Annotation

Purpose: analysis and construction of hierarchical and facet classifications of reclamation pumping stations (RPS). During the research, a search, analysis, comparison and systematization of RPS types were carried out in accordance with regulatory and technical documentation, as well as the developments of various Russian scientists. When developing and constructing RPS classifications, the following methods were used: facet and hierarchical. 

Discussion. As a result of the study and analysis of various sources of information, it was found that the existing RPS classifications in most cases are presented according to one classification criterion. In this regard, a classification has been carried out at several levels. First, the main classification criteria such as the purpose and main characteristics, including flow and pressure, were determined, according to which the hierarchical classification was built. Subsequently, lower order classification features were considered: importance classes, degree of durability, design, type of building, structure configuration, location relative to the irrigation source, location in the system, degree of use, type of water intake structure and source, devices used and control principle. Based on the indicated classification criteria, hierarchical and facet classifications of the RPS were formed. 

Conclusions. As a result of research, a hierarchical classification of the RPS by main types with a hierarchy of vague subordination up to the seventh level with minor groups of classification characteristics has been developed. The use of the facet method made it possible to combine all types and kinds of RPS into a more detailed classification with the introduction of some independent classification features of lower levels, specifying certain types of RPS within the hierarchical classification levels. The developed hierarchical and facet classifications of RPS make it possible to their further use in the development of a regulatory document on RPS design.

doi: 10.31774/2712-9357-2024-14-3-261-283

For quoting

Kozhanov A. L., Voevodin O. V. On reclamation pumping stations classification. Land Reclamation and Hydraulic Engineering. 2024;14(3):261–283. (In Russ.). https://doi.org/10.31774/2712-9357-2024-14-3-261-283.

Bibliography

1. Gulyuk G.G., Kolganov A.V., Balakay G.T., Bochkarev V.Ya., Voloshkov V.M., Nazarenko V.A., Snipich Yu.F., Shishkin V.O., Guzykin D.S., Guzykina T.N., Burdun A.A., Oleinik A.M., Shramkova E.A., Kozin V.A., Lozovoy V.N., Selyukov V.I., Korchev A.V., Klishin I.V., Selitsky S.A., Senchukov G.A., Slabunov V.V., Dokuchaeva L.M., Yurkova R.E., Kapustyan A.S., Mironov V.I., Kulygin V.A., Ilyinskaya I.N., Voevodin O.V., Skuratov N.S., Kosenko V.O., Vasilyeva E.A., 2003. Normativno-metodicheskoe obespechenie sistemy gosudarstvennogo kontrolya i nadzora v melioratsii [Regulatory and Methodological Support for the System of State Control and Supervision in Land Reclamation]. Novocherkassk, Meliovodinform Publ., 437 p., EDN: VLXFPY. (In Russian).

2. Shchedrin V.N., Vasilyev S.M., Slabunov V.V., Slabunova A.V., Zavalin A.A., 2020. Podkhody k formirovaniyu informatsionnoy sistemy “Tsifrovaya melioratsiya” [Approaches to the information system “Digital Reclamation” formation]. Informatsionnye tekhnologii i vychislitel'nye sistemy [Journal of Information Technologies and Computing Systems], no. 1, pp. 53-64, DOI: 10.14357/20718632200106, EDN: FAWTUT. (In Russian).

3. Vasiliev S.M., Shchedrin V.N., Slabunova A.V., Slabunov V.V., 2019. Na puti k tsifrovoy melioratsii [Towards the digital land reclamation]. Melioratsiya i vodnoe khozyaystvo [Land Reclamation and Water Management], no. 4, pp. 5-9, EDN: XJGCNW. (In Russian).

4. Shchedrin V.N., Senchukov G.A., Slabunov V.V., Churaev A.A., 2012. [The aspects of forming the regulatory basis for reclamation complex in Russia]. Nauchnyy zhurnal Rossiyskogo NII problem melioratsii, no. 3(07), pp. 1-27, available: https:rosniipm-sm.ru/article?n=580 [accessed 15.05.2024], EDN: PCYQAH. (In Russian).

5. Vikulova O.I., Dalchenko D.I., 2023. Normativnye trebovaniya k proektirovaniyu gidrotekhnicheskikh sooruzheniy [Regulatory requirements for the design of hydraulic structures]. Melioratsiya kak drayver modernizatsii APK v usloviyakh izmeneniya klimata: materialy IV Mezhdunarodnoy nauchno-prakticheskoy internet-konferentsii [Land Reclamation as a Driver for the Modernization of the Agro-Industrial Complex under the Conditions of Climate Change: Proc. of the IV International Scientific-Practical Internet Conference]. Novocherkassk, Lik Publ., pp. 96-100, EDN: WHAJDR. (In Russian).

6. Voevodin O.V., Kozhanov A.L., Slabunov V.V., Zhuk S.L., 2010. Vzaimodeystvie organizatsiy razlichnykh spetsializatsiy na stadiyakh zhiznennogo tsikla meliorativnykh sistem [Interaction of organizations of various specializations at the life cycle stages of reclamation systems]. Puti povysheniya effektivnosti oroshaemogo zemledeliya: sb. nauch. trudov [Ways of Increasing the Efficiency of Irrigated Agriculture: Collection of Articles]. Russian Scientific Research Institute of Land Improvement Problems, Novocherkassk, no. 44, pp. 26-33, EDN: SYPCOL. (In Russian).

7. Kozhanov A.L., Kirilenko A.A., 2023. [The composition and location of waterworks of reclamation pumping stations]. Ekologiya i vodnoe khozyaystvo, vol. 5, no. 2, pp. 40-53, available: http:www.ecology-wm.ru/article-3.html?n=178 [accessed 15.05.2024], DOI: 10.31774/2658-7890-2023-5-2-40-53, EDN: RGBGYQ. (In Russian).

8. Sysoev A.N., Astakhova T.S., Smirnova O.V., 2021. Svoystva ierarkhicheskoy struktury UDK: novye dannye [Some features of the UDC hierarchical structure: new data]. Rumyantsevskie chteniya: materialy mezhdunarodnoy nauchno-prakticheskoy konferentsii [Rumyantsev Readings: Proc. of the International Scientific-Practical Conference]. Moscow, Pashkov House Publ., pp. 425-429, EDN: SDYZBI. (In Russian).

9. Mikoni S.V., 2016. O klasse, klassifikatsii i sistematizatsii [About the class, classification and systematization]. Ontologiya proektirovaniya [Ontology of Designing], vol. 6, no. 1(19), pp. 67-80, DOI: 10.18287/2223-9537-2016-6-1-67-80, EDN: VXEGVT. (In Russian).

10. Holena M., Pulc P., Kopp M., 2020. Some frequently used classification methods. Classification Methods for Internet Applications. Studies in Big Data. Cham, Springer, vol. 69, DOI: 10.1007/978-3-030-36962-0_3.

11. Mishra V., Agarwal M., Rajoria R., 2019. Analysis of various classification methods. 2019 International Conference on Issues and Challenges in Intelligent Computing Techniques (ICICT). Ghaziabad, India, pp. 1-4, DOI: 10.1109/ICICT46931.2019.8977688.

12. Nepra A.S., Kidenko N.S., Romanenko N.S., 2021. Meliorativnye nasosnye stantsii. Osnovnye terminy i opredeleniya [Reclamation pumping stations. Basic terms and definitions]. Sistemnyy analiz i sintez modeley nauchnogo razvitiya obshchestva: sb. st. po itogam Mezhdunarodnoy nauchno-prakticheskoy konferentsii [System Analysis and Synthesis of Models of Scientific Development of Society: Collection of Articles Based on the Results of the International Scientific-Practical Conference]. Sterlitamak, International Agency Research, pp. 129-131, EDN: ZAULFA. (In Russian).

13. Kornyushenko S.I., 2014. Nasosnye stantsii [Pumping stations]. Stroitel'naya tekhnika i tekhnologii [Construction Equipment and Technologies], no. 1, pp. 48-51. (In Russian).

14. Beglyarov D.S., Sukharev Yu.I., Ali M.S., 2021. Nasosnye stantsii v sostave pol'dernykh meliorativnykh sistem [Pumping stations as part of polder reclamation systems]. Nauchnaya zhizn' [Scientific Life], vol. 17, no. 4(124), pp. 494-506, DOI: 10.35679/1991-9476-2022-17-4-494-506, EDN: LGBJOU. (In Russian).

15. Ali M.S., Purusova I.Yu., 2023. Osobennosti komponovki pol'dernykh nasosnykh stantsiy v sostave poverkhnostnykh vodotokov [Polder pumping station layout features as a part of surface water courses]. Zhilishchnoe khozyaystvo i kommunal'naya infrastruktura [Housing and Utilities Infrastructure], no. 3(26), pp. 69-78, DOI: 10.36622/VSTU.2023.26.3.007, EDN: NGOKCB. (In Russian). 

16. Prochiy D.V., Volkova E.A., Korzhov V.I., 2023. Ispol'zovanie elementov modelirovaniya raboty meliorativnykh nasosnykh stantsiy pri perekhodnykh gidravlicheskikh rezhimakh [Use of operation simulation elements of the reclamation pumping stations under transient hydraulic modes]. Melioratsiya kak drayver modernizatsii APK v usloviyakh izmeneniya klimata: materialy IV Mezhdunarodnoy nauchno-prakticheskoy internet-konferentsii [Land Reclamation as a Driver for the Modernization of the Agro-Industrial Complex under the Conditions of Climate Change: Proc. of the IV International Scientific-Practical Internet Conference]. Novocherkassk, Lik Publ., pp. 59-64, EDN: QQENNM. (In Russian). 

17. Voevodin O.V., Kirilenko A.A., 2022. [Methodology for assessing the mobility level of reclamation pumping stations]. Melioratsiya i gidrotekhnika, vol. 12, no. 2, pp. 68-83, available: https:rosniipm-sm.ru/article?n=1279 [accessed 20.01.2024], DOI: 10.31774/2712-9357-2022-12-2-68-83, EDN: DYVDLY. (In Russian).

18. Salva A.M., 2016. Rekonstruktsiya golovnoy plavuchey nasosnoy stantsii na reke Lena [Reconstruction of the head floating pumping station on the Lena River]. Sel'skokhozyaystvennye nauki i agropromyshlennyy kompleks na rubezhe vekov [Agricultural Sciences and Agro-Industrial Complex at the Turn of the Century], no. 16, pp. 22-25, EDN: WKRGXB. (In Russian).

19. Kizurov A.S., 2022. Testirovanie razrabotannoy modeli sistemy avtomatizatsii nasosnoy stantsii [Testing the developed model of the pumping station automation system]. Izvestiya Orenburgskogo gosudarstvennogo agrarnogo universiteta [Bull. of Orenburg State Agrarian University], no. 5(97), pp. 131-135, EDN: INWOHQ. (In Russian).

20. Burkova Yu.G., Sokolov A.L., 2017. Vybor optimal'nykh parametrov krupnoy nasosnoy stantsii meliorativnogo i kompleksnogo naznacheniya v usloviyakh neopredelennosti [Selection of optimal parameters of a large pumping station for reclamation and complex purposes under the uncertainty conditions]. Prirodoobustroystvo [Environmental Engineering], no. 4, pp. 62-67, EDN: ZGUVMZ. (In Russian).

21. Beglyarov D.S., Sukharev Yu.I., Ali M.S., Nazarkin E.E., 2021. Osobennosti raboty nasosnykh stantsiy na zakrytykh orositel'nykh sistemakh [Features of pumping stations operation on closed irrigation systems]. Nauchnaya zhizn' [Scientific Life], vol. 16, no. 5(117), pp. 538-553, DOI: 10.35679/1991-9476-2021-16-5-538-553, EDN: PJSCDL. (In Russian). 

22. Tsurikova E.G., Rodionova A.B., Bagnyukova N.E., 2021. Vybor chisla nasosnykh agregatov dlya meliorativnoy nasosnoy stantsii [Selection of the number of pumping units for a reclamation pumping station]. Aktual'nye problemy nauki i tekhniki. 2021: materialy Vserossiyskoy (nats.) nauchno-prakticheskoy konferentsii [Current Issues of Science and Technology. 2021: Proc. of All-Russian (National) Scientific-Practical Conference]. Rostov-on-Don, DGTU, pp. 158-160, EDN: BSZKPC. (In Russian).

23. Dyadyun S.V., Nesterenko L.V., 2015. Vybor optimal'nogo oborudovaniya nasosnykh stantsiy truboprovodnykh sistem pri proektirovanii i rekonstruktsii [The choice of the optimum pump station aggregates structure of pipeline systems while designing and reconstructing]. Tekhnologicheskiy audit i rezervy proizvodstva [Technological Audit and Production Reserves], vol. 3, no. 2(23), pp. 20-23, DOI: 10.15587/2312-8372.2015.44779, EDN: TXOQBB. (In Russian).

24. Abidov K.G., 2020. Povyshenie nadezhnosti raboty meliorativnykh nasosnykh stantsiy s primeneniem samozapuska elektrodvigateley [Improving the reliability of reclamation pumping stations by applying self-starting electric motors]. Elektrooborudovanie: ekspluatatsiya i remont [Electrical Equipment: Operation and Repairing], no. 3, pp. 34-38, EDN: TQCQAD. (In Russian).

25. Abidov K.G., Zaripov O.O., Zaripova Sh.O., 2021. Samozapusk nasosnykh ustanovok meliorativnykh nasosnykh stantsiy [Self-start of reclamation pumping units of pumping stations]. Nauka, tekhnika i obrazovanie [Science, Technology and Education], no. 3(78), pp. 19-24, EDN: OGACZH. (In Russian). 

26. Rakhnyanskaya O.I., Tarasyants S.A., Urzhumova Yu.S., 2017. Puti snizheniya energeticheskikh zatrat na nasosnykh stantsiyakh meliorativnogo naznacheniya [Ways to reduce energy costs at pumping stations for reclamation purposes]. Melioratsiya i vodnoe khozyaystvo. Puti povysheniya effektivnosti i ekologicheskoy bezopasnosti melioratsiy zemel' Yuga Rossii: materialy Vserossiyskoy nauchno-prakticheskoy konferentsii [Land Reclamation and Water Management. Ways to Increase the Efficiency and Environmental Safety of Land Reclamation in the South of Russia: Proc. of All-Russian Scientific-Practical Conference]. Novocherkassk, Lik Publ., vol. 15, pt. 2, pp. 38-42, EDN: YOKHNZ. (In Russian).

27. Tarasyants A.S., Evteev D.O., 2016. Sposoby ekonomii elektroenergii na nasosnykh stantsiyakh meliorativnogo naznacheniya [Methods of saving electricity at pumping stations for reclamation purposes]. Melioratsiya i vodnoe khozyaystvo: materialy nauch.-prakt. konferentsii [Land Reclamation and Water Management: Proc. of Scientific and Practical Conference]. Novocherkassk, Lik Publ., vol. 14, pp. 100-106, EDN: YOFPAL. (In Russian).