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The waste warm waters from power plants, owing to their temperature regime (25–38°C) and the volumes of discharge, allow for their use for heating of open ground areas in agriculture. Underground heating by such water is a new, special heat and irrigation method which enables not only purposeful regulation of temperature conditions of the crop growing environment, but also dissipates heat in the soil, thus cooling the water for its reuse. This makes it possible to reduce the thermal pollution of water sources.
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13--25
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Bibliogr. 17 poz., rys., tab.
Twórcy
autor
- National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
autor
- National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
autor
- Institute of Water Problems and Land Reclamation of the National Academy of Agrarian Sciences of Ukraine; 37 Vasylkivska Str., 03022, Kyiv, Ukraine
autor
- National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
autor
- National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
Bibliografia
- Agrawal K. K., Tejpal Y., Rohit M. (2019) Effect of soil moisture contents on thermal performance of earth-air-pipe heat exchanger for winter heating in arid climate: In situ measurement, Geothermics, 77, 12–23. https://doi.org/10.1016/j.geothermics.2018.08.004 Get rights and content.
- Balghouthia M., Koolia S., Farhata A., Daghariw H. (2005) Experimental investigation of thermal and moisture behaviors of wet and dry soils with buried capillary heating system, Solar Energy, 79 (6), 669–681. https://doi.org/10.1016/j.solener.2005.06.011.
- Dalampakis P., Gelegenis J., Ilias A., Ladas A. (2017) Technical and economic assessment of geothermal soil heating systems in row covered protected crops: A case study from Greece, Applied Energy, 203 (1), 201–218. https://doi.org/10.1016/j.apenergy.2017.06.029 Get rights and content.
- Dudnik A., Kuzmych L., Trush O., Domkiv T., Leshchenko O., Vyshnivskyi V. (2020) Smart Home Technology Network Construction Method and Device Interaction Organization Concept, IEEE Second International Conference on System Analysis & Intelligent Computing (SAIC’2020), DOI: 10.1109/SAIC51296.2020.9239220.
- Issakhov A. (2014) Mathematical modeling of thermal process to aquatic environment with different hydro meteorological conditions, Sci. World J., 632–635.
- Korobiichuk I., Drevetsky V., Kuzmych L., Kovela I. (2020) The method of multy-criteria parametric optimization, Advances in Intelligent Systems and Computing, 1140, 2020. Automation 2020: Towards Industry of the Future, 87–97. doi.org/10.1007/978-3-030-40971-5. – Available at: https://link.springer.com/chapter/10.1007/978-3-030-40971-5_9.
- Korobiichuk I., Kuzmych L., Kvasnikov V. (2019) The system of the assessment of a residual resource of complex technical structures, MECHATRONICS 2019: Recent Advances Towards Industry 4.0, 350–357. https://doi.org/10.1007/978-3-030-29993-4_43.
- Love R. V., Wüest A., Zappa M., Fink G., Bouffard D. (2018) Tributaries affect the thermal response of lakes to climate change, Hydrol. Earth Syst. Sci.,22, (1), 132–141.
- Madden N., Lewis A., Davis M. (2013) Thermal effluent from the power sector: an analysis of once-through cooling system impacts on surface water temperature, Environmental Research Letters, 8, 2–8.
- Prats J., Val R., Dolz J., Armengol J. (2012) Water temperature modeling in the Lower Ebro River (Spain): heat fluxes, equilibrium temperature, and magnitude of alteration caused by reservoirs and thermal effluent, Water Recourses, 48 (5), 230–245.
- Rakovec J., Hočevar A. (1988) Simulation of soil- and air-microclimate modifications using soil heating with warm water, Agricultural and Forest Meteorology,42 (1), 41–52. https://doi.org/10.1016/0168-1923(88)90065-2.
- Rokochynskiy A., Volk P., Frolenkova N., Prykhodko N., Gerasimov I., Pinchuk O. (2019a) Evaluation of climate changes and their accounting for developing the reclamation measures in Western Ukraine, Scientific Review Engineering and Environmental Sciences, 28 Issue 1(83), 3–13. DOI: 10.22630/PNIKS.2019.28.1.1. http://iks_pn.sggw.pl/PN83/A1/zeszyt83art1en.html.
- Rokochinskiy A., Jeznach J., Volk P., Turcheniuk V., Frolenkova N., Koptiuk R. (2019b) Reclamation projects development improvement technology considering optimization of drained lands water regulation based on BIM, Scientific Review Engineering and Environmental Sciences, 28 Issue 3 (85), 432–443. doi: 10.22630/PNIKS.2019.28.3.40. http://iks_pn.sggw.pl/PN85/A11/zeszyt85art11en.html.
- Vasiliev N. N., Remizov Yu.V. (2004) Energobiological complexes as a method of utilization of waste heat of large power facilities and the creation high-intensity waste-free production, Atomic science issues and technology, 1, 57–60.
- Vasiliev A. M. (2011) Development of greenhouse farms subject to the use of potential of power generating enterprises, Science Journal of Russian Scientific Researches of Institute of Land Reclamation Problems, 2, 1–7.
- Vostrikov V. P. (2015) Heat reclamation system for heating the soil with waste warm waters, International Scientific Institute “EDUCATIO”, 6 (13), 131–134.
- Vostrikov V. P., Pinchuk O. L., Gnatyuk V. N. (2014) Soil Water Regime in the Tunnel Shelters at Heating Water Filled Shells-Sleeves and Drip Irrigation, Universal Journal of Food and Nutrition Science – USA, 2 (1), 7–17 (http://www.hrpub.org/ download/20140105/UJFNS2-11101752.pdf).
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Typ dokumentu
Bibliografia
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