Experimental validation of design and performance parameters of radioactive particle tracking (RPT) experimentation

In recent years, radioactive particle tracking (RPT) has emerged as a powerful noninvasive technique for characterization and visualization of flow in opaque multiphase flow reactors. This technique has been applied to a variety of multiphase flow reactors largely based on the theoretical framework for optimal design and performance parameters. No systematic evaluation and validation of the design and performance parameters of the RPT technique has been reported in the literature thus far. Consequently, the theoretical framework for the design of RPT experiments has had limited scalability and application to a wide variety of flow systems. Thus far, design of a “good” RPT experiment continues to be an art, no matter how much the richness of flow of information that the experimental method brings. The present work reports systematic experimental evaluation of design parameters for an optimal RPT experiment and validation of the theoretical results reported in literature. The experiments were performed in a carefully designed setup in which precise positioning of the tracer particle was made possible. The experiments assess the effect of various parameters on the performance of the RPT experiment, such as the choice of radioactive isotope, activity, gamma-ray energy, size of the detector, and relative positioning of detectors. Finally, a set of recommendations based on experimental work are provided to “optimally” perform the RPT experiment in any single or multiphase reactor. •The design parameters of RPT were experimentally evaluated.•The theoretical results reported in the literature of theoretical evaluation were validated.•Scandium-46 was found to be the most suitable radioisotope for RPT studies.•NaI (Tl) detector with a crystal size of 5 cm × 5 cm was found to be most efficient.•Three detectors in a particular plane were sufficient to obtain accurate results.