Akbarzadeh P., Nejad A.A., Movahed F. & Zolfaghari S., 2018, A new approach to numerical investigation of gfx and power-pipe drain water heat recovery (dwhr) systems in buildings. Heat Transfer Research 49(14): 1339-1352. doi:10.1615/HeatTransRes.2018016060

DBN V.2.6-31, 2016, Thermal insulation of construction DBN V.2.6-31, 2016, Minregion of Ukraine, Kyiv. https://www.minregion.gov.ua/wp-content/uploads/2017/02/DBN-V.2.6-31-2016-Teplova-izolyatsiya-budivel.pdf (in Ukrainian).

Dobrovicova S., Dobroviс R. & Dobroviс J., 2015, The economic impact of floods and their importance in different regions of the world with emphasis on Europe. Procedia Economics and Finance 34: 649-655. (in Russian).

Heat pumps in modern industry and communal infrastructure. Informational - methodical edition, 2016, Publishing House "Pero", Moscow 204 pp. https://mpei.ru/personal/Lists/CadrePapers/Attachments/2000/%D0%92%D0%B5%D1%80%D1%81%D1%82%D0%BA%D0%B0%20%D1%87%D0%B8%D1%81%D1%82%D0%BE%D0%B2%D0%B0%D1%8F.pdf (in Russian).

Kirillini V.A. Sychev V.V. & Sheindlin A. E., 1979, Technical thermodynamics: monograph. Nauka, Moscow, 512 pp. (in Russian).

Kostenko E., Melnyk L., Matko S. & Malovanyy M., 2017, The use of sulphophtalein dyes immobilized on anionite Ab-17X8 to determine the contents of Pb(Ii), Cu(Ii), Hg(Ii) and Zn(Ii) in liquid medium. Chemistry & Chemical Technology 11(1): 117-124. doi:10.23939/chcht11.01.117.

Kordana-Obuch S., 2017, SWOT analysis of wastewater heat recovery systems application. Paper presented at the E3S Web of Conferences, 17. doi:10.1051/e3sconf/20171700042

Kordana-Obuch S., Pochwat K., Słyś D. & Starzec M., 2019, Opportunities and threats of implementing drain water heat recovery units in Рoland. Resources 8(2): 88. doi:10.3390/resources8020088

Madramootoo Ch.A., Johnston W.R. & Willardson L.S., 1997, Management of Agricultural Drainage Water Quality. Food and Agriculture Organization of the United Nations, Rome, 94 pp.

Malyovanyy М., Sakalova, G., Chornomaz N. & Nahurskyy O., 2013, Water sorption purification from ammonium pollution. Chemistry and Chemical Technology 7(3): 355-358. doi:10.23939/chcht07.03.355

Matsevity Yu.M., Chirkin N.B. & Klepanda A.S., 2014, About the use of heat pumps in the world and what hinders their large-scale implementation in Ukraine. Energy saving. Energy. Energy audit No. 2(120): 2-16. (in Russian).

Medvedkov K.S. & Shtripling L.O., 2017, Analysis of the flooded area using the example of groundwater in the city of Nazyvaevsk. Bulletin of the Tomsk Polytechnic University. Engineering of Georesources Vol. 328, No. 4: 85–93. (in Russian).

Nifontova L.S., Rudi D.Yu. & Khalitov N.A., 2016, Analysis of the types of heat pumps. Technical Sciences 5(47), Part 3: 145-149. (in Russian).

Sakalova H., Malovanyy M., Vasylinych T. & Kryklyvyi R., 2019, The Research of Ammonium Concentrations in City Stocks and Further Sedimentation of Ion-Exchange Concentrate. Journal of Ecological Engineering 20(1): 158-164. doi: 10.12911/22998993/93944

Sait M.A., Chigbu U.E., Hamiduddin I. & De Vries W.T., 2019, Renewable energy as an underutilised resource in cities: Germany's 'energiewende' and lessons for post-brexit cities in the united kingdom. Resources 8(1): 7. doi:10.3390/resources8010007

Sedin V.L. & Grabovets O.N., 2018, Distribution of distructive underflooding in the territory of Ukraine. Bulletin of Prydniprovska State Academy of Civil Engineering and Architecture 5: 245-246. doi: 10.30838/J.BPSACEA.2312.271118.24.362

Seybold C. & Brunk M., 2017, Wastewater heat utilization. Heat pumps 1: 29-34.

Sirko Z.S., Korenda V.A., Vyshnyakov I.Y., Protasov O.S., Okhrimenko S.M. & Tsiren N.L., 2020, Use of heat pumps for heating and hot water supply of buildings of enterprises on the example of HELIOTERM installations. Scientific reports of NULES of Ukraine No. 5 (87). (in Ukrainian).

Tulaydan Y., Malovanyy M., Kochubei V. & Sakalova H., 2017, Treatment of high-strength wastewater from ammonium and phosphate ions with the obtaining of struvite. Chemistry & Chemical Technology 11(4): 463-468. doi: 10.23939/chcht11.04.463

Tymchuk I., Malovanyy M., Shkvirko O. & Yatsukh K., 2021, Sewage sludge as a component to create a substrate for biological reclamation. Ecological Engineering and Environmental Technology 22(4): 101-110. doi:10.12912/27197050/137863

Tymchuk I., Shkvirko O., Sakalova H., Malovanyy M., Dabizhuk T., Shevchuk O., Matviichuk O. & Vasylinych T., 2020, Wastewater a source of nutrients for crops growth and development. Journal of Ecological Engineering 21(5): 88-96. doi:10.12911/22998993/122188

Vranayova Z., Kaposztasova D. & Poorova Z., 2018, Water management of “Smart” buildings and cities. Czasopismo inżynierii lądowej, środowiska i architektury [Journal of Civil Engineering, Environment and Architecture, JCEEA], Vol. XXXV, No. 65 (1/18), Styczeń-marzec, p. 45-52.

Zakharov A.V., Zabalueva T.R. & Saud Ya.M., 2021, An economical way to ensure thermal comfort in the premises of cottages built in a subtropical climate zone, as exemplified by the city of Kasab (Syria) . "Innovation and investment" 4: 251-255. (in Russian).

Zhidovich I.S., 2017, The use of heat pumps in heat supply and hot water supply systems for multi-apartment housing on the principles of energy conservation. United Nations Development Program in the Republic of Belarus / Global Environment Facility / Energy Efficiency Department of the State Standard of the Republic of Belarus. Minsk, 30 pp. (in Russian).