Scientific Reports (May 2023)

Improved disinfection performance for 280 nm LEDs over 254 nm low-pressure UV lamps in community wastewater

  • Sean A. MacIsaac,
  • Kyle D. Rauch,
  • Taylor Prest,
  • Richard M. Simons,
  • Graham A. Gagnon,
  • Amina K. Stoddart

DOI
https://doi.org/10.1038/s41598-023-34633-7
Journal volume & issue
Vol. 13, no. 1
pp. 1 – 9

Abstract

Read online

Abstract Ultraviolet (UV) disinfection has been incorporated into both drinking water and wastewater treatment processes for several decades; however, it comes with negative environmental consequences such as high energy demands and the use of mercury. Understanding how to scale and build climate responsive technologies is key in fulfilling the intersection of UN Sustainable Development Goals 6 and 13. One technology that addresses the drawbacks of conventional wastewater UV disinfection systems, while providing a climate responsive solution, is UV light emitting diodes (LEDs). The objective of this study was to compare performance of bench-scale 280 nm UV LEDs to bench-scale low pressure (LP) lamps and full-scale UV treated wastewater samples. Results from the study demonstrated that the UV LED system provides a robust treatment that outperformed LP systems at the bench-scale. A comparison of relative energy consumptions of the UV LED system at 20 mJ cm−2 and LP system at 30 and 40 mJ cm−2 was completed. Based on current projections for wall plug efficiencies (WPE) of UV LED it is expected that the energy consumption of LED reactors will be on par or lower compared to the LP systems by 2025. This study determined that, at a WPE of 20%, the equivalent UV LED system would lead to a 24.6% and 43.4% reduction in power consumption for the 30 and 40 mJ cm−2 scenarios, respectively.