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Modelling the Future of the Baltic Energy Systems: A Green Scenario

L. Petrichenko
L. Petrichenko
, 
R. Petrichenko
R. Petrichenko
, 
A. Sauhats
A. Sauhats
, 
K. Baltputnis
K. Baltputnis
 oraz 
Z. Broka
Z. Broka
   | 24 cze 2021
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Data publikacji: 24 cze 2021
Zakres stron: 47 - 65
DOI: https://doi.org/10.2478/lpts-2021-0016
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© 2021 L. Petrichenko et al., published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

1. AST. (n.d.). TSO Annual Statement. Available at http://www.ast.lv/lv/content/parvades-sistemas-operatora-novertejumazinojumi Search in Google Scholar

2. Global Wind Energy Council. (2019). Global Wind Report 2019. Available at https://gwec.net/global-wind-report-2019/ Search in Google Scholar

3. International Energy Agency. (n.d.). IEA Report. Available at https://www.iea.org/reports/world-energy-outlook-2020 Search in Google Scholar

4. International Energy Agency. (n.d.). Renewables 2020. Analysis and Forecast to 2025. Available at https://www.iea.org/reports/renewables-2020/renewable-electricity-2 Search in Google Scholar

5. AST (n.d.). Synchronisation with Europe. Available at https://www.ast.lv/en/projects/synchronisation-europe Search in Google Scholar

6. Estonian National Development Plan of the Energy Sector until 2030. Available at https://www.mkm.ee/sites/default/files/ndpes_2030_eng.pdf Search in Google Scholar

7. ISSUU. (n.d.). Security of Supply Report. Extract. Elering 2018. Available at https://issuu.com/elering/docs/elering_vka_2018_web_trc_eng_v4 Search in Google Scholar

8. GAAS. (n.d.). Estonia’s Largest Solar Power Plant Started Operating in Pärnu. Available at https://www.gaas.ee/en/estonia-s-largest-solar-power-plant-started-operating-in-parnu/ Search in Google Scholar

9. Litgrid. (n.d.). Lithuanian Power System. Available at https://www.litgrid.eu/index.php/power-system/power-system-information/national-electricity-demand-and-generation/3523 Search in Google Scholar

10. Jain, H., Rahimi, K., Tbaileh, A., Broadwater, R., Jain, A. K., & Dilek, M. (2016). Integrated transmission & distribution system modeling and analysis: Need & advantages. In IEEE Power and Energy Society General Meeting (PESGM), (pp. 1–5), 17–21 July 2016, Boston, MA, USA.10.1109/PESGM.2016.7741235 Search in Google Scholar

11. Herbst, A., Toro, F., & Reitze, F. (2012). Introduction to Energy Systems Modelling. Swiss J Econ Stat., 148, 111–135. 10.1007/BF03399363.10.1007/BF03399363 Search in Google Scholar

12. Helistö, N., Kiviluoma, J., Ikäheimo, J., Rasku, T., Rinne, E., O’Dwyer, C. … & Flynn, D. (2019). Backbone – An Adaptable Energy Systems Modelling Framework. Energies, 12, 1–34. 10.3390/en12173388.10.3390/en12173388 Search in Google Scholar

13. Official Statistics Portal of Lithuania. Available at https://osp.stat.gov.lt Search in Google Scholar

14. IEA. (n.d.). Report of Estonian Energy System. Available at https://webstore.iea.org/download/direct/2869?fileName=Estonia_2019_Review.pdf Search in Google Scholar

15. Generation and Production in Poland. Available at https://bdl.stat.gov.pl/BDL Search in Google Scholar

16. REVE. (n.d.). Joint Baltic 1GW Offshore Wind Farm Set to Weigh on Prices. Available at https://www.evwind.es/2020/08/27/joint-baltic-1gw-offshore-wind-farm-set-to-weigh-on-prices/76841 Search in Google Scholar

17. The Baltic Course. (2020). Estonia, Latvia Planning to Jointly Develop Offshore Wind Farm. Available at http://www.baltic-course.com/eng/good_for_business/?doc=157852 Search in Google Scholar

18. AST. (n.d.) Latvia – Estonia Third Interconnection. Available at https://ast.lv/en/transmission-network-projects/latvia-estonia-third-interconnection Search in Google Scholar

19. Marine Energy. (2019). Lithuanian Floating Solar Plant Wins Project Funding. Available at https://marineenergy.biz/2019/02/26/lithuanian-floating-solar-plant-wins-project-funding/ Search in Google Scholar

20. Elering. (2019). Ten-Year Development Plan of the Estonian Electricity Transmission System. Available at https://elering.ee/sites/default/files/public/Infokeskus/elering_vka_2019_web_final2.pdf Search in Google Scholar

21. Tuuliki. (2019). EU Supports the Estonian Storage Project. Available at https://sunly.ee/eu-supports-the-estonian-pumped-hydro-storage-project-that-is-necessary-for-commissioning-more-renewable-energy-inthe-baltic-states/ Search in Google Scholar

22. ERR News. (2018). Eesti Energia Constructing 7 MW of Solar Power Stations in Next Year. Available at https://news.err.ee/867987/eesti-energia-constructing-7-mw-of-solar-power-stations-in-next-year Search in Google Scholar

23. Nord Pool Group. (n.d.). Nord Pool Energy Exchange. Available at https://www.nordpoolgroup.com/the-power-market/ Search in Google Scholar

24. Petrichenko, L., Broka, Z., Sauhats, A., & Bezrukovs, D. (2018). Cost-benefit analysis of Li-Ion batteries in a distribution network. In 2018 15th International Conference on the European Energy Market (EEM), (pp. 1–5), 27–29 June 2018, Lodz, Poland. 10.1109/EEM.2018.846978210.1109/EEM.2018.8469782 Search in Google Scholar

25. Sauhats, A., Petričenko, R., Broka, Z., Baltputnis, K., & Soboļevskis, D. (2016). ANN-based forecasting of hydropower reservoir inflow. In 2016 57th International Scientific Conference on Power and Electrical Engineering of Riga Technical University (RTUCON 2016), (pp. 267–272), 13–14 October 2016, Riga, Latvia.10.1109/RTUCON.2016.7763129 Search in Google Scholar

26. Baltputnis, K., Petrichenko, R., & Sobolevsky, D. (2018). Heating demand forecasting with multiple regression: Model setup and case study. In IEEE 6th Workshop on Advances in Information, Electronic and Electrical Engineering (AIEEE), (pp. 1–5), 8–10 November 2018, Vilnius, Lithuania.10.1109/AIEEE.2018.8592144 Search in Google Scholar

27. Sauhats, A., Petrichenko, R., Baltputnis, K., Broka, Z., & Varfolomejeva, R. (2016). A multi-objective stochastic approach to hydroelectric power generation scheduling. In Power Systems Computation Conference (PSCC), (pp. 1–7), 20–24 June 2016, Genoa, Italy.10.1109/PSCC.2016.7540821 Search in Google Scholar

28. Sauhats, A., Coban, H., Baltputnis, K., Broka, Z., Petrichenko, R., & Varfolomejeva, R. (2016). Optimal Investment and Operational Planning of a Storage Power Plant. International Journal of Hydrogen Energy, 41 (29), 12443–12453.10.1016/j.ijhydene.2016.03.078 Search in Google Scholar

29. Petrichenko, R., Petrichenko, L., Baltputnis, K., Sauhats, A., Gudzius, S., & Slivikas, A. (2020). Selection of the initial state and duration of the planning period in the tasks of managing energy storage systems. In 2020 IEEE 61st International Scientific Conference on Power and Electrical Engineering of Riga Technical University (RTUCON 2020), (pp. 1–6), 5–7 November 2020, Riga, Latvia.10.1109/RTUCON51174.2020.9316613 Search in Google Scholar

30. SolarEdge. (n.d.). Solar Generation Data. Available at https://monitoringpublic.solaredge.com/solaredge-web/p/home/public?locale=en_US Search in Google Scholar

31. SKM Market Predictor AS. (2019). Long-Term Power Outlook 2019. Available at https://www.skmenergy.com/reports/long-term-power-outlook Search in Google Scholar

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Język:
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Dziedziny czasopisma:
Physics, Technical and Applied Physics
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