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Numerical modelling of a large-scale UV-LED reactor performance – a case study

Research output: Contribution to conference - Without ISBN/ISSN Speech

Published

Standard

Numerical modelling of a large-scale UV-LED reactor performance – a case study. / Zidonis, Audrius; Autin, Olivier; Shah, Jainil et al.
2021. The International Ultraviolet Association 2021 IUVA World Congress, Washington, Maryland, United States.

Research output: Contribution to conference - Without ISBN/ISSN Speech

Harvard

Zidonis, A, Autin, O, Shah, J & Aggidis, G 2021, 'Numerical modelling of a large-scale UV-LED reactor performance – a case study', The International Ultraviolet Association 2021 IUVA World Congress, Washington, United States, 7/06/21 - 8/06/21.

APA

Zidonis, A., Autin, O., Shah, J., & Aggidis, G. (2021). Numerical modelling of a large-scale UV-LED reactor performance – a case study. The International Ultraviolet Association 2021 IUVA World Congress, Washington, Maryland, United States.

Vancouver

Zidonis A, Autin O, Shah J, Aggidis G. Numerical modelling of a large-scale UV-LED reactor performance – a case study. 2021. The International Ultraviolet Association 2021 IUVA World Congress, Washington, Maryland, United States.

Author

Zidonis, Audrius ; Autin, Olivier ; Shah, Jainil et al. / Numerical modelling of a large-scale UV-LED reactor performance – a case study. The International Ultraviolet Association 2021 IUVA World Congress, Washington, Maryland, United States.

Bibtex

@conference{60a6c0ee0dc64c009a4cc361bf798551,
title = "Numerical modelling of a large-scale UV-LED reactor performance – a case study",
abstract = "Performance modelling of the UV-LED based reactor presents unique set of challenges. Intensity of the light propagating from a multitude of small sources can be varying in all three dimensions. Therefore, it is important to accurately model the Light Intensity Distribution (LID) inside of the reactor to ensure the UV fluence distribution is even. Furthermore, flow dynamics inside of the reactor is another important variable. It is modelled using Computational Fluid Dynamics (CFD) and expressed as flow trajectories also known as streamlines. Integration of the LID data and the CFD results is vital when analyzing the reactor design and predicting its performance. In this study, we present a methodology to predict the dose and its distribution in a UV-LED reactor. Moreover, we present metrics to quantify the effect that distribution has on the overall performance of the reactor. We apply this methodology in a case study where we model the state-of-the-art large scale commercial UV LED reactor for a varying set of flow and UV Transmittance (UVT) conditions within its validated range. The performance envelope of a reactor modelled in this case study is 70 to 98 %/cm UVT and 28 to 501 m³/h (12 MLD) flow rate for up to 4 log inactivation of Cryptosporidium, Giardia and adenovirus. Validation was conducted in conjunction with the German Water Centre (TZW) and Carollo Engineers, Inc.",
author = "Audrius Zidonis and Olivier Autin and Jainil Shah and George Aggidis",
year = "2021",
month = jun,
day = "8",
language = "English",
note = "The International Ultraviolet Association 2021 IUVA World Congress, 2021 IUVA World Congress ; Conference date: 07-06-2021 Through 08-06-2021",
url = "https://iuva.org/2021-IUVA-World-Congress",

}

RIS

TY - CONF

T1 - Numerical modelling of a large-scale UV-LED reactor performance – a case study

AU - Zidonis, Audrius

AU - Autin, Olivier

AU - Shah, Jainil

AU - Aggidis, George

PY - 2021/6/8

Y1 - 2021/6/8

N2 - Performance modelling of the UV-LED based reactor presents unique set of challenges. Intensity of the light propagating from a multitude of small sources can be varying in all three dimensions. Therefore, it is important to accurately model the Light Intensity Distribution (LID) inside of the reactor to ensure the UV fluence distribution is even. Furthermore, flow dynamics inside of the reactor is another important variable. It is modelled using Computational Fluid Dynamics (CFD) and expressed as flow trajectories also known as streamlines. Integration of the LID data and the CFD results is vital when analyzing the reactor design and predicting its performance. In this study, we present a methodology to predict the dose and its distribution in a UV-LED reactor. Moreover, we present metrics to quantify the effect that distribution has on the overall performance of the reactor. We apply this methodology in a case study where we model the state-of-the-art large scale commercial UV LED reactor for a varying set of flow and UV Transmittance (UVT) conditions within its validated range. The performance envelope of a reactor modelled in this case study is 70 to 98 %/cm UVT and 28 to 501 m³/h (12 MLD) flow rate for up to 4 log inactivation of Cryptosporidium, Giardia and adenovirus. Validation was conducted in conjunction with the German Water Centre (TZW) and Carollo Engineers, Inc.

AB - Performance modelling of the UV-LED based reactor presents unique set of challenges. Intensity of the light propagating from a multitude of small sources can be varying in all three dimensions. Therefore, it is important to accurately model the Light Intensity Distribution (LID) inside of the reactor to ensure the UV fluence distribution is even. Furthermore, flow dynamics inside of the reactor is another important variable. It is modelled using Computational Fluid Dynamics (CFD) and expressed as flow trajectories also known as streamlines. Integration of the LID data and the CFD results is vital when analyzing the reactor design and predicting its performance. In this study, we present a methodology to predict the dose and its distribution in a UV-LED reactor. Moreover, we present metrics to quantify the effect that distribution has on the overall performance of the reactor. We apply this methodology in a case study where we model the state-of-the-art large scale commercial UV LED reactor for a varying set of flow and UV Transmittance (UVT) conditions within its validated range. The performance envelope of a reactor modelled in this case study is 70 to 98 %/cm UVT and 28 to 501 m³/h (12 MLD) flow rate for up to 4 log inactivation of Cryptosporidium, Giardia and adenovirus. Validation was conducted in conjunction with the German Water Centre (TZW) and Carollo Engineers, Inc.

M3 - Speech

T2 - The International Ultraviolet Association 2021 IUVA World Congress

Y2 - 7 June 2021 through 8 June 2021

ER -