References
- ASHRAE. 1987. Standard 41.2. Standard Methods for Laboratory Air-flow Measurement. Atlanta: ASHRAE.
- ASHRAE. 2000. Method of Testing Forced Circulation Air Cooling and Air Heating Coils. Atlanta: ASHRAE.
- Ding, G.L. 2007. Recent developments in simulation techniques for vapour-compression refrigeration systems. International Journal of Refrigeration 30(7):1119–33.
- Ding, G.L., H.T. Hu, X.C. Huang, B. Deng, and Y. Gao. 2009. Experimental investigation and correlation of two-phase frictional pressure drop of R410A-oil mixture flow boiling in a 5 mm microfin tube. International Journal of Refrigeration 32(1):150–61.
- Dong, J.Q., J.P. Chen, Z.J. Chen, Y.M. Zhou, and W.F. Zhang. 2007. Heat transfer and pressure drop correlations for the wavy fin and flat tube heat exchangers. Applied Thermal Engineering 27(11):2066–73.
- Halıcı F., I. Taymaz, and M. Gündüz. 2001. The effect of the number of tube rows on heat, mass and momentum transfer in flat-plate finned tube heat exchangers. Energy 26(11):963–72.
- He, Y.L., W.Q. Tao, F.Q. Song, and W. Zhang. 2005. Three-dimensional numerical study of heat transfer characteristics of plain plate fin-and-tube heat exchangers from view point of field synergy principle. International Journal of Heat and Fluid Flow 26(3):459–73.
- Jiang, H., V. Aute, and R. Radermacher. 2006. CoilDesigner: A general-purpose simulation and design tool for air-to-refrigerant heat exchangers. International Journal of Refrigeration 29(4):601–10.
- Korte, C., and A.M. Jacobi. 2001. Condensate retention effects on the performance of plain-fin-and-tube heat exchangers: Retention data and modeling. Journal of Heat Transfer 123(5):926–36.
- Lin, Y.T., Y.M. Hwang, and C.C. Wang. 2002. Performance of the herringbone wavy fin under dehumidifying conditions. International Journal of Heat and Mass Transfer 45(25):5035–44.
- Ma, X.K., G.L. Ding, Y.M. Zhang, and K.J. Wang. 2007. Airside heat transfer and friction characteristics for enhanced fin-and-tube heat exchanger with hydrophilic coating under wet conditions. International Journal of Refrigeration 30(7):1153–67.
- Ma, X.K., G.L. Ding, Y.M. Zhang, and K.J. Wang. 2009. Airside characteristics of heat, mass transfer and pressure drop for heat exchangers of tube-in hydrophilic coating wavy fin under dehumidifying conditions. International Journal of Heat and Mass Transfer 52(19–20):4358–70.
- Mirth, D.R., and S. Ramadhyani. 1993. Prediction of cooling-coils performance under condensing conditions. International Journal of Heat and Fluid Flow 4(4): 391–400.
- Mirth D.R., and S. Ramadhyani. 1994. Correlations for predicting the air-side Nusselt numbers and friction factors in chilled-water cooling coils. Experimental Heat Transfer 7(2):143–62.
- Singh, V., V. Aute, and R. Radermacher. 2008. Numerical approach for modeling air-to-refrigerant fin-and-tube heat exchanger with tube-to-tube heat transfer. International Journal of Refrigeration 31(8):1414–25.
- Sommers, A.D., J. Ying, and K.F. Eid. 2012. Predicting the onset of condensate droplet departure from a vertical surface due to air flow-Applications to topographically-modified, micro-grooved surfaces. Experimental Thermal and Fluid Science 40:38–49.
- Tang, L.H., Z. Min, G.N. Xie, and Q.W. Wang. 2009. Fin pattern effects on air-side heat transfer and friction characteristics of fin-and-tube heat exchangers with large number of large-diameter tube rows. Heat Transfer Engineering 30(3):171–80.
- Tang, L.H., M. Zeng, and Q.W. Wang. 2009. Experimental and numerical investigation on air-side performance of fin-and-tube heat exchangers with various fin patterns. Experimental Thermal and Fluid Science 33(5):818–27.
- Threlkeld, L. 1970. Thermal Environment Engineering. New York: Prentice-Hall.
- Wang, C.C., K.Y. Chi, and C.J. Chang. 2000. Heat transfer and friction characteristics of plain fin-and-tube heat exchangers, part II: Correlation. International Journal of Heat and Mass Transfer 43(15):2693–700.
- Wang, C.C., Y.J. Du, Y.J. Chang, and W.H. Tao. 1999. Airside performance of herringbone fin-and-tube heat exchangers in wet conditions. The Canadian Journal of Chemical Engineering 77(6):1225–30.
- Wang, C.C., W.S. Lee, W.J. Sheu, and Y.J. Chang. 2001. Parametric study of the air-side performance of slit fin-and-tube heat exchangers in wet conditions. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science 215(9):1111–21.
- Wang, C.C., W.S. Lee, W.J. Sheu, and Y.J. Chang. 2002. A comparison of the airside performance of the fin-and-tube heat exchangers in wet conditions with and without hydrophilic coating. Applied Thermal Engineering 22(3):269–78.
- Wang, C.C., Y.T. Lin, and C.J. Lee. 2000a. An airside correlation for plain fin-and-tube heat exchangers in wet conditions. International Journal of Heat and Mass Transfer 43(10):1869–72.
- Wang, C.C., Y.T. Lin, and C.J. Lee. 2000b. Heat and momentum transfer for compact louvered fin-and-tube heat exchangers in wet conditions. International Journal of Heat and Mass Transfer 43(18):3443–52.
- Wu, W., G.L. Ding, Y.X. Zheng, and Y.F. Gao. 2012. Principle of designing fin-and-tube heat exchanger with smaller diameter tubes for air conditioner. Proceedings of the 14th International Refrigeration and Air Conditioning Conference at Purdue, West Lafayette, IN, July 17–21.
- Xie, G., Q. Wang, and B. Sunden. 2009. Parametric study and multiple correlations on air-side heat transfer and friction characteristics of fin-and-tube heat exchangers with large number of large-diameter tube rows. Applied Thermal Engineering 29(1):1–16.
- Zhang, L., C. Dang, and E. Hihara. 2010. Performance analysis of a no-frost hybrid air conditioning system with integrated liquid desiccant dehumidification. International Journal of Refrigeration 33(1):116–24.