Dmitrii Bogdanov

Hydro, wind and solar power as a base for a 100% renewable energy supply for South and Central America

Power systems for South and Central America based on 100% renewable energy (RE) in the year 2030 were calculated for the first time using an hourly resolved energy model. The region was subdivided into 15 sub-regions. Four different scenarios were considered: three according to different high voltage direct current (HVDC) transmission grid development levels (region, country, area-wide) and one integrated scenario that considers water desalination and industrial gas demand supplied by synthetic natural gas via power-to-gas (PtG). RE is not only able to cover 1813 TWh of estimated electricity demand of the area in 2030 but also able to generate the electricity needed to fulfil 3.9 billion m3 of water desalination and 640 TWhLHV of synthetic natural gas demand. Existing hydro dams can be used as virtual batteries for solar and wind electricity storage, diminishing the role of storage technologies. The results for total levelized cost of electricity (LCOE) are decreased from 62 €/MWh for a highly decentralized to 56 €/MWh for a highly centralized grid scenario (currency value of the year 2015). For the integrated scenario, the levelized cost of gas (LCOG) and the levelized cost of water (LCOW) are 95 €/MWhLHV and 0.91 €/m3, respectively. A reduction of 8% in total cost and 5% in electricity generation was achieved when integrating desalination and power-to-gas into the system.

Electricity system based on 100% renewable energy for India and SAARC

The developing region of SAARC (South Asian Association for Regional Cooperation) is home to a large number of people living below the poverty line. In future, providing affordable, universally accessible, reliable, low to zero carbon electricity in this region will be the main aim. A cost optimal 100% renewable energy system is simulated for SAARC for the year 2030 on an hourly resolved basis. The region was divided into 16 sub-regions and three different scenarios were set up based on the level of high voltage direct current (HVDC) grid connections. The results obtained for a total system levelised cost of electricity (LCOE) showed a decrease from 71.6 €/MWh in a decentralized to 67.2 €/MWh for a centralized grid connected scenario. An additional scenario was simulated to show the benefits of integrating industrial gas production and seawater reverse osmosis desalination demand, and showed the system cost decreased by 5% and total electricity generation decreased by 1%. The results show that a 100% renewable energy system could be a reality in the SAARC region with the cost assumptions used in this research and it may be more cost competitive than nuclear and fossil carbon capture and storage (CCS) alternatives. One of the limitations of this study is the cost of land for installation of renewables which is not included in the LCOE calculations, but regarded as a minor contribution.

North-East Asian Super Grid: Renewable energy mix and economics

Further development of the North-East Asian energy system is at a crossroads due to severe limitations of the current conventional energy based system. For North-East Asia it is proposed that the excellent solar and wind resources of the Gobi desert could enable the transformation towards a 100% renewable energy system. An hourly resolved model describes an energy system for North-East Asia, subdivided into 14 regions interconnected by high voltage direct current (HVDC) transmission grids. Simulations are made for highly centralized, decentralized and countrywide grids scenarios. The results for total system levelized cost of electricity (LCOE) are 0.065 and 0.081€/(kW&h) for the centralized and decentralized approaches for 2030 assumptions. The presented results for 100% renewable resources-based energy systems are lower in LCOE by about 30–40% than recent findings in Europe for conventional alternatives. This research clearly indicates that a 100% renewable resourcesbased energy system is THE real policy option.

Integrated renewable energy based power system for Europe, Eurasia and MENA regions

The existing fossil fuel based power sector has to be transformed towards carbon neutrality in close future to limit global warming to 2°C. The 100% renewable energy (RE) based system will be discussed in the paper. Such a system can be built using already existing energy generation, storage and transmission technologies. A regional integration of Europe, Eurasia and MENA energy systems will facilitate access to lower cost energy sources in neighboring regions, provide additional flexibility in the system and decrease the need in energy storage and increase the system stability because of more distributed generation. Additional demand from synthetic gas generation will additionally decrease the energy storage demand, additional flexibility enables the system to use lower cost energy sources and the primary energy generation cost decreases. Finally, such an integration can provide a sustainable and economically feasible energy system with total LCOE of about 50 €/MWh for the year 2030 cost assumptions. Even for a much higher energy demand in the system the total LCOE will be around 42 €/MWh - lower than coal-CCS or new nuclear options.