical effects in ultrasonic reactors, revealing the impact of probe diameter and amplitude on reactor performance.

Contribution

It presents an innovative combination of high-speed imaging and coumarin dosimetry for detailed vapor and chemical activity characterization in ultrasonic reactors, improving upon existing methods.

Findings

Probe diameter significantly influences vapor field structure.

Chemical effectiveness varies with probe size and amplitude.

Method applicable to different ultrasonic reactor configurations.

Abstract

Ultrasound driven cavitation is widely used to intensify lab and industrial-scale processes. Various studies and experiments demonstrate that the acoustic energy, dissipated through the bubbles collapse, leads to intense physicochemical effects in the processed liquid. A better understanding of these phenomena is crucial for the optimization of ultrasonic reactors, and their scale-up. In the current literature, the visual characterization of the reactor reactivity is mainly carried out with sonoluminescence and sonochemiluminescence. These techniques have limitations in the time resolution since a high camera exposure time is required. In this research, we proposed an alternative method, based on coumarin dosimetry to monitor the hydroxylation activity, and high-speed imaging for the visualization of the vapor field. By this approach, we aim to capture the structure and the dynamics of the vapor field and to correlate this with the chemical effects induced in the ultrasonic reactor. This characterization was carried out for four different ultrasonic probe diameters (3, 7, 14 and 40 mm), displacement amplitudes and processing volumes. Key findings indicate that the probe diameter strongly affects the structure of the vapor field and the chemical effectiveness of the system. The proposed methodology could be applied to characterize other types of ultrasonic reactors with different operating and processing conditions.