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Анотація
Джерелом зниження ефективності теплообмінного апарату в процесі експлуатації є відклади. Проблеми відкладів на поверхнях теплообмінних апаратів віднесено до “невирішених”. В роботі наведено спосіб експериментального дослідження повітряного конденсатора з реальними відкладами та модельованими решітками-імітаторами на зовнішній поверхні Доведено, що головним критерієм для аналізу відкладів є його структура.
Ключові слова:
Повітряний конденсатор, Експериментальний стенд, Теплообмінна поверхня, Відклади
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Як цитувати
Морозюк, Л. І., Соколовська, В. В., Гайдук, С. В., & Мошкатюк, А. В. (2017). Метод експериментального дослідження повітряних конденсаторів малих холодильних машин і теплових насосів. Refrigeration Engineering and Technology, 53(3). https://doi.org/10.15673/ret.v53i3.674
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ХОЛОДИЛЬНА ТЕХНІКА
Посилання
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8. Ian H. Bell, Eckhard A. Groll. (2010). Experimental comparison of the impact of air-side particulate fouling on the thermo-hydraulic performance of microchannel and plate-fin heat exchangers. International Refrigeration and Air Conditioning conference, Purdue, USA.
9. Bell, I., Groll, E., König, H. (2009). Experimental analysis of the effects of particulate fouling on heat exchanger heat transfer and air side pressure drop for a hybrid dry cooler. Heat Transfer Engineering In Press.
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11. Danilova G.N. (1986). Teploobmennye apparaty kho-lodilnykh ustanovok. L.: Mashinostroenie, 303.
12. Morosuk T. (2003). Porous media theory as basis for model of fouling layers formation in heat exchangers. Con-denser and evaporator of refrigeration machines and heat pumps. In: Emerging Technologies and Techniques in Po-rous Media, Eds. Ingham, D.B. et al., Kluwer Chapter 32, Academic Published, 491–507.
2. Standards of the tubular exchanger manufacturers
Association (2007). 9th edn., TEMA Inc, New York.
3. Omer Sarfraz, Christian Bach. (2016). A Literature Review On Heat Exchanger Air Side Fouling In Heating, Ventilation And Airconditioning (HVAC) Applications. International refrigeration and air conditioning conference, Purdue, USA.
4. Breuker, M. S., Braun, J. E. (1998). Common faults and their impacts for rooftop air conditioners. HVAC and R Research, 4 (3), 303–317.
5. Lankinen, R., Suihkonen, J., Sarkomaa, P. (2003). The effect of air side fouling on thermal-hydraulic characteristics of a compact heat exchanger. International Journal of Energy Research, 27 (4), 349–361.
6. L. Yang, J.E. Braun,E.A. Groll, (2004). The role of filtra-tion in maintaining clean heat exchanger coils. Final Report ARTI-21CR/611-40050-01, Air-Conditioning and Refrig-eration Technology Institute (ARTI).
7. Ali, A. H., Ismail, I. M. (2008). Evaporator air-side fouling: effect on performance of room air conditioners and impact on indoor air quality. HVAC&R Research, 14(2), 209-219.
8. Ian H. Bell, Eckhard A. Groll. (2010). Experimental comparison of the impact of air-side particulate fouling on the thermo-hydraulic performance of microchannel and plate-fin heat exchangers. International Refrigeration and Air Conditioning conference, Purdue, USA.
9. Bell, I., Groll, E., König, H. (2009). Experimental analysis of the effects of particulate fouling on heat exchanger heat transfer and air side pressure drop for a hybrid dry cooler. Heat Transfer Engineering In Press.
10. Koshkin, N.N. (1976). Teplovye konstruktivnye raschety kholodilnykh mashin. L.: Mashinostroenie, 463.
11. Danilova G.N. (1986). Teploobmennye apparaty kho-lodilnykh ustanovok. L.: Mashinostroenie, 303.
12. Morosuk T. (2003). Porous media theory as basis for model of fouling layers formation in heat exchangers. Con-denser and evaporator of refrigeration machines and heat pumps. In: Emerging Technologies and Techniques in Po-rous Media, Eds. Ingham, D.B. et al., Kluwer Chapter 32, Academic Published, 491–507.