Hydraulic performance assessment on dynamic fluidic and complete fluidic sprinklers under indoor and outdoor conditions

Published: 8 May 2024
Abstract Views: 150
PDF: 134
Publisher's note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.

Authors

Since complete fluidic sprinklers (CFS) cannot function well in low-pressure environments, dynamic fluidic sprinklers (DFS) were developed to address this issue. In 2021, research in the field and laboratory were conducted to examine how well DFS and CFS performed hydraulically in both indoor and outdoor conditions. In this investigation, a Thiess Clima laser precipitation monitor was used to evaluate the droplet size and velocity distribution of two different types of sprinklers indoors. From the findings, DFS velocities ranged from 0.1 to 4 m/s whereas CFS ranged from 0.1 to 5.3 m/s. The maximum frequency value was obtained at velocities of 1 m/s for each combination. The DFS had a slightly greater discharge coefficient and spray pattern than the CFS. The DFS's maximum spray range was 12.2 m, while the CFS's maximum spray range was 10.8 m, with standard deviations of 1.07 and 1.66, respectively. Under high wind speed conditions, the maximum combined Coefficient of Uniformity (CU) of DFS and CFS were 81.1% and 78%, respectively. For a given pressure and sprinkler spacing, DFS delivered higher CU values than CFS, especially while running at low pressure, demonstrating that DFS offered a more favored water distribution pattern at low pressure. At different distances from the sprinkler, the highest application rates for DFS and CFS were 6.7 mm h−1 at 7 m and 6.5 mm h−1 at 7 m, respectively. A comparison of DFS and CFS under hydraulic performance indicated that DFS had a better performance than CFS. The study can serve as a guide for how to conserve water in sprinkler-irrigated fields.

Dimensions

Altmetric

PlumX Metrics

Downloads

Download data is not yet available.

Citations

Chan, D., Wallender, W.W. 1985. Droplet size distribution and water application with a low- pressure sprinkler. T. ASAE 11:801-803.
Chen, X.X., Wang, C., Shi, W.D., Zhang, Y.C. 2020. Numerical simulation of submerged impinging water jet at different impact angles. J. Drain. Irrig. Mach. Eng. 38:658-666.
Coanda, H. 1936. Device for deflecting a stream of elastic fluid projected into an elastic fluid. U.S. Patent No. US2052869A.
Dukes, M.D. 2006. Effect of wind speed and pressure on linear move irrigation system uniformity. Appl. Eng. Agric. 22:541-548.
Dwomoh, F.A., Yuan, S., Li, H. 2013. Field performance characteristics of a fluidic sprinkler. Appl. Eng. Agric. 29:529-536.
Dwomoh, F.A., Yuan, S., Li, H. 2014. Droplet size characterization of the new type complete fluidic sprinkler. IOSR J. Mechan. Civil Eng. 11:70-73.
Edling, R.J. 1985. Kinetic energy, evaporation and wind drift of droplets from low pressure irrigation nozzles. T. ASAE 28:1543-1550.
Hills, D.J., Gun, Y. 1989. Sprinkler volume droplet diameter as a function of pressure. T. ASAE 32:471-476.
Hu, G., Zhu, X.Y., Yuan, S.Q., Zhang, L.G., Li, Y.F. 2019. Comparison of ranges of fluidic sprinkler predicted with BP and RBF neural network models. J. Drain. Irrig. Mach. Eng. 37:263-269.
Keller, R.D., Bliesner, R.D. 1990. Sprinkler irrigation. New York, Van Nostrand Reinhold.
Khalil, M.F., Kassab, S.Z., Elmiligui, A.A. 2002. Applications of drag-reducing polymers in sprinkler irrigation systems: Sprinkler head performance. J. Irrig. Drain. E. 128:147-152.
Khatri-Chhetri, A., Aggarval, Joshi, P.K. 2016. Farmers’ priotization of climate-smart agriculture (CSA) technologies. Agr. Syst. 151:184-191.
King, B.A., Stark, J.C., Wall, R.W. 2006. Comparison of site-specific and conventional uniform irrigation management for potatoes. Appl. Eng. Agric. 22:677- 688.
Lorenzini, G., Wrachien, D. 2005. Performance assessment of sprinkler irrigation systems: a new indicator for spray evaporation losses. Irrig. Drain. 54:295-305.
Li, H., Yuan, S.Q., Liu, J.P., Xiang, Q.J., Zhu, X.Y., Xie, F.Q. 2007. Wall-attachment fluidic sprinkler. China Patent No. 101224444B.
Li, H., Tang, P., Chen, C., Zhang, Z. Y., Xia, H. M. 2021. Research status and development trend of fertilization equipment used infertigation in China. J. Drain. Irrig. Mach. Eng. 39:200-209.
Li, Y.B., Liu, J.P. 2020. Prospects for development of water saving irrigation equipment and technology in China. J. Drain. Irrig. Mach. Eng. 38:738-742.
Li, L.H., Zhang, X.Y., Qiao, X.D., Lui, G.M. 2016. Analysis of the decrease of center pivot sprinkling system uniformity and its impact on maize yield. Int. J. Agric. Biol. Eng. 9:108-119.
Li, Y.F., Liu, J.P., Li, T., Xu, J.E. 2018. Theoretical model and experiment on fluidic sprinkler wet radius under multi-factor. J. Drain. Irrig. Mach. Eng. 36:685-689.
Liang, X.Z., Wu, Y., Chambers, G.R., Schmoldt, L.D., Gao, C., Yan, L.L., Sun, C., Kennedy, A.J. 2016. Determining climate effects on US total agricultural productivity. Proc. Natl. Acad.Sci. USA 114:2285-2292.
Lima, J.L., Torfs, P.J.F., Singhc, V.P. 2002. A mathematical model for evaluating the effect of wind on downward-spraying rainfall simulators. Catena 46:221-241.
Liu, J.P., Li, T., Zhang, Q. 2021. Experimental study on influence of flow channel structure on hydraulic performance of low-pressure rotary sprinkler. J. Drain. Irrig. Mach. Eng. 39:312-317.
Liu, J.P., Liu, W.Z., Bao, Y. Zhang, Q., Liu X.F. 2017. Drop size distribution experiments of gas-liquid two phases fluidic sprinkler. J. Drain. Irrig. Mach. Eng. 35:731-736.
Liu, H.J., Kang, Y.H. 2007. Sprinkler irrigation scheduling of winter wheat in the North China Plain using 20 cm standard pan. Irrig. Sci. 25:149-159.
Liu, H.J., Kang, Y.H., Liu, S.P. 2003. Regulation of field environmental condition by sprinkler irrigation and its effect on water use efficiency of winter wheat. Trans. China Soc. Agric. Eng. 19:46-51.
Liu, J.P. Zhu, X.Y., Yuan, S.Q., Liu, X.F. 2018. Droplet motion model and simulation of a complete fluidic sprinkler. T. ASABE. 61:1297-1306.
Molle, B. 2002. Characterizing droplet distribution of an irrigation sprinkler water application. Pro. 18th Int. Cong. on Irrigation and Drainage, Montréal. pp. 1-19.
Shi, Y.J., Zhu, X.Y., Hu, G., Zhang, A.Y., Li, J.P. 2021. Effect of water distribution on different working conditions for sprinkler irrigation. J. Drain. Irrig. Mach. Eng. 39:318-324.
Solomon, K.H. 1987. Sprinkler irrigation uniformity. Extension Bull. n. 247. ASPAC, Food and Fertilizer Technology Center, Taiwan.
Xu, Z.D., Li, H., Xiang, Q.J., Wang, J.H., Jiang, Y., Liu J. 2022. Effect on combination irrigation of low pressure 20PY2 impact sprinkler with and without aeration. J. Drain. Irrig. Mach. Eng. 40:74-79.
Xu, Z.D., Xiang, Q.J, Waqar, A.Q., Liu, L. 2018. Field combination experiment on impact sprinklers with aerating jet at low working pressure. J. Drain. Irrig. Mach. Eng. 36:840-844.
Zhang, Q., Liu, J.P., Yuan, S.Q., Li, Y. ., Li, H. 2022. Structure design and hydraulic performance test of water and pesticide integrated sprinkler. J. Drain. Irrig. Mach. Eng. 40:102-108.
Zhang, Z.H., Sun, X.D., Xie, J.P., Li, H., Zhang, D.J., Jiang, T.T., Lyu, M.L., Hua, L. 2022. Numerical simulation of water-sand phase flow in regulator channel of micro-sprinkler irrigation system. J. Drain. Irrig. Mach. Eng. 40:211-216.
Zhu, X.Y., Yuan, S.Q., Liu, J.P. 2012. Effect of sprinkler head geometrical parameters on hydraulic Performance of fluidic sprinkler. J. Drain. Irrig. Mach. Eng. 138:1019-1026.
Zhu, X., Yuan, S., Jiang, J., Liu, J., Liu X. 2015. Comparison of fluidic and impact sprinklers based on hydraulic performance. Irrig. Sci. 33:367-374.
Zhu, X.Y., Fordjour, A., Yuan, S.Q., Dwomoh, F., Ye, D.X. 2018. Evaluation of hydraulic performance characteristics of a newly designed dynamic fluidic sprinkler. Water 10:1301.
Zhu, X.Y., Zhang, A.Y., Zhang, L.G., Shi, Y.J., Jiang, N. 2021. Research on atomization performance of low-pressure atomization nozzle. J. Drain. Irrig. Mach. Eng. 39:210-216.

How to Cite

Zhu, X. (2024) “Hydraulic performance assessment on dynamic fluidic and complete fluidic sprinklers under indoor and outdoor conditions”, Journal of Agricultural Engineering, 55(3). doi: 10.4081/jae.2024.1580.

Similar Articles

<< < 5 6 7 8 9 10 11 12 13 14 > >> 

You may also start an advanced similarity search for this article.