Experimental Study of Pathogenic Microorganisms Inactivated by Venturi-Type Hydrodynamic Cavitation with Different Throat Lengths

https://doi.org/10.22146/jcef.38756

Zhiyong Dong(1*), Zhaoyu Qin(2)

(1) College of Civil Engineeringand ArchitectureatZhejiang University of Technology, Hangzhou, CHINA
(2) College of Civil Engineeringand ArchitectureatZhejiang University of Technology, Hangzhou, CHINA
(*) Corresponding Author

Abstract


Based on self-developed Venturi-type hydrodynamic cavitation device with different throat length-radius ratios L/R in Hydraulics Laboratory at Zhejiang University of Technology in China, 4 throat length-radius ratios L/R=10, 30, 60 and 100, and 4 raw water percentages V0/V=25%, 50%, 75%, and 100% were considered, Escherichia coli and total colony count were selected for indicator bacteria, effects of throat length-radius ratio, throat velocity, cavitation time, raw water percentage and cavitation number on inactivating pathogenic microorganism in raw water by hydrodynamic cavitation were experimentally studied. The results showed cavitation damage of cells of pathogenic microorganisms occurred by microjets and shock waves due to cavitation bubble collapse. The lower the flow cavitation number, the higher the killing rate of E. coli and total colony count. When flow velocity was lower or raw water percentage was higher, killing rate gradually increased with increase in throat length-radius ratio; when flow velocity was higher or raw water percentage was lower, killing rate was almost independent of throat length-radius ratio. Inactivated effect of pathogenic microorganisms can be further enhanced by increasing throat velocity or prolonging cavitation time. Hydrodynamic cavitation is a novel disinfection technique for drinking water without disinfection byproducts (DBPs) and no need to add disinfectant.

Keywords


Venturi-type hydrodynamic cavitation; throat length-radius ratio; raw water percentage; pathogenic microorganism; killing rate

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References

Bodurova, D. & Angelov, M., 2004. Intensification the process of water purification by hydrodynamic cavitation. Production and Industrial Engineering Association Scientific Conference with International Participation, Manufacturing and Management in 21st Century. Ohrid, the Republic of Macedonia, University “Ss Cyril and Methodius” – Skopje Faculty of Mechanical Engineering.

Chen, L., Dong, Z. & Lui, C., 2016. Experimental study on disinfection of Escherichia coli by hydrodynamic cavitation behind square multi-orifice plates. Journal of Hydroelectric Engineering, 35(9), pp. 48-54.

Doyle, T. J., 1997. The association of drinking water source and chlorination by-products with cancer incidence among postmenopausal women in Iowa. American Journal of Public Health, 87(7), pp. 1168-1176.

Liu, C., Dong, Z. & Chen, L., 2016. Experimental study of Escherichia coli killed by hydrodynamic cavitation due to circular multi-orifice plates. China Environmental Science, 36(8), pp. 2364-2370.

Save, S. S., Pandit, A. B. & Joshi, J. B., 1994. Microbial cell disruption:role of cavitation. The Chemical Engineering Journal, Volume 55, pp. 67-72.

Save, S. S., Pandit, A. B. & Joshi, J. B., 1997. Use of hydrodynamic cavitation for large-scale cell disruption. Chemical Engineering Research and Design, 75(C1), pp. 41-49.

Simpson, K. L. & Hayes, K. P., 1998. Drinking water disinfection by-products: an Australian perspective. Water Research, 32(5), pp. 1522-1528.

Traube, M., 1894. Leben und Wirken des universellen Privatgelehrten und Wegbereiters der physiologischen Chemie. Med. Dissertation., Signatur 94 HB 1449: Universitätsbibliothek der Humboldt Universität Berlin.

Tsenter, I. & Khandarkhayeva, M., 2012. Effect of hydrodynamic cavitation on microbial inactivation: Potential for disinfection technique, July, Lviv, Ukraine: The 13th Meeting of the European Society of Sonochemistry.

Zhang, X., Dong, Z. & Chen, L., 2016. Experimental study on Escherichia coli killed by hydrodynamic cavitation behind triangular multi-orifice plates. Journal of Hydroelectric Engineering, 35(8), pp. 65-71.



DOI: https://doi.org/10.22146/jcef.38756

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