Strategizing of vanguard physicochemical and biological technologies for water treatment in Kuzbass (technological aspect)

The authors use Kuzbass as the example to study strategic approach and methodology of choosing and implementing vanguard (perspective) physicochemical and biological technologies for water treatment plants. They also examine the requirements for purification and disinfection of drinking and waste waters under present conditions characterized by increased anthropogenic loads. These procedures should be carried out with controlling a number of new types of dangerous contaminants. Currently there is no provision for systematic analysis of their presence in water sources before and after their treatment. The authors study the interrelation between forecasting, strategizing, target programming, project management of planning and realization of the priority of implementation of vanguard physicochemical and biological technologies of vanguard physicochemical and biological technologies for water treatment at the water supply and drainage utilities. In the strategic study the authors adduce the overview of perspective trends of development of vanguard physicochemical and biological technologies and the examples of their technical realization which allow fulfilling the strategy’s priority under study within the set of priorities “Development strategy of life supply systems (water supply and water waste). Water utilities as “green economy” translators”. The article studies the levels of water quality control as well as common approaches to building regional water quality control centres and implementing online water quality control. The authors adduce the main competitive advantages that the Kemerovo region possesses to fulfill the priority. Strategizing of the implementation of vanguard physicochemical and biological technologies will provide the opportunity for realizing long-term (up to 15 years long) target programs in water supply and drainage areas in order to improve the performance of water industry.

1. SP 31.13330.2012. Water supply. Pipelines and portable water treatment plants. Updated edition of SNiP 2.04.02-84 *. With change No. 1 . (Red. ot 30.12.2015). Available at: https://adm44.ru/i/u/_31.13330.2012__2.04.02-84_.____1.pdf (accessed: 4.08.2020). (In Russ.)

2. Methodology for developing a register of the best available technologies (BAT) for water supply and sanitation systems. Moscow: National Association of Designers, 2014. 343 p. (In Russ.)

3. Sanitary and Epidemiological Rules and Norms SanPiN 2.1.4.1074-01. Drinking water. Hygienic requirements for water quality of centralized drinking water supply systems. Quality control. Hygienic safety requirements. Resolution of September 26, 2001 No. 24 (as amended on April 2, 2018). Available at: http://docs.cntd.ru/document/901798042 (accessed: 04.08.2020). (In Russ.)

4. Tkachenko I.S., Tkachenko S.N., Lunin V.V. The principles of ‘green chemistry’ using the example of design and operation of an underground water treatment station at a Moscow food processing enterprise for purification out of compounds of iron and the utilization of byproducts. Water Practice & Technology. 2015. Vol. 10. No. 1. Pp. 36–42. DOI: 10.2166/wpt.2015.005

5. Kvint V.L. The Concept of Strategizing. Kemerovo: Kemerovo State University. 2020. 170 p.

6. Kvint V.L. The Concept of Strategizing. St. Petersburg: NWIM RANEPA, 2020. Vol. 2. 164 p.

7. Kvint V.L. Strategic planning in Russia and the world: importance of human interactions. Economics and Management. 2014. No. 11. Pp.15–17. (In Russ.)

8. Khramenkov S.V. Strategy for the development of water supply and sanitation in the city of Moscow until 2020. Birzha intellektual’noi sobstvennosti = Intellectual property exchange. 2007. Vol. 6. No. 7. Pp. 7–16. (In Russ.)

9. Pupyrev E.I. Development of the project of ozone-sorption unit on the reserved territory of south west water station. Delovaya slava Rossii = Business glory to Russia. 2014. No. 2 (45). Pp. 22–23. (In Russ.)

10. Tkachenko I.S., Tkachenko S.N., Lunin V.V. Razrabotka, vnedrenie i opyt ekspluatatsii promyshlennykh sistem otvedeniya i destruktsii ozona [Development, implementation and operational experience of industrial systems for the removal and destruction of ozone]. Collection of materials of the 33rd All-Russian scientific-practical seminar «Ozone and other environmentally friendly oxidants. Science and technology». Moscow: Izd-vo MAKS Press, 2016. Pp. 30–42. (In Russ.)

11. Karelin V.A. Water treatment. Physical and chemical foundations of water treatment processes. Tomsk: Izd-vo Tomskogo politekhnicheskogo universiteta. 2012. 97 p. (In Russ.)

12. Lunin V.V., Samoilovich V.G., Tkachenko S.N., Tkachenko I.S. Teoriya Theory and practice of obtaining and using ozone. Moscow: Izd-vo Moskovskogo universiteta, 2016. 432 p. (In Russ.)

13. Tkachenko I. et al. Two-Stage Ozonation – Adsorption Purification of Ground Water from Trichloroethylene and Tetrachloroethylene with Application of Commercial Carbon. Ozone: Science & Engineering. 2020. Vol. 42. Pp. 357–370. DOI: 10.1080/01919512.2020.1735994

14. Patent 2288183 (RF) Method for treating groundwater from iron and manganese at low temperatures, alkalinity and water hardness. Available at: https://patentinform.ru/inventions/reg-2288183.html (accessed: 04.08.2020). (In Russ.)

15. Domenjoud B. et al. 22rd Ozone Word Congress. Proceed. Barcelona (Spain), 2015. P. 24-4-1.

16. Khokhryakova E. Modern methods of water disinfection. Moscow: Litagent «AkvaTerm», 2014. 110 p.

17. Miklos D.B., Remy C., Jekel M., Linden K.G., Drewes J.E., Hübner U. Evaluation of advanced oxidation processes for water and wastewater treatment - A critical review. Water Research. 2018. Vol. 139. Pp. 118–131. DOI: 10.1016/j.watres.2018.03.042

18. Anastas P.T., Warner J.C. Green Chemistry: Theory and Practice. New York: Oxford University Press, 1998. 148 p.

19. Penru Y. Urban wastewater micropollutant removal by ozonation: Lesson learned from Sophia Antipolis wastewater facility. Techniques – Sciences – Methodes. 2018. No. 6. Pp. 71–83.

20. Sánchez-Castillo M.A., CarrilloPedroza F.R., Fraga-Tovar F., de Jesús SoriaAguilar Ma. Ozonation of cyanide catalyzed by activated carbon. Ozone: Science & Engineering. 2015. Vol. 37. No. 3. Pp. 240–251. DOI: 10.1080/01919512.2014.965804

21. Lunin V.V., Karyagin N.V., Tkachenko S. N. Application and production of ozone. Moscow: Izd-vo: Knizhnyi dom universitet, 2006. 128 p. (In Russ.)

22. Mamleeva N.A., Ben’ko E.M., Lunin V.V. Methods for the neutralization of waste water, gas emissions and production and consumption waste. Moscow: Izd-vo Mos. Universitet, 2019. 352 p. (In Russ.)

23. Sergei Sobyanin: Emissions from the Lyubertsy Wastewater Treatment Plant decreased by 95–97 percent. Available at: https://www.mos.ru/mayor/themes/5299/4819050/ (accessed: 31.05.2020). (In Russ.)

24. Department of Natural Resources and Ecology of the Kemerovo Region. Report on the state and protection of the environment of the Kemerovo region in 2018. Kemerovo, 2019. Available at: http://kuzbasseco.ru/wp-content/uploads/2019/02/Doclad_2018.pdf (accessed: 05.08.2020). (In Russ.)

25. Alekseev G.F., Burtsev S.V., Turgeneva L.A. Ccomprehensive approach to open pit mine water treatment facilities upgrading – «sbucoal» holding company jsc priority task. Ugol’. 2018. No. 6 (1107). Pp. 72–73. (In Russ.). DOI: 10.18796/0041-5790-2018-6-72-73

26. MGUP «Mosvodokanal». Available at: http://www.mosvodokanal.ru. (accessed: 31.05.2020). (In Russ.)

27. SGUP «Moszelenkhoz». Available at: http://www.zelenhoz.ru (accessed: 31.05.2020). (In Russ.)

28. Yanin E.P. Sludge from waterworks (composition, processing, disposal). Ekologicheskaya ekspertiza = Environmental assessment. 2010. No. 5. Pp. 2–45. (In Russ.)

29. Pakhomov A.N., Bitiev A.V., Strel’tsov S.A., Khamidov M.G. Mini-TPP on biogas: the experience of the Moscow State Unitary Enterprise «Mosvodokanal». Available at: http://www.combienergy.ru/stat/1051-Mini-TES-nabiogaze-opyt-MGUP-Mosvodokanal (accessed: 31.05.2020). (In Russ.)

30. ITS 8-2015. Wastewater treatment in manufacture of products (goods), performance of works and provision of services in large enterprises In accordance with the Decree of the Government of the Russian Federation No. 1458 of December 23, 2014. Available at: http://docs.cntd.ru/document/1200128668 (accessed: 05.08.2020). (In Russ.)

31. ITS 10-2015 «Wastewater treatment using centralized drainage systems of settlements, urban districts» Handbook approved by order of Rosstandart No. 1580 dated December 15, 2015, entered into force on July 1, 2016 Available at: http://docs.cntd.ru/document/1200128670 (accessed: 05.08.2020). (In Russ.)

32. Collivignarelli C., Pedrazzani R., Giorgio Bertanza G. A comparison among different wastewater disinfections systems: experimental results. Environ. Technol. 2000. Vol. 21. No. 1. Pp. 1–16. DOI: 10.1080/09593332108618137

33. Moscow has tightened control over the safety of drinking water Available at: https://www.mos.ru/mayor/themes/183299/6470050 (accessed: 31.05.2020).