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Abstract
CT (i.e. concentration × contact time) is one of the critical design and operational parameters to manage pathogen inactivation in ozone treatment. Ozone concentration and contact time are measured using an ozone sensor and a non-reactive tracer test, respectively. The actual CT value, however, might be different from this because of non-ideal flow in an ozone contactor. Hence, there is a need to investigate the spatial actual CT distribution. We developed a method to quantify CT distribution in an ozone contactor using a microsphere and three-dimensional laser-induced fluorescence technology. The dyed carboxylate microsphere, 50 nm in diameter, was used since its fluorescence decreased gradually according to CT without turbidity issues. The microsphere was fed continuously into an ozone contactor and reacted with ozone. After reaching steady state, planar laser sheets scanned a model ozone contactor and induced fluorescence light, which was captured with a high-speed video camera. The image was corrected and calibrated to produce fluorescence distribution, which was further processed into CT in an ozone contactor. We successfully obtained spatial actual CT distribution of a model ozone contactor and identified that CT distribution was not uniform in a model ozone contactor because of non-ideal flow.
Acknowledgments
Dr Roberts in School of Civil and Environmental Engineering, Georgia Institute of Technology is acknowledged for allowing to use the 3D-LIF system. The present research was supported by the research fund from Dankook University in 2012.
Notes
Presented at the 6th International Conference on the “Challenges in Environmental Science and Engineering” (CESE-2013), 29 October–2 November 2013, Daegu, Korea