Frost on heat exchanger fin surfaces increases the thermal resistance and blocks the air flow passages, which reduce the system energy efficiency. Therefore, investigations of frost formation especially simulations of frosting on the heat exchanger surfaces are essential for designing heat exchangers that operate with frosting. In this paper, the frost growth and densification processes on fin-and-tube heat exchanger surfaces are numerically investigated using a mass transfer model implemented as a user-defined function (UDF) in fluent. The model predicts the frost distributions on the heat exchanger surfaces, the temperature distributions, and the air flow pressure drop. The results show that the frost is thicker and the frost density is higher on the fin surfaces on the windward side near the tubes, while the frost is thinner and the density is lower near the inlet. Very little frost appears in the tube wake region. Frost on the fin-and-tube heat exchanger surfaces restricts the airflow and about doubles the pressure drop after frosting for 50 min. The simulated frost distributions and pressure drops are in good agreement with experimental data, which means that the frosting model can be used to predict frost layer growth on heat exchanger surfaces and the resulting airflow resistance.
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September 2017
Research-Article
Numerical Simulation of Frosting on Fin-and-Tube Heat Exchanger Surfaces
Xiaomin Wu,
Xiaomin Wu
Key Laboratory for Thermal Science and Power
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: wuxiaomin@mail.tsinghua.edu.cn
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: wuxiaomin@mail.tsinghua.edu.cn
Search for other works by this author on:
Qiang Ma,
Qiang Ma
Key Laboratory for Thermal Science and Power
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: maq09@sina.cn
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: maq09@sina.cn
Search for other works by this author on:
Fuqiang Chu
Fuqiang Chu
Key Laboratory for Thermal Science and Power
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: chu_fuqiang@126.com
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: chu_fuqiang@126.com
Search for other works by this author on:
Xiaomin Wu
Key Laboratory for Thermal Science and Power
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: wuxiaomin@mail.tsinghua.edu.cn
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: wuxiaomin@mail.tsinghua.edu.cn
Qiang Ma
Key Laboratory for Thermal Science and Power
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: maq09@sina.cn
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: maq09@sina.cn
Fuqiang Chu
Key Laboratory for Thermal Science and Power
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: chu_fuqiang@126.com
Engineering of Ministry of Education,
Department of Thermal Engineering,
Tsinghua University,
Beijing 100084, China
e-mail: chu_fuqiang@126.com
1Corresponding author.
Contributed by the Heat Transfer Division of ASME for publication in the JOURNAL OF THERMAL SCIENCE AND ENGINEERING APPLICATIONS. Manuscript received May 31, 2016; final manuscript received September 7, 2016; published online April 4, 2017. Assoc. Editor: Ziad Saghir.
J. Thermal Sci. Eng. Appl. Sep 2017, 9(3): 031007 (7 pages)
Published Online: April 4, 2017
Article history
Received:
May 31, 2016
Revised:
September 7, 2016
Citation
Wu, X., Ma, Q., and Chu, F. (April 4, 2017). "Numerical Simulation of Frosting on Fin-and-Tube Heat Exchanger Surfaces." ASME. J. Thermal Sci. Eng. Appl. September 2017; 9(3): 031007. https://doi.org/10.1115/1.4035925
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