Your search keyword '"KI dosimetry and calorimetric power"' showing total 2 results

1. Contributions of reactor geometry and ultrasound frequency on the efficiency of sonochemical reactor

Author

Jitendra A. Kewalramani, Bruno Bezerra de Souza, Richard W Marsh, and Jay N. Meegoda

Subjects

Acoustic Cavitation, PFAS, Reactor geometry, Power levels, KI dosimetry and calorimetric power, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

An intermediate-scale reactor with 10L capacity and two transducers operating at 700 and 950 kHz frequencies was developed to study the scalability of the sonolytic destruction of Per and Polyfluoroalkyl substance (PFAS). The impact of frequency, height of liquid or power density, and transducer position on reactor performance was evaluated with the potassium iodide (KI) oxidation and calorimetric power. The dual frequency mode of operation has a synergistic effect based on the triiodide concentration, and calorimetric power. The triiodide concentration, and calorimetric power were higher in this mode compared to the combination of both frequencies operating individually. The sonochemical efficiency for an intermediate-scale reactor (10L) was similar that obtained from a bench-scale reactor (2L), showing the scalability of the sonolytic technology. The placement of the transducer at the bottom or side wall of the reactor had no significant impact on the sonochemical reactivity. The superposition of the ultrasonic field from the dual transducer mode (side and bottom) did not produce a synergistic effect compared to the single transducer mode (bottom or side). This can be attributed to a disturbance due to the interaction of ultrasonic fields of two frequencies from each transducer. With the encouraging results scaling up is in progress for site implementation.

Published

2023

2. Contributions of reactor geometry and ultrasound frequency on the efficiency of sonochemical reactor.

Author

Kewalramani, Jitendra A., Bezerra de Souza, Bruno, Marsh, Richard W, and Meegoda, Jay N.

Subjects

*FLUOROALKYL compounds, *ULTRASONIC imaging, *LIQUID density, *POTASSIUM iodide, *TRANSDUCERS, *NUCLEAR reactors, *FAST reactors

Abstract

• Optimization Ultrasound Reactor to treat PFAS. • Impact of geometry, frequency and transducer position for reactor optimization. • Use of KI dosimetry and calorimetric power for reactor optimization. • Scalability of ultrasound for field treatment of PFAS. An intermediate-scale reactor with 10 L capacity and two transducers operating at 700 and 950 kHz frequencies was developed to study the scalability of the sonolytic destruction of Per and Polyfluoroalkyl substance (PFAS). The impact of frequency, height of liquid or power density, and transducer position on reactor performance was evaluated with the potassium iodide (KI) oxidation and calorimetric power. The dual frequency mode of operation has a synergistic effect based on the triiodide concentration, and calorimetric power. The triiodide concentration, and calorimetric power were higher in this mode compared to the combination of both frequencies operating individually. The sonochemical efficiency for an intermediate-scale reactor (10 L) was similar that obtained from a bench-scale reactor (2L), showing the scalability of the sonolytic technology. The placement of the transducer at the bottom or side wall of the reactor had no significant impact on the sonochemical reactivity. The superposition of the ultrasonic field from the dual transducer mode (side and bottom) did not produce a synergistic effect compared to the single transducer mode (bottom or side). This can be attributed to a disturbance due to the interaction of ultrasonic fields of two frequencies from each transducer. With the encouraging results scaling up is in progress for site implementation. [ABSTRACT FROM AUTHOR]

Published

2023