Ben Amar, “Design Analysis of DC-DC Converters Connected to a Photovoltaic Generator and Controlled by MPPT for Optimal Energy Transfer throughout a Clear Day,” J. Lopez-Santos, “Contribution to the DC-AC conversion in photovoltaic systems: Module oriented converters,” Citeseer, 2015. Hahm, “Implementation and control of grid connected AC-DC-AC power converter for variable speed wind energy conversion system,” in Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC, 2003, vol. Boeke, “Energy efficient low-voltage DC-grids for commercial buildings,” 2015, doi: 10.1109/ICDCM.2015.7152030. Taufik, “The DC House project: An alternate solution for rural electrification,” Proc. Asian Development association, Handbook on Battery Energy Storage System, no.Parra et al., “An interdisciplinary review of energy storage for communities: Challenges and perspectives,” Renew. González-Huerta, “Analysis of Stand-Alone Photovoltaic-Marine Current Hybrid System and the Influence on Daily and Seasonal Energy Storage,” Energies, vol. Drobinski, “Predictable and unpredictable climate variability impacts on optimal renewable energy mixes: The example of Spain,” Energies, vol. Rahman, “Grid-independent pv-wind-diesel generator hybrid renewable energy system for a medium population: A case study,” J. Zsiborács et al., “Intermittent renewable energy sources: The role of energy storage in the european power system of 2040,” Electron., vol. Zulfatman, “Optimization of Maximum Power Point Tracking (MPPT) Using P&O-Fuzzy and IC-Fuzzy Algorithms on Photovoltaic,” Kinet. Ashari, “Penetration of Photovoltaic-Synchronous Diesel Generator Systems without Storage for Isolated Area,” 2019, doi: 10.1109/ICOMITEE.2019.8921203. Ashari, “Emission abatement cost analysis of hybrid marine current/photovoltaic/diesel system operation,” Proc. Simulations also show that the battery utilization meets its current and capacity, meaning that an optimum size and filling the load profile can be smoothly conducted. Simulations demonstrate that the battery size, solar PV, and turbine radius matches to meet the loads. The distribution network employs 320 V DC connecting from the power plan to the community residents. All loads, mainly for lightings and electronic equipment work in 24 V DC through converters. The loads divide into 6 categories, including household 1, household 2, villagse office, school, mosque, and public health center with the peak demand as 112 kW and 856 kWh perday. Data at a typical time, shows that the marine current peak power occurs every 6 hours perday, whereas the PV is at noon. Hourly data of marine current speed from Cipalulu Strait in Maluku, Indonesia is provided. Thus, the length of the turbine diameter is varied to meet the optimum system size. A centralized battery storage is sized according to the unfilled load demand by the marine current and the solar PV. To anticipate the intermittent, a load-based battery discharge method is proposed. This paper presents the design of DC micro grid with a load-based battery discharge method for remote island electrification utilising marine currents and solar photovoltaic.
0 Comments
Leave a Reply.AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |