Analysis of test results of a household absorption refrigerating appliance on an electric and gas source of thermal energy
DOI:
https://doi.org/10.15587/2706-5448.2021.237173Keywords:
refrigeration equipment, absorption refrigeration unit, environmentally friendly refrigerants, heat recoveryAbstract
One of the biggest challenges for refrigeration systems is their conversion to environmentally friendly refrigerants. This attracts the attention of developers of household refrigeration equipment to absorption refrigeration devices (ARD), which include an absorption refrigeration unit (ARU). ARD working fluid consists of natural components - ammonia water solution with the addition of an inert gas (hydrogen). Therefore, the use of ARU can be considered as one of the options for transferring to environmentally friendly refrigerants. In recent years, in connection with the rapidly developing gasification of the population of Europe, an alternative has arisen - the operation of household ARD on natural gas. Natural gas can become an alternative to electrical energy in stationary operating conditions of household refrigeration appliances. Thus, the object of the study was a single-chamber household refrigerator with a low-temperature compartment "Kiev-410" (Ukraine).
In this paper, the study is aimed at comparing the thermal modes of operation and the costs of operating a household ARD on electric energy and natural gas. To solve this, it was necessary to determine the temperatures at the characteristic points of the refrigeration apparatus and in the chamber, as well as the energy consumption of the absorption-type apparatus in accordance with regulatory documents, at various values of the thermal load on the thermosyphon and various ambient temperatures.
The studies were carried out at elevated outdoor temperatures: 28–33 ° С. The range of thermal loads on the ARU thermosyphon electric heater was 50–130 W. The range of numerical values of natural gas consumption in the burner was (2.8–8.8) • 10-6 m3/s. In the process of conducting experimental studies of household ARD, results were obtained showing the economic prospects of working in stationary conditions on natural gas.
At the same time, ARD of increased useful volume (200 dm3 and above) has the greatest prospects. The daily operating costs in them are 0.078...0.084 USD, which is 23...27 % lower than the case of using electricity. When the ARU thermosyphon is built into the heating and hot water supply system, it becomes possible to use the temperature potential of the waste products of combustion and completely eliminate operating costs.
References
- Srikhirin, P., Aphornratana, S. (2002). Investigation of a diffusion absorption refrigerator. Applied Thermal Engineering, 22 (11), 1181–1193. doi: http://doi.org/10.1016/s1359-4311(02)00049-2
- Natural Refrigerants. Available at: https://www.linde-gas.com/en/products_and_supply/refrigerants/natural_refrigerants/index.html
- Gutiérrez, F. (1988). Behavior of a household absorption-diffusion refrigerator adapted to autonomous solar operation. Solar Energy, 40 (1), 17–23. doi: http://doi.org/10.1016/0038-092x(88)90067-9
- Dincer, I., Ratlamwala, T. A. H. (2016). Developments in Absorption Refrigeration Systems. Green Energy and Technology, 241–257. doi: http://doi.org/10.1007/978-3-319-33658-9_8
- Titlov, A. S. (2007). Sovremenniy uroven razrabotok i proizvodstva bytovykh absorbtsionnykh kholodilnykh priborov. Kholodilniy bіznes, 8, 12–17.
- Starace, G., De Pascalis, L. (2013). An enhanced model for the design of Diffusion Absorption Refrigerators. International Journal of Refrigeration, 36 (5), 1495–1503. doi: http://doi.org/10.1016/j.ijrefrig.2013.02.016
- Yildiz, A. (2016). Thermoeconomic analysis of diffusion absorption refrigeration systems. Applied Thermal Engineering, 99, 23–31. doi: http://doi.org/10.1016/j.applthermaleng.2016.01.041
- Moroziuk, L. I. (2014). Development andimprovement of the heat using refrigerating machines. Refrigeration Engineering and Technology, 50 (5). doi: http://doi.org/10.15673/0453-8307.5/2014.28695
- Ersöz, M. A. (2015). Investigation the effects of different heat inputs supplied to the generator on the energy performance in diffusion absorption refrigeration systems. International Journal of Refrigeration, 54, 10–21. doi: http://doi.org/10.1016/j.ijrefrig.2015.02.013
- Khomenko, N. F., Olifer, G. M., Titlov, A. S. (1997). Pat. No. 19328 UA. Absorbtsionniy kholodilnik. MPK: F25 B15/10. No. 95321331, declareted: 03.04.91; published: 25.12.97, Bul. No. 6.
- DSTU 2295-93 (HOST 16317-95 ISO 5155-83, ISO 7371-85, IEC 335-2-24-84). Prylady kholodylni elektrychni pobutovi. Zahalni tekhnichni umovy. Vzamen HOST 16317-87; Vved. 20.07.95 (1996). Kyiv: Derzhstandart Ukrainy, 35.
- DSTU 3023-95 (HOST 30204-95, ISO 5155-83, ISO 7371-85, ISO 8187-91). Prylady kholodylni pobutovi. Ekspluatatsiini kharakterystyky ta metody vyprobuvan. Vvedeno vpershe 20.07.95 (1996). Kyiv: Derzhstandart Ukrainy, 22.
- Sözen, A., Menlik, T., Özbaş, E. (2012). The effect of ejector on the performance of diffusion absorption refrigeration systems: An experimental study. Applied Thermal Engineering, 33-34, 44–53. doi: http://doi.org/10.1016/j.applthermaleng.2011.09.009
- Fernández-Seara, J., Vázquez, M. (2001). Study and control of the optimal generation temperature in NH3–H2O absorption refrigeration systems. Applied Thermal Engineering, 21 (3), 343–357. doi: http://doi.org/10.1016/s1359-4311(00)00047-8
- NAFTOHAZ hrupa. Available at: https://www.naftogaz.com/www/3/nakwebru.nsf/0/05A0E3BBAE4ED6BFC2257AD3004F2656
- Titlova, O. A., Titlov, A. S. (2011). Analiz vliyaniya teplovoy moschnosti, podvodimoy v generatore absorbtsionnogo kholodilnogo agregata, na rezhimy raboty i energeticheskuyu effektivnost absorbtsionnogo kholodilnogo pribora. Naukovі pratsі ONAKHT, 1 (39), 148–154.
- Ocheretyaniy, Yu. A. (2007). Rezultaty ispytaniy transportnogo absorbtsionnogo kholodilnika s gorelochnym ustroystvom. Kholodilna tekhnіka і tekhnologіya, 2, 34–37.
- Ocheretyaniy, Yu. A., Titlov, A. S., Zakharov, N. D. (2007). Sravnitelniy analiz energopotrebleniya bytovykh absorbtsionnykh kholodilnikov razlichnogo naznacheniya. Kholodilna tekhnіka і tekhnologіya, 1, 29–32.
- Babakin, B. S., Vygodin, V. A. (2005). Bytovye kholodilniki i morozilniki. Ryazan: Uzoreche, 860.
- Temperatura goreniya prirodnogo gaza v kotle. Available at: https://teplogidromash.ru/stati/temperatura-goreniya-prirodnogo-gaza-v-kotle.html
- Temperatura goreniya gaza v gazovoy plite. Available at: https://stroy-podskazka.ru/plity-kuhnya/gazovye-plity/temperatura-goreniya/
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2021 Daniyorbek Adambayev, Alexander Titlov
This work is licensed under a Creative Commons Attribution 4.0 International License.
The consolidation and conditions for the transfer of copyright (identification of authorship) is carried out in the License Agreement. In particular, the authors reserve the right to the authorship of their manuscript and transfer the first publication of this work to the journal under the terms of the Creative Commons CC BY license. At the same time, they have the right to conclude on their own additional agreements concerning the non-exclusive distribution of the work in the form in which it was published by this journal, but provided that the link to the first publication of the article in this journal is preserved.