Purpose: development of methodology for determining the irrigation rate value, which ensures the formation of a primary local contour of moistened soil in the soil space under drip irrigation with one emitter.
Materials and methods. The methodological and factual basis of the development were materials and empirical dependencies obtained from the data of author's field studies of local moisture contours formed under various soil conditions with above-surface and surface drip irrigation.
Results and discussion. The analysis and evaluation of known approaches to the calculation of irrigation rates for drip irrigation of plants is carried out, the direction of the development of the methodology is determined. Based on materials of field and office studies, 11 contour profiles of drip-moistened soil formed under various soil and technological conditions of drip irrigation were obtained. Soil conditions are characterized by a wide range of changes in their parameters: the content of physical clay is from 20.8 to 74.6 % of the dry soil mass (DSM), the lowest moisture capacity is from 16.9 to 32.2 % of DSM, the level of additional irrigation moisture is from 60 to 70 % of the lowest moisture capacity. Moisture contours were formed with an average soil moisture content of 90 % of the lowest moisture capacity. Empirical dependencies for determining the maximum and average radius (diameter) of moisture contours at given depths of the moistened soil layer, which make it possible to predict the volumes of moisture contours are obtained. The dependence and a method for calculating the irrigation rate value, which ensures the formation of a moisture contour of a given depth and a given level of soil moisture, are obtained for a wide range of granulometric and water-physical characteristics of soils.
Conclusion. A method for calculating the irrigation rate required for the formation of a local moisture contour in soil space with specified dimensional and moisture parameters during irrigation water delivery by one drip micro emitter is proposed.
doi: 10.31774/2712-9357-2023-13-1-19-38
drip irrigation, irrigation rate, soil moisture, drip-moistened contour, moisture contour average diameter, moisture contour volume
Shtanko A. S., Shkura V. N. Determining the irrigation rate for drip-moistened soil primary local contour formation. Land Reclamation and Hydraulic Engineering. 2023;13(1):19–38. (In Russ.). https://doi.org/10.31774/2712-9357-2023-13-1-19-38.
1. Kapel'noe oroshenie: posobie k SNiP 2.06.03-85 “Meliorativnye sistemy i sooruzheniya” [Drip Irrigation: manual to SNiP 2.06.03-85 “Reclamation Systems and Structures”]. Moscow, Soyuzvodproekt Publ., 1986, 149 p. (In Russian).
2. Oleinik A.M., Gadzhiev M.K., 1984. Kharakter formirovaniya konturov uvlazhneniya pochvy pri kapel'nom oroshenii [The nature of formation of soil moisture contours under drip irrigation]. Rezhimy orosheniya i vodopotreblenie sel'skokhozyaystvennykh kul'tur na Severnom Kavkaze [Irrigation Regimes and Water Consumption of Agricultural Crops in the North Caucasus]. Novocherkassk, pp. 129-133. (In Russian).
3. Yasonidi O.E., 2011. Kapel'noe oroshenie [Drip Irrigation]. Novocherkassk, Lik Publ., 322 p. (In Russian).
4. Khrabrov M.Yu., 1999. Raschet rasprostraneniya vlagi v pochve pri kapelnom oroshenii [Calculation of moisture distribution in soil during drip irrigation]. Melioratsiya i vodnoe khozyaystvo [Irrigation and Water Management], no. 4, pp. 34-35. (In Russian).
5. Akhmedov A.D., Galiullina E.Yu., 2012. Kontury uvlazhneniya pochvy pri kapel'nom oroshenii [Contours of soil moistening under drip irrigation]. Izvestiya Nizhnevolzhskogo agrouniversitetskogo kompleksa: nauka i vysshee professional'noe obrazovanie [Proceedings of Nizhnevolzhsky Agro-University Complex: Science and Higher Professional Education], no. 3, pp. 183-188. (In Russian).
6. Melikhova E.V., 2019. Modelirovaniya protsessov vlagoperenosa pri orositel'nykh melioratsiyakh s uchetom evapotranspiratsii [Modeling of moisture transfer processes under irrigation taking into account evapotranspiration]. Paradigma agrarnogo obrazovaniya v usloviyakh tsifrovoy ekonomiki: materialy mezhdunarodnoy nauchno-prakticheskoy konferentsii [Paradigm of Agrarian Education under the Conditions of Digital Economy: Proc. of International Scientific-Practical Conference]. Volgograd, pp. 355-362. (In Russian).
7. Rogachev A.F., Melikhova E.V., 2021. Kompyuternoe modelirovanie i parametrizatsiya v srede MathCAD konturov uvlazhneniya pri kapelnom oroshenii [Computer modeling and parameterization in the MathCAD environment of moisture contours during drip irrigation]. Izvestiya Nizhnevolzhskogo agrouniversitetskogo kompleksa: nauka i vysshee professional'noe obrazovanie [Proceedings of Nizhnevolzhsky Agro-University Complex: Science and Higher Professional Education], no. 4(64), pp. 367-378, DOI: 10.32786/2071-9485-2021-04-37. (In Russian).
8. Zhatkanbaeva A.O., Kozykeeva A.T., Mustafaev Zh.S., 2016. Matematicheskoe modelirovanie lineynogo parametra konturov uvlazhneniya pri kapel'nom oroshenii [Mathematical modeling linear parameter of moisture contours under drip irrigation]. Issledovaniya i rezul'taty [Research and Results], no. 2, pp. 120-127. (In Russian).
9. Pronko N.A., Korsak V.V., Kadnova Yu.Yu., Phillipova M.Yu., Baklushina O.A., 2020. Raschet polivnykh norm pri kapel'nom oroshenii v usloviyakh sukhostepnogo Za-volzh'ya [Calculation of irrigation rates for drip irrigation under the conditions of Trans-Volga dry steppe]. Osnovy ratsional'nogo prirodopol'zovaniya: materialy VI Natsionalnoy konferentsii s mezhdunarodnym uchastiem [Basis of Rational Use of Nature Resources: Proc. of VI National Conference with International Participation]. Saratov, pp. 55-59. (In Russian).
10. Shkura V.N., Obumakhov D.L., Ryzhakov A.N., 2014. Kapel'noe oroshenie yabloni: monografiya [Drip Irrigation of Apple Tree: monograph]. Novocherkassk, Lick Publ., 310 p. (In Russian).
11. Shtanko A.S., Shkura V.N., 2018. [Method of graphoanalytical design of moisture contour under drip irrigation]. Nauchnyy zhurnal Rossiyskogo NII problem melioratsii, no. 1(29), pp. 67-85, available: http:www.rosniipm-sm.ru/archive?n=526&id=531 [accessed 04.03.2021]. (In Russian).
12. Shtanko A.S., Shkura V.N., 2022. [Geometry of local drip soil moisture contours formed in southern chernozems]. Melioratsiya i gidrotekhnika, vol. 12, no. 3, pp. 123-140, available: http:www.rosniipm-sm.ru/article?n=1297 [accessed 04.09.2022], https:doi.org/10.31774/2712-9357-2022-12-3-123-140. (In Russian).
13. Shkura V.N., Shtanko A.S., 2022. [Theoretical substantiation of layout and design solutions for irrigation modules of drip irrigation systems in tree and fruit plantations]. Melioratsiya i gidrotekhnika, vol. 12, no. 4, pp. 119-135, available: http:www.rosniipm-sm.ru/article?n=1316 [accessed 16.11.2022], DOI: 10.31774/2712-9357-2022-12-4-119-135. (In Russian).
14. Lytov M.N., 2020. Osobennosti primeneniya differentsirovannykh rezhimov vodoobespecheniya pri kapel'nom sposobe orosheniya [Features of differentiated water supply modes application with drip irrigation method]. Puti povysheniya effektivnosti oroshaemogo zemledeliya [Ways of Increasing the Efficiency of Irrigated Agriculture], no. 2(78), pp. 54-60. (In Russian).
15. Pronko N.A., Korsak V.V., Lomovtseva A.N., 2015. Kontur uvlazhneniya pri kapel'nom oroshenii na pochvakh Zavolzh'ya [Moisture contour under drip irrigation on soils of the Trans-Volga region]. Nauchnaya zhizn [Scientific Life], no. 1, pp. 74-81. (In Russian).
