Application of Hydrocyclones to Improve Membrane Technologies for Urban Wastewater Treatment

Kassymbekov, Zhuzbay; Akmalaiuly, Kenzhebek; Kassymbekov, Galimzhan

doi:10.12911/22998993/134043

Artykuł - szczegóły

Tytuł artykułu

Application of Hydrocyclones to Improve Membrane Technologies for Urban Wastewater Treatment

Autorzy

Kassymbekov Zhuzbay , Akmalaiuly Kenzhebek , Kassymbekov Galimzhan

Treść / Zawartość

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15_Kassymbekov_Application_JEE_2021_4.pdf

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DOI

10.12911/22998993/134043

Warianty tytułu

Języki publikacji

Abstrakty

The technologies associated with the use of a membrane bioreactor (MBR) are becoming one of the dynamically developing directions in the wastewater disposal system. However, a certain part of the used design of membrane units are exposed to mechanical contamination, which significantly impairs their performance. This is especially noticeable when working at wastewater treatment plants, where the required degree of preliminary cleaning from solid mechanical particles and suspended solids is not provided. The purpose of the work was to improve the process of post-treatment of urban wastewater and protect the membrane element of the installation from clogging with coarse impurities and wear, with an overestimated concentration of suspended solids. The essence of the improved membrane technology of wastewater treatment consists in the preliminary capture of heavy and suspended particles with a size of more than 0.03 microns in a hydrocyclone, followed by water treatment in a chamber of a membrane bioreactor of modern design. The operating conditions of the membranes were determined by the operating modes and parameters of the bioreactor, in particular, by the degree of formation of colloidal compounds in it, which adversely affect the permeability. The density of the initial water varied within 1.059–1.078 g/cm³, and the content of solid particles was up to 0.3 mm. The activated sludge was filtered under vacuum on a Buchner funnel through a thin layer of cotton wool and gauze. During the tests, the indicators for capturing suspended solids were 5.0–9.0 mg/dm³, whereas, when working without a hydrocyclone, they were equal to 27–30 mg/dm³. The maximum performance of the hydrocyclone is provided at an inlet pressure of 225–300 kPa, and the pressure loss in the hydrocyclone chamber is 7.9–9.0 kPa. It was established that additional preparation of waste water for the post-treatment process using a hydrocyclone increases the cleaning capacity of membrane elements by reducing the load of accumulation of coarse impurities on the membrane surface.

Słowa kluczowe

waste water post-treatments membrane technology hydrocyclone testing

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2021

Tom

Vol. 22, nr 4

Strony

148--155

Opis fizyczny

Bibliogr. 29 poz., rys., tab.

Twórcy

autor

Kassymbekov Zhuzbay

jkk2004@mail.ru

Satbayev University, Institute of Architecture and Construction, Department of Engineering Systems and Networks, Almaty, Kazakhstan

https://orcid.org/0000-0001-6445-3584

autor

Akmalaiuly Kenzhebek

Satbayev University, Institute of Architecture and Construction, Department of Engineering Systems and Networks, Almaty, Kazakhstan

autor

Kassymbekov Galimzhan

Kasgidro, Almaty, Kazakhstan

Bibliografia

1. Balandina A.G., Khangildin R.I., Martyasheva V.A., Shundeeva E.V.2015. Hardware for the treatment of difficult-to-oxidize wastewater. Bashkir Chemical Journal, 22, 101–108(in Russian).
2. Bayo J., Lаpez-Castellanos J., Martаn ez-Garcаa R., Alcolea A., Lardаn C.2015. Hydrocyclone as a cleaning device for anaerobic sludge digesters in a wastewater treatment plant, Journal of Cleaner Production, 87, 550–557.
3. Bhardwaj P., Bagdi P., & Sen A.K.2012. Microfluidic device based on a micro-hydrocyclone for particle-liquid separation. Lab on a Chip, 11(23).
4. Bogateev I.A., Polyakov A.M. 2010. Design and construction of small domestic wastewater treatment plants using membrane bioreactor technology (MBR): Int. Forum “Clean Water’2010” / JSC “Mosvodokanalproekt” .Moscow(in Russian).
5. Botantaeva B.S.,Kassymbekov Zh.K., Ni N.P. 2014. Testing of the water-pipe centrifugal vent valvepressure damper in laboratory conditions. Water and Ecology, 2(58),39–44(in Russian).
6. Fazal S., Zhang B., Zhong Z., Gao L., Chen X. 2015. Industrial wastewater treatment by using MBR (Membrane Bioreactor). Review study. Journal of Environmental Protection, 6, 584–598.
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12. Khurmamatov A.M. 2017. Influence of the size of solid particles of mechanical impurities on the efficiency of cleaning a hydrocyclone . Institute of General and Inorganic Chemistry of the Academy of Sciences of RUz, 6, 47–50(in Russian).
13. Lebiocka M. 2020.Application of Hydrodynamic Cavitation to Improve the Biodegradability of Municipal Wastewater.J. Ecol. Eng.21(6),155–160.
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15. Mansour-Geoffrion M., Dold P., Lamarre D., Gadbois, A.2010. Characterizing hydrocyclone performance for grit removal from wastewater treatment activated sludge plants. Minerals Engineering, 23(4), 359–364.
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19. Nosova O. V., Karmanovskaya N. V., Galishevskaya V. V. 2018. Study of water flows of technological water circulation and wastewater metallurgical production in relation to the content of pollutants. Periodico Tche Guimica, 15(30), 550–555.
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22. Sevostianov I., Ivanchuk Y.,Polishchuk J., Lutsyk V., Dobrovolska K., Smailova S., Wójcik W., Kalizhanova A. 2021. Development of the Scheme of the Installation for Mechanical Wastewater Treatment.J. Ecol. Eng.; 22(1), 20–28.
23. Senfter T., Pillei M., Berger M., Bockreis A., Rauch W. and Kraxner M. 2017. Influence of the Viscosity on the Velocity Propagation in Axial Direction in a Rietema Hydrocyclone, AIChE – American Institute of Chemical Engineers – Annual Meeting, Minneapolis USA.
24. SN RK 4.01–03–2011.2012. Wastewater disposal. External networks and facilities (with changes and additions as of 07.11.2019) (in Russian)
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28. Membrane Bioreactor Treating Brewery Wastewater: Relaxation as a Method for Detection of Membrane Fouling. Journal of Environ. Engineering, 147(4).
29. Zhurinov M., Kassymbekov Zh., Kassymbekov G. Zh. 2019. Mastering and development hydropower in Kazakhstan. The National Academy of Sciences of the Republic of Кazakhstan, Series of Geology and Technical Sciences, 3(435), 219–224.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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