Pressurized irrigation systems are economically justifiable for medium- to large-scale farms, while fewer choices are available for smallholders. The current research work provides additional options for small plots, as the only income source for low-income farmers in poorer countries, which produce a considerable portion of the agricultural products in some regions of the world. In this research, two novel layouts of a semipermanent sprinkler irrigation system, namely, clock hand (CH) and corner pivot (CP) lateral designs, were designed for a lighter irrigation system to lower the cost requirement. The new techniques were based on a quadrant/full circle movement pattern of manually pivoting laterals, with no/shorter main pipe requirements, which causes a higher system efficiency. These retrofitted layouts were examined in different farms with areas of 0.20 hm2, 0.81 hm2, 1.62 hm2, and 3.24 hm2 in Guangxi, China. This study introduced, analyzed, and compared the layouts with the widespread traditional split lateral method on technical planning, components, implementation, operation details, size optimization, performance evaluation, and economic advantages. In comparison with the traditional system, CH and CP were found to be more user-friendly and cost-effective but slightly complicated in design with higher required manual work. The results revealed a distribution uniformity (LQDU) of 81.0% to 84.0% via the catch can method, lower capital costs (35.0%-45.0%), and lower annual expenses (6.5%-9.8%) for CP and CH, respectively, compared to the split lateral method. The 0.81 hm2 and 1.62 hm2 farms were found to be the optimum farm sizes for implementation of the new methods for a 25-year project time horizon. The outcomes of this experimental work can encourage small farm owners with limited capital to apply pressurized systems for efficient irrigation and water resource sustainability.
Keywords: sprinkler irrigation layout, semipermanent, smallholder, cost-effectiveness
DOI: 10.25165/j.ijabe.20221502.6363

Citation: Rad S, Gan L, Dai J F, Zhang S P, Huang L L, Pan L Y, et al. Improved sprinkler irrigation layouts for smallholders. Int J Agric & Biol Eng, 2022; 15(2): 30–38.

sprinkler irrigation layout, semipermanent, smallholder, cost-effectiveness

Shiklomanov I A. Appraisal and assessment of world water resources. Water International, 2000; 25(1): 11–32.

Leaman D J. The state of the world’s land and water resources for food and agriculture. Economic Botany, 2012; 66(4): 418–419.

Food and Agriculture Organization of the United Nations (FAO). Aquastat online database. Rome: FAO, 2016. Available: http://www.fao.org/nr/water/aquastat/irrigationmap/index.stm. Accessed on [2019-07-13].

Daoud R, Peter M, George A, Dani F. Efficiency of drip irrigation system for «paulownia» trees in the Aakkar coastal plain of Lebanon. International Journal of Plant, Animal, and Environmental Sciences, 2017; 7(2): 1–7.

Krutz L J, Irby T, Golden B, Pringle L, Falconer L. Improving furrow irrigation efficiency. Mississippi soybean promotion board project 2014; No. 54-2013 annual report.

United Nations, Department of Economic and Social Affairs, Population Division. World population prospects: The 2017 revision, 2017; 46p.

Chavez C, Fuentes C. Design and evaluation of surface irrigation systems applying an analytical formula in the irrigation district 085, La Begoña, Mexico. Agricultural Water Management, 2019; 221: 279–285.

Saidi A, Hammami M, Daghari H, Boughdiri A, Ben Ali H. Irrigation uniformity impacts on water use efficiency and soil salinity: Case study of tomato crop under trickle irrigation system in the north-east of Tunisia. Journal of Hydrogeology Hydrologic Engineering, 2016; 5(1): 1000130. doi: 10.4172/2325-9647.1000130.

Yan H J, Hui X, Li M N, Xu Y C. Development in sprinkler irrigation technology in China. Irrigation and Drainage, 2020; 69(S2): 75–87.

Montero J, Martínez A, Valiente, M, Moreno M A, Tarjuelo J M. Analysis of water application costs with a center pivot system for irrigation of crops in Spain. Irrigation Science, 2013; 31(3): 507–521.

Nasseri A. Energy use and economic analysis for wheat production by conservation tillage along with sprinkler irrigation. Science of the Total Environment, 2019; 648: 450–459.

Ganjegunte G, Clark J. Improved irrigation scheduling for freshwater conservation in the desert southwest U.S. Irrigation Science. Irrigation Science, 2017; 35: 315–326.

Waller P, Yitayew M. Irrigation lateral design, irrigation and drainage engineering. Cham, Switzerland: Springer, 2016; pp.105–121.

Ferrant S, Bustillo V, Burel E, Salmon-Monviola J, Claverie M, Jarosz N. Extracting soil water holding capacity parameters of a distributed agro-hydrological model from high resolution optical satellite observations series. Remote Sensing, 2016; 8(2): 154. doi: 10.3390/rs8020154.

Amin A. Irrigation system design, pressured irrigation systems design. Mashhad, Iran: University of Fredousi, 2006; 368p.

Rad S, Gan L, Chen X, You S, Huang L, Su S, et al. Sustainable water resources using corner pivot lateral, a novel sprinkler irrigation system layout for small scale farms. Applied Sciences, 2018; 8(12): 2601. doi: 10.3390/app8122601.

Louie M J, Selker J S. Sprinkler head maintenance effects on water application uniformity. Journal of Irrigation and Drainage Engineering, 2000; 126: 142–148.

Christensen B A, Locher F A, Swamee P K. Limitations and proper use of the Hazen-Williams equation. Journal of Hydraulic Engineering, 2000; 126(2): 167–170.

Jackson T M, Khan S, Hafeez M. A comparative analysis of water application and energy consumption at the irrigated field level. Agricultural Water Management, 2010; 97: 1477–1485.

Gan L, Rad S, Chen X B, Fang R J, Yan L, Su S H. Clock hand lateral, a new layout for semi-permanent sprinkler irrigation system. Water, 2018; 10(6): 767. doi: 10.3390/w10060767.

Merriam J L, Keller J. Farm irrigation system evaluation: A guide to management. Logan, USA: Utah State University, 1978, 271p.

Hui X, Yan H J, Zhang L, Chen J Y. A simplified method to improve water distribution and application uniformity for sprinkler irrigation on sloping land: adjustment of riser orientation. Water Supply, 2021; 21(6): 2786–2798.

Wang X A. Study of the irrigation water pricing system in China. Hayden Hall, USA: University of Pennsylvania, 2010; 13p.

Zhou N. Key China energy statistics. China Energy Group, Lawrence Berkeley National Laboratory, University of California, USA, 2016; 26p.

Field W P, Collier F W, Wallington H R. Guidelines for planning Irrigation and Drainage investment Project, Technical paper 11. FAO Investment Center, 1996; 68p.

Moyer R C, McGuigan J, Rao R P. Contemporary financial management. Cengage Learning, 2017; 800p.

Khan M Y. Theory & problems in financial management. Boston: McGraw Hill Higher Education, 1993, 203p.

Li J, Rao M. Field evaluation of crop yield as affected by non-uniformity of sprinkler-applied water and fertilizers. Agricultural Water Management, 2003; 59: 1–13.

Li J, Li B, Rao M. Spatial and temporal distributions of nitrogen and crop yield as affected by non-uniformity of sprinkler irrigation. Agricultural Water Management, 2005; 76: 160–180.

Qin X, Zhang F, Liu C, Yu H, Cao B, Tian S, et al. Wheat yield improvements in China: Past trends and future directions. Field Crops Research, 2015; 177: 117–124.