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http://dx.doi.org/10.5389/KSAE.2018.60.2.045

Estimation of the Probable Maximum Water Thermal Energy in Korean Dams based on the Water-Energy Nexus Concept  

Jung, Younghun (Department of Construction & Disaster Prevention Engineering, Kyungpook National University)
Publication Information
Journal of The Korean Society of Agricultural Engineers / v.60, no.2, 2018 , pp. 45-53 More about this Journal
Abstract
Demand for essential resources including water, energy and food is rapidly increasing due to climate change, population growth and urbanization. To solve this problem, the concept of water-energy-food nexus has been introduced, and many countries have been trying to acquire the Nexus technology that can maximize the efficiency by analyzing the interconnection between resources. In this regard, this study attempted to estimate the probable maximum water thermal energy in the dam based on the water-energy nexus concept. The estimation of the probable maximum water thermal energy was implemented to monthly water storage of the largest dams in the four major river systems. As a result of analyzing the estimated monthly water thermal energy from 2000 to 2016, Soyang River dam has the largest probable maximum water thermal energy, and Sumjin River dam has the smallest. However, the probable maximum water thermal energy was small in common between March and April, between September and October due to the small temperature difference between the ambient air and the dam water. Also, according to the characteristics of the dam, Daecheong dam and Soyang River dam were beneficial for supplying water thermal energy for heating, and Sumjin River dam and Andong dam were advantageous for supplying water thermal energy for cooling. Our findings can be useful to realize the water-energy-food nexus by increasing the utilization and value of water resources as well as expanding the roles and functions of dams as a starting point to use dam water thermal energy.
Keywords
Dam; nexus; renewable energy; temperature; water thermal energy;
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