CONSTRUCTION ANALYSIS OF SOLAR PANEL FOUNDATION ON THE SURFACE OF DAM WATER BODY WITH DAM SLOPE
(Case Study: Jatibarang Dam Solar Power Plant - Semarang)
Main Article Content
Indonesia's potential solar panel renewable energy capacity is 207.8 GW, currently only 0.135 GW has been realized or 0.02% has only been achieved. The development is still very broad and far ahead. The best place for a PLTS (Solar Power Plant) location is in the dam area. Why? The dam has a very large area and is owned by the government. This paper investigates the comparison of the cost and time of implementing PLTS foundation construction at the location of the Dam Slope (Landed) and on the Surface of the Dam Water Body (Floating). The research was conducted based on a case study of the application of PLTS in the Jatibarang Dam. Where in 2017 the construction of PLTS has been realized at the location of the Dam Slope. The PLTS Floating model was developed with a design simulation based on real data at the same dam location. The cost and time indicators for both Landed and Floating foundation models are then calculated and compared. From the analysis results, in terms of costs, the application of the PLTS Floating foundation is 41% higher than the foundation on the slopes. But in time 31% faster than the Slope foundation. By knowing the cost and time comparison between the two PLTS laying models, the aim is to design a PLTS development strategy for the Dam area based on the most optimal considerations.
Delgado, C. M., Albaladejo, L. R., Fischer, S., Larsen, E., & Kauppila, A. (2019). Floating Solar Panel Park. Final Project Report. Floating Ideas Team.
ERM for Asian Development Bank (ADB) and Da Nhim - Ham Thuan - Da Mi Hydro Power Joint Stock Company. (2018). Proposed Loan and Administration of Loans Da Nhim - Ham Thuan - Da Mi Hydro Power Joint Stock Company Floating Solar Energy Project (Viet Nam).
Farfan, J., & Breyer, C. (2018). Combining Floating Solar Photovoltaic Power Plants and Hydropower Reservoirs: A Virtual Battery of Great Global Potential. 12th International Renewable Energy Storage Conference, IRES 2018.
Kim, S. H., Baek, S. C., Choi, K. B., & Park, S. J. (2020). Design and Installation of 500-kW Floating, Photovoltaic Structures Using High-Durability Steel. Energies, 13, 4996. doi:10.3390/en13194996.
Kim, S. H., Yoon, S. J., & Choi, W. (2017). Design and Construction of 1MW Class Floating PV Generation Structural System Using FRP Members. Energies, 10, 1142. doi:10.3390/en10081142.
Majid, Z. A. A., Ruslan, M. H., Sopian, K., Othman, M. Y., & Azmi, M. S. M. (2014). Study On Performance Of 80 Watt Floating Photovoltaic Panel. Journal of Mechanical Engineering and Sciences (JMES), 7, 1150-1156.
Sasmanto, A. A., Dewi, T., & Rusdianasari. (2020). Eligibility Study on Floating Solar Panel Installation over Brackish Water in Sungsang, South Sumatra. EMITTER International Journal of Engineering Technology.
Sharma, P., Muni, B., & Sen, D. (2015). Design Parameters Of 10kw Floating Solar Power Plant. International Advanced Research Journal in Science, Engineering and Technology (IARJSET), 2(Special Issue 1), May 2015.
Taye, B. Z., Nebey, A. H., & Workineh, T. G. (2020). Design of floating solar PV system for typical household on Debre Mariam Island. Cogent Engineering, 7, 1829275.
World Bank. (2019). Energy Sector Management Assistance Program; Solar Energy Research Institute of Singapore. Where Sun Meets Water: Floating Solar Handbook for Practitioners. World Bank, Washington, DC. © World Bank.