Energy-saving system development based on heat pump
Abstract
This article describes the structure and the operation of energy-saving systems based on a heat pump with the use of renewable energy sources. Using the method of an experiment three-factor active planning, the response surfaces and their two-dimensional cross sections were constructed in the isolines of the transition process duration and the amount of the energy carrier heat from the the electric heater power. The developed energy-saving systems support the temperature regime of an agricultural object by using solar energy, low-potential and artificial energy sources throughout the year. The developed system (option one), installed in hard-to-reach places at agricultural facilities, is designed to generate thermal energy, electricity, and provides significant energy savings during energy supply. Due to the speed of the electric regulator with solid filler and electric heater, the efficiency of the heat pump is increased, which maintains the microclimate parameters of the agricultural object.
Downloads
References
Chebotareva, G. S. (2016). Methodical Tools for Assessment of Investment Attractiveness of Energy Generating Company: Dissertation for Candidate of Economics: 08.00.05. G. S.
Chebotareva; the Place of Presentation of the Dissertation: The Ural Federal University after the First President of Russian B. N. Yeltsin. Yekaterinburg, 243.
Dorokhov, A. S. (2010). Automation of measurements during quality control of agricultural machinery spare parts. The collection of scientific reports VIM. Moscow: All-Russian Research Institute of Agricultural Mechanization. 2, 448-457.
Ershova, I. G., Ershov, M.A., & Poruchikov, D.V. (2017). Justification of low-potential energy source transfer regulation in the system based on a heat pump. The Journal "Fundamental Foundations of Mechanics", 2, 32-33.
Jarreau, J., & Poncet, S. (2012). Export sophistication and economic growth: evidence from China. Journal of Development Economics. URL: http://www.scopus.com.
Kireev, V. V. Lazeev, N.A., & Stepanenko, P.P. (2003). The saving of energy resources based on the use of natural cold. Storage and processing of agricultural raw materials. 10, 10-13.
Novikova, G. V., Belova, M. V., Belov, A. A., Ershova, I. G., & Poruchikov, D. V. (2015). The methods of product heat treatment process modification by electromagnetic radiation energy. International Scientific and Technical Conference "Innovations in Agriculture." Moscow: FSECI VIESH. 5 (14), 17-21.
Qazani, M.R.C., Pedrammehr, S. & Nategh, (2018). An Investigation on the Motion Error of Machine Tools’ Hexapod Table, M.J. Int. J. Precis. Eng. Manuf. 19: 463. https://doi.org/10.1007/s12541-018-0056-5.
Sayfudinova, N. Z., Safiullin, M. R., Safiullin, А. R., & Zainullina, M. R. (2016). Modeling of economic system of the development of the Russian Federation system. Journal of Economics and Economic Education Research, 17, 334-346.
Vasilyev, G. P. (2007). Efficiency and the prospect of heat pump use in the urban economy of Moscow. Energy Saving, 8, 63-65.
Wonglimpiyarat, J. (2010). Commercialization strategies of technology: lessons from Silicon Valley. The Journal of Technology Transfer. 35 (2), 225-236.
.gif)
