Вестник Пермского университета. Геология

Эксплуатация теплонасосных установок, работающих по принципу «грунт-вода», имеет ряд преимуществ над традиционными источниками тепловой энергии. Однако наряду с преимуществами имеются и недостатки: выхолаживание массива и, как следствие, снижение коэффициента полезного действия установки, зависимость тепловой мощности от площади теплообменника. Для решения этой проблемы предлагается выход в виде работы теплонасосной установки в реверсивном режиме в теплое время года (нагрев массива грунта), при этом грунтовый массив будет являться теплоаккумулятором. Проведены исследования на лабораторной установке, показана принципиальная возможность такого подхода.

Butuzov V.A. 2022. Obzor rossiyskikh geothermalnykh teplonasosnykh tehnologiy [Review of Russian geothermal heat pump technologies]. Energetik. 2:40-44. (in Russian)

Vasiliev G.P. 2006. Geotermalnye teplonasosnye sistemy teplokhladosnabzheniya zdaniy i sooruzheniy [Geothermal heat pump systems of heat and cooling supply for buildings and structures]. Science and technology of transport. 1:78-87. (in Russian)

Vasiliev G.P. 2009. Primenenie GTST v Rossii [The use of GTST in Russia]. Energy: economics, technology, ecology. 7:22-29. (in Russian)

Vasiliev G.P. 2006. Teplokhladosnabzhenie zdaniy i sooruzheniy s ispolzovaniem nizkopotentsialnoy teplovoy energii poverkhnostnykh sloev Zemli [Heat and cooling supply of buildings and structures using low-potential thermal energy of the surface layers of the Earth]. Moskva, Gran, p. 173. (in Russian)

Vozobnovlyaemye i vtorichnye istochniki energii inzhenernykh sistem pri ekspluatatsii i rekonstruktsii zdaniy i sooruzheniy [Renewable and secondary energy sources of engineering systems in the operation and reconstruction of buildings and structures]. Eds. T.N. Ilyina, N.Y. Savvin, O.A. Averkova, K.I. Logachev. Bulletin of Eurasian Science. 2023. vol. 13,2, No. 4. (in Russian)

GOST 34346.2-2017 Teplovye nasosy s vodoy v kachestve istochnika tepla. Ispytanija i otsenka rabochikh kharakteristik. Chast 2. [GOST 34346.22017. Heat pumps with water as a heat source. Testing and evaluation of performance characteristics. Part 2]. (in Russian)

Mezentseva N.N., Mezentsev I.V., Elistratov D.S. et al. 2015. Ispolzovanie tepla sukhogo grunta pri rabote teplonasosnoy ustanovki v usloviyakh Sibiri [The use the dry soil heat during the operation of a heat pump installation in Siberia]. Modern science: research, ideas, results, technologies. 1(16):90-94. (in Russian)

Kirillov V.V., Seydakmatova Z.D., Zaychenko K.V. 2018. Malopotentsialnye istochniki tepla i ikh ispolzovanie [Low-potential heat sources and their use]. Bulletin of the Kyrgyz-Russian Slavic University. 18(4):22-25. (in Russian)

Prosvirina I.S. 2022. Issledovanie metodov akkumulirovaniya tepla grunta s pomoshchyu solnechnoy energii [Investigation of methods of soil heat accumulation using solar energy]. In: Prospects for the development of the construction complex. Materials of the XVI Scientific and Practical International Conference, Astrakhan, October 27-28, 2022. Astrakhan State University of Architecture and Civil Engineering, pp. 175-179. (in Russian)

Fedoseeva E.A., Krupenya D.V., Bulatov V.R. 2020. Analiz primeneniya teplovykh nasosov v mire [Analysis of the use of heat pumps in the world]. Electrotechnical and information complexes and systems. 16(2):54-58. doi: 10.17122/1999-54582020-16-2-54-58. (in Russian)

Svod pravil SP 25.13330.2012. Osnovaniya i fundamety na vechnomerzlykh gruntakh. Aktualizirovannaya redaktsiya SNiP 2.02.04-88 [Code of rules of SP 25.13330.2012 Foundations and foundations on permafrost soils. Updated version of SNiP 2.02.04-88]. (in Russian)

Kantor A., Owen D., Harter D., Nylen G., Kiparsky M. 2018. Investigation of the interaction of groundwater and surface waters in accordance with the Law on Sustainable Groundwater Management, Center for Law, Energy and the Environment, University of California Berkeley Law School, Berkeley, California.

Psomas A., Bariamis G., Rouillard J., Stein W., Roy S. 2021. Investigation of the impact of loads on groundwater in Europe: analysis of groundwater related aquatic ecosystems (GWAAEs) and terrestrial ecosystems dependent on groundwater (GWDTEs). John W. Lund, Aniko N. Toth. 2020. Direct use of geothermal energy: A Global Overview for 2020. Proceedings of the 2020 World Geothermal Congress. Reykjavik, Iceland. p. 39.