Analysis of the Energy Efficiency of a Hybrid Energy Storage System for an Electric Vehicle
暂无分享,去创建一个
[1] Jiyan Qi,et al. Analysis of Micro-Electric Vehicle with Super Capacitor/Battery Hybrid Energy Storage System , 2023, Journal of Physics: Conference Series.
[2] Wei Zhou,et al. A Review on Thermal Behaviors and Thermal Management Systems for Supercapacitors , 2023, Batteries.
[3] A. Cavallo,et al. Stability and Control for Buck–Boost Converter for Aeronautic Power Management , 2023, Energies.
[4] SANTHI DURGANJALI CHALLA,et al. Design, development, and techno-economic analysis of extreme fast charging topologies using Super Capacitor and Li-Ion Battery combinations , 2022, Journal of Energy Storage.
[5] Xuelai Zhang,et al. A comprehensive review of supercapacitors: Properties, electrodes, electrolytes and thermal management systems based on phase change materials , 2022, Journal of Energy Storage.
[6] Qihong Chen,et al. Multiobjective Optimization for a Li-Ion Battery and Supercapacitor Hybrid Energy Storage Electric Vehicle , 2022, Energies.
[7] F. Blaabjerg,et al. A Comprehensive Review on Supercapacitor Applications and Developments , 2022, Energies.
[8] Georgios A. Vokas,et al. Energy management and storage systems on electric vehicles: A comprehensive review , 2021, Materials Today: Proceedings.
[9] Hui Xu,et al. The control of lithium‐ion batteries and supercapacitors in hybrid energy storage systems for electric vehicles: A review , 2021, International Journal of Energy Research.
[10] F. Heakal,et al. Synthesis of worm-like binary metallic active material by electroless deposition approach for high-performance supercapacitor , 2020 .
[11] Jingkun Xu,et al. Binder-free hierarchical porous N-doped graphene directly anchored on carbon fiber cloth for high-performance electrochemical energy storage , 2020 .
[12] Dragan Milicevic,et al. Comparative analysis of the supercapacitor influence on lithium battery cycle life in electric vehicle energy storage , 2020 .
[13] Jie Hu,et al. Intelligent energy management strategy of hybrid energy storage system for electric vehicle based on driving pattern recognition , 2020, Energy.
[14] Ihab M. Obaidat,et al. Recent progress of advanced energy storage materials for flexible and wearable supercapacitor: From design and development to applications , 2020 .
[15] Junting Wang,et al. Applications of battery/supercapacitor hybrid energy storage systems for electric vehicles using perturbation observer based robust control , 2020 .
[16] Yufeng Zhao,et al. Challenges and opportunities for supercapacitors , 2019, APL Materials.
[17] Kangwoo Chun,et al. Analysis of a Supercapacitor/Battery Hybrid Power System for a Bulk Carrier , 2019, Applied Sciences.
[18] Yazan A. Alqudah,et al. Investigations into best cost battery-supercapacitor hybrid energy storage system for a utility scale PV array , 2019, Journal of Energy Storage.
[19] Jeremy Webb,et al. Supercapacitors: A new source of power for electric cars? , 2019, Economic Analysis and Policy.
[20] Chengyi Song,et al. Temperature effect and thermal impact in lithium-ion batteries: A review , 2018, Progress in Natural Science: Materials International.
[21] Poulomi MUKHERJEE,et al. Superconducting magnetic energy storage for stabilizing grid integrated with wind power generation systems , 2018, Journal of Modern Power Systems and Clean Energy.
[22] Yee Wan Wong,et al. An adaptive learning control strategy for standalone PV system with battery-supercapacitor hybrid energy storage system , 2018, Journal of Power Sources.
[23] Evgueniy Entchev,et al. Hybrid battery/supercapacitor energy storage system for the electric vehicles , 2018 .
[24] A. K. Thakur,et al. Facile synthesis and electrochemical evaluation of PANI/CNT/MoS2 ternary composite as an electrode material for high performance supercapacitor , 2017 .
[25] Samveg Saxena,et al. Using CPE Function to Size Capacitor Storage for Electric Vehicles and Quantifying Battery Degradation during Different Driving Cycles , 2016 .
[26] A. K. Thakur,et al. High-performance supercapacitors based on polymeric binary composites of polythiophene (PTP)–titanium dioxide (TiO2) , 2016 .
[27] John R. Miller,et al. Engineering electrochemical capacitor applications , 2016 .
[28] Amine Lahyani,et al. Optimal hybridization and amortized cost study of battery/supercapacitors system under pulsed loads , 2016 .
[29] Mehrdad Kazerani,et al. A Comparative Analysis of Optimal Sizing of Battery-Only, Ultracapacitor-Only, and Battery–Ultracapacitor Hybrid Energy Storage Systems for a City Bus , 2015, IEEE Transactions on Vehicular Technology.
[30] Hamid Gualous,et al. Thermal management and forced air-cooling of supercapacitors stack , 2015 .
[31] Leon R. Roose,et al. Extended Kalman Filter with a Fuzzy Method for Accurate Battery Pack State of Charge Estimation , 2015 .
[32] Xiaowu Zhang,et al. A comparison study of different semi-active hybrid energy storage system topologies for electric vehicles , 2015 .
[33] Heath Hofmann,et al. Energy management strategies comparison for electric vehicles with hybrid energy storage system , 2014 .
[34] Valentin A. Boicea,et al. Energy Storage Technologies: The Past and the Present , 2014, Proceedings of the IEEE.
[35] John McPhee,et al. A survey of mathematics-based equivalent-circuit and electrochemical battery models for hybrid and electric vehicle simulation , 2014 .
[36] Chee Wei Tan,et al. A review of energy sources and energy management system in electric vehicles , 2013 .
[37] G. Muralidharan,et al. Interconnected V2O5 nanoporous network for high-performance supercapacitors. , 2012, ACS applied materials & interfaces.
[38] Alireza Khaligh,et al. Battery, Ultracapacitor, Fuel Cell, and Hybrid Energy Storage Systems for Electric, Hybrid Electric, Fuel Cell, and Plug-In Hybrid Electric Vehicles: State of the Art , 2010, IEEE Transactions on Vehicular Technology.
[39] Bin Wu,et al. An Overview of SMES Applications in Power and Energy Systems , 2010, IEEE Transactions on Sustainable Energy.
[40] Bingqing Wei,et al. Wide-temperature range operation supercapacitors from nanostructured activated carbon fabric , 2009 .
[41] Bruno Sareni,et al. Sizing and Energy Management of a Hybrid Locomotive Based on Flywheel and Accumulators , 2009, IEEE Transactions on Vehicular Technology.
[42] A. Morandi,et al. Cryogenic Fuel-Cooled SMES for Hybrid Vehicle Application , 2009, IEEE Transactions on Applied Superconductivity.
[43] Alfred Rufer,et al. A Hybrid Energy Storage System Based on Compressed Air and Supercapacitors With Maximum Efficiency Point Tracking (MEPT) , 2006, IEEE Transactions on Industrial Electronics.
[44] T. Ise,et al. A hybrid energy storage with a SMES and secondary battery , 2005, IEEE Transactions on Applied Superconductivity.
[45] Shuiwen Shen,et al. Analysis and control of a flywheel hybrid vehicular powertrain , 2004, IEEE Transactions on Control Systems Technology.
[46] Alexis P. Malozemoff,et al. Power applications of high-temperature superconductors: status and perspectives , 2002 .
[47] Robert E. Hebner,et al. Flywheel batteries come around again , 2002 .
[48] K. T. Chau,et al. Hybridization of energy sources in electric vehicles , 2001 .
[49] J.W. Zhang,et al. A review of control strategies for flywheel energy storage system and a case study with matrix converter , 2022, Energy Reports.
[50] M. Lewandowski,et al. Cost comparison of different configurations of a hybrid energy storage system with battery-only and supercapacitor-only storage in an electric city bus , 2019 .
[51] Bor Yann Liaw,et al. A novel on-board state-of-charge estimation method for aged Li-ion batteries based on model adaptive extended Kalman filter , 2014 .