This study explores the design and adaptation of a shipping container into aportable irrigation control station for agricultural operations. The project leveragesthe structural durability and mobility of containers to offer a versatile andsustainable solution for irrigation management. By integrating irrigation equipment,control systems, and energy storage, this unit provides an efficient and cost-effectivealternative to traditional irrigation stations. A key advantage of this innovation is itsmobility, allowing the container to be easily relocated between farms using a cranetruck. This feature optimizes its use in seasonal crop rotations and in agriculturaloperations spread across different locations. The system operates autonomously,harnessing photovoltaic solar energy stored in batteries, thereby eliminatingreliance on fossil fuels and significantly reducing the environmental impact ofagricultural irrigation. The system was designed to irrigate 4 hectares, with a pumpflow rate of 26 L/s, a total power load of 3.47 kW, and the capacity to supply a croparea of up to 4 ha under typical operating conditions. Beyond its operationalefficiency, the study emphasizes the environmental benefits of repurposingshipping containers, contributing to waste reduction and mitigating ecologicaldegradation. This approach aligns with sustainability principles in agriculture,promoting the responsible and efficient use of water and energy resources indecentralized irrigation systems
Chica et al. (Tue,) studied this question.