|
1. [1] Favre-Perrod, Patrick. "A vision of future energy networks." Power Engineering Society Inaugural Conference and Exposition in Africa, 2005 IEEE. IEEE, 2005. 2. [2] Vahid-Pakdel, M. J., et al. "Stochastic optimization of energy hub operation with consideration of thermal energy market and demand response." Energy Conversion and Management 145 (2017): 117-128. 3. [3] Pazouki, Samaneh, Mahmoud-Reza Haghifam, and Albert Moser. "Uncertainty modeling in optimal operation of energy hub in presence of wind, storage and demand response." International Journal of Electrical Power & Energy Systems 61 (2014): 335-345. 4. [4] Moeini-Aghtaie, Moein, et al. "Multiagent genetic algorithm: an online probabilistic view on economic dispatch of energy hubs constrained by wind availability." IEEE Transactions on Sustainable Energy 5.2 (2014): 699-708. 5. [5] Rastegar, Mohammad, et al. "A probabilistic energy management scheme for renewable-based residential energy hubs." IEEE Transactions on Smart Grid (2016). 6. [6] Muruganantham, B., R. Gnanadass, and N. P. Padhy. "Challenges with renewable energy sources and storage in practical distribution systems." Renewable and Sustainable Energy Reviews 73 (2017): 125-134. 7. [7] Masuta, Taisuke, et al. "Application of battery energy storage system to power system operation for reduction in pv curtailment based on few-hours-ahead PV forecast." Power System Technology (POWERCON), 2016 IEEE International Conference on. IEEE, 2016. 8. [8] Sedghi, Mahdi, Ali Ahmadian, and Masoud Aliakbar-Golkar. "Optimal storage planning in active distribution network considering uncertainty of wind power distributed generation." IEEE Transactions on Power Systems 31.1 (2016): 304-316. 9. [9] Aalami, Habib Allah, and Sayyad Nojavan. "Energy storage system and demand response program effects on stochastic energy procurement of large consumers considering renewable generation." IET Generation, Transmission & Distribution 10.1 (2016): 107-114. 10. [10] Khani, Hadi, Mohammad R. Dadash Zadeh, and Amir H. Hajimiragha. "Transmission congestion relief using privately owned large-scale energy storage systems in a competitive electricity market." IEEE Transactions on Power Systems 31.2 (2016): 1449-1458. 11. [11] Khani, Hadi, Mohammad R. Dadash Zadeh, and Amir H. Hajimiragha. "Transmission congestion relief using privately owned large-scale energy storage systems in a competitive electricity market." IEEE Transactions on Power Systems 31.2 (2016): 1449-1458. 12. [12] Schiebahn, Sebastian, et al. "Power to gas: Technological overview, systems analysis and economic assessment for a case study in Germany." International journal of hydrogen energy 40.12 (2015): 4285-4294. 13. [13] Götz, Manuel, et al. "Renewable Power-to-Gas: A technological and economic review." Renewable Energy 85 (2016): 1371-1390. 14. [14] Clegg, Stephen, and Pierluigi Mancarella. "Integrated modeling and assessment of the operational impact of power-to-gas (P2G) on electrical and gas transmission networks." IEEE Transactions on Sustainable Energy 6.4 (2015): 1234-1244. 15. [15] Peng, Dan. "Enabling utility-scale electrical energy storage through underground hydrogen-natural gas co-storage." (2013). 16. [16] Maroufmashat, Azadeh, et al. "Mixed integer linear programing based approach for optimal planning and operation of a smart urban energy network to support the hydrogen economy." International Journal of Hydrogen Energy 41.19 (2016): 7700-7716. 17. [17] Bucher, Matthias A., et al. "Modeling and economic evaluation of Power2Gas technology using energy hub concept." Power & Energy Society General Meeting, 2015 IEEE. IEEE, 2015. 18. [18] AlRafea, Kamal, et al. "Integration of renewable energy sources into combined cycle power plants through electrolysis generated hydrogen in a new designed energy hub." International Journal of Hydrogen Energy 41.38 (2016): 16718-16728. 19. [19] Guandalini, Giulio, Stefano Campanari, and Matteo C. Romano. "Power-to-gas plants and gas turbines for improved wind energy dispatchability: Energy and economic assessment." Applied Energy 147 (2015): 117-130.
|
