To study the influence of ripple cross angles on the resistance of wet curtains, wet curtains with different ripple cross angles (45°/45°, 45°/15°) were tested on agricultural ventilation equipment performance testing benches, and the static pressure drop under different wind speeds (1-3 m/s) was determined. Four turbulence models (κ-ε, RNG κ-ε, κ-ω, SST κ-ω) were adopted for numerical simulations of the two types of wet curtain, and the simulations’ results were compared with those of experiments. The average errors found are 41.1%, 48.7%, 27.1%, and 27.8%, respectively, and the κ-ω model is found to be the most suitable one for the calculation of wet curtain resistance among the four turbulence models. By using the κ-ω turbulence model, the static pressure drop performances of wet curtains with ripple cross angles 45°/35° and 45°/25° were calculated. Resistance increases with wind speed and ripple cross angles, and a large ripple cross angle has a higher resistance growth rate with increasing wind speed.
Keywords: wet curtain, ripple cross angle, resistance, turbulence model, ventilation, cooling and humidifying system
DOI: 10.25165/j.ijabe.20191204.3446

Citation: Ding T, Fang L M, Shi Z X, Li B M, ZhaoY. Effects of ripple cross angles and turbulence models on wet curtain resistance. Int J Agric & Biol Eng, 2019; 12(4): 43–46.

wet curtain, ripple cross angle, resistance, turbulence model, ventilation, cooling and humidifying system

Zhang M, Wang Z. Application and principle of wet-curtain cooling system in greenhouse. Journal of agricultural mechanization research, 2008; 4: 46–51. (in Chinese)

Sethi V P, Sharma S K. Survey of cooling technologies for worldwide agricultural greenhouse applications. Solar Energy, 2007; 81: 1447–1459.

Dagtekin M, Karaka C, Yildiz Y. Performance characteristics of a pad evaporative cooling system in a broiler house in a Mediterranean climate. Biosystems Engineering, 2009; 103: 100–104.

Macmanus C N, Seth I M. A techno-economic assessment for viability of some waste as cooling pads in evaporative cooling system. Intl J Agric & Biol Eng, 2015; 8(2): 151–158.

Zhou C. Experimental study for optimal construction of honeycomb paper pad. Transactions of the CSAE, 1988; 2: 84–86. (in Chinese)

Wang L, Ding X. Mechanical performance and test method for paper wet-pad. Transactions of the CSAE, 2011; 27(2): 267–271. (in Chinese)

Zhang S, Song W, Teng G. Cooling effect of different installation height of wet-curtain fan-cooling system. Transactions of the CSAM, 2006; 3: 91–94. (in Chinese)

Zhang L, Huang X, Li X. Cooling performance of evaporative cooling pad-fan unit in greenhouse in Shaanxi. Journal of Xi'an Polytechnic University, 2014; 6(28): 333–328. (in Chinese)

Lu Z, Wu Z, Wang M. Effects of pad and fan cooling system on necessary ventilation rate of henhouse. Chinese Journal of Animal Science, 2008; 44(23): 50–54. (in Chinese)

Cheng Q, Liu J, Jin W. Effects of cooling fan-duct on cooling performance in open-sided beef barn in southern China. Transactions of the CSAE, 2014; 4(30): 126–135. (in Chinese)

Egbal M A, Osama A, Mohammed A, MohdRodzi I. Performance evaluation of three different types of local evaporative cooling pads in greenhouses in Sudan. Saudi Journal of Biological Sciences, 2011; 18: 45–51.

Abdollah M, Hamid R S, Mohammad L, Seyedmehdi S, Hamid B. Investigating the performance of cellulosic evaporative cooling pads. Energy Conversion and Management, 2011; 52: 2598–2603.

Chung-Min L, Kun-Hung C. Wind tunnel modeling the system performance of alternative evaporative cooling pads in Taiwan region. Building and Environment, 2002; 37: 177–187.

Dagtekin M, Karaka C, Yildiz Y. Performance characteristics of a pad evaporative cooling system in a broiler house in a Mediterranean climate. Biosystems Engineering, 2009; 103: 100–104.

Hao X, Zhu C, Lin Y. Optimizing the pad thickness of evaporative air-cooled chiller for maximum energy saving. Energy and Buildings, 2013; 61: 146–152.

Xu J, Li Y, Wang R, Liu W, Zhou P. Experimental performance of evaporative cooling pad systems in greenhouses in humid subtropical climates. Applied Energy, 2015; 138: 291–301.

Li R, Poul P, Thomas L J, Svend M, Zhang G. Dynamic performance of an evaporative cooling pad investigated in a wind tunnel for application in hot and arid climate. Biosystems Engineering, 2017; 156: 173–182.

Jorge F, Juan I, Montero E, Baeza J. Mechanical and natural ventilation systems in a greenhouse designed using computational fluid dynamics. Intl J Agric & Biol Eng, 2014; 7(1): 1–16.

Su W, Zhang T. Analysis of evaporative cooling mechanism of evaporative pad. Refrigeration and air conditioning, 2005; 3: 84–86.

Xu F, Cai Y, Chen J. Temperature/flow field simulation and parameter optimal design for greenhouses with fan-pad evaporative cooling system. Transactions of the CSAE, 2016; 31(9): 201–208.

Franco A, Valera D L, Pena A, Perez A M. Aerodynamic analysis and CFD simulation of several cellulose evaporative cooling pads used in Mediterranean greenhouses. Computers and Electronics in Agriculture, 2011; 76: 218–230.