Review
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Year 2024, Volume: 8 Issue: 1, 44 - 51, 31.03.2024
https://doi.org/10.30939/ijastech..1357392

Abstract

References

  • [1]   Oladunni OJ, Mpofu K, Olanrewaju OA. Greenhouse gas emissions and its driving forces in the transport sector of South Africa. Energy Reports, 2022; 8: 2052–2061. 10.1016/j.egyr.2022.01.123
  • [2]   Ntombela M, Musasa K, Moloi K. A Comprehensive Review for Battery Electric Vehicles (BEV) Drive Circuits Technology, Operations, and Challenges. World Electric Vehicle Journal, 2023; 14(7): 195. 10.3390/wevj14070195
  • [3]   Kim J, Oh J, Lee H. Review on battery thermal management system for electric vehicles. Applied thermal engineering, 2019; 149:192–212. 10.1016/j.applthermaleng.2018.12.020
  • [4]   Wu S, Xiong R, Li H, Nian V, Ma S. The state of the art on preheating lithium–ion batteries in cold weather. Journal of Energy Storage, 2020; 27:101059. 10.1016/j.est.2019.101059
  • [5]   Hu X, Zheng Y, Howey DA, Perez H, Foley A. Pecht, M. Battery warm–up methodologies at subzero temperatures for automotive applications: Recent advances and perspectives. Progress in Energy and Combustion Science, 2020; 77: 100806. 10.1016/j.pecs.2019.100806
  • [6]   Karakaş O, Şeker UB, Solmaz H. Modeling of an Electric Bus Using MATLAB/Simulink and Determining Cost Saving for a Realistic City Bus Line Driving Cycle. Engineering Perspective, 2021; 1 (2): 52–62. 10.29228/eng.pers.51422.
  • [7]   Goud, PVS, Chary ASVP. Evaluation of Electrification of 4W Light Commercial Vehicle. Engineering Perspective, 2023; 3(1): 9–17. 10.29228/eng.pers.69296
  • [8]   Ziegler D, Abdelkafi N. Business models for electric vehicles: Literature review and key insights. Journal of Cleaner Production ,2022; 330: 129803. 10.1016/j.jclepro.2021.129803
  • [9]   Dong Y. Analysis of consumers’ willingness to accept of government subsidies for electric vehicles. Transportation Research Procedia, 2022; 61: 90–97. 10.1016/j.trpro.2022.01.016
  • [10] Mohammadi F, Saif MA. Comprehensive Overview of Electric Vehicle Batteries Market. e–Prime–Advances in Electrical Engineering Electronics and Energy, 2023; 3: 100127. 10.1016/j.prime.2023.100127
  • [11] PR Newswire. Global nickel–metal hydride (Ni–MH) battery market 2018–2022. Available: https://www.prnewswire.com/news–releases/global–nickel–metal–hydride–ni–mh–battery–market–2018–2022–300667854.html. (Jun. 18, 2018).
  • [12] Zelinsky MA, Koch JM, Young KH. Performance comparison of rechargeable batteries for stationary applications (Ni/MH vs. Ni–Cd and VRLA). Batteries, 2017; 4(1): 1. 10.3390/batteries4010001
  • [13] Zhang Z, Dong Y, Han Y. Dynamic and control of electric vehicle in regenerative braking for driving safety and energy conservation. Journal of Vibration Engineering & Technologies, 2020; 8:179–197. 10.1007/s42417-019-00098-0
  • [14] Erhan K, Özdemir E. Prototype production and comparative analysis of high–speed flywheel energy storage systems during regenerative braking in hybrid and electric vehicles. Journal of Energy Storage, 2021; 43:103237. 10.1016/j.est.2021.103237
  • [15] Zhao W, Wu G, Wang C, Yu L, Li Y. Energy transfer and utilization efficiency of regenerative braking with hybrid energy storage system. Journal of Power Sources, 2019; 427: 174–183. 10.1016/j.jpowsour.2019.04.083
  • [16] González EL, Cuesta JS, Fernandez FJV, Llerena FI, Carlini MAR, Bordons C, Elfes A. Experimental evaluation of a passive fuel cell/battery hybrid power system for an unmanned ground vehicle. International journal of hydrogen energy, 2019; 44(25): 12772–12782. 10.1016/j.ijhydene.2018.10.107Get rights and content
  • [17] Di Trolio P, Di Giorgio P, Genovese M, Frasci E, Minutillo M. A hybrid power–unit based on a passive fuel cell/battery system for lightweight vehicles. Applied Energy, 2020; 279:115734. 10.1016/j.apenergy.2020.115734
  • [18] Esfahanian M, Safaei A, Nehzati H, Esfahanian V, Tehrani MM. Matlab–based modeling, simulation and design package for eletric, hydraulic and flywheel hybrid powertrains of a city bus. International Journal of Automotive Technology, 2014; 15:1001–1013. 10.1007/s12239-014-0105-8
  • [19] Perrotta D, Ribeiro, B, Rossetti RJ, Afonso JL. On the potential of regenerative braking of electric buses as a function of their itinerary. Procedia–Social and Behavioral Sciences, 2012; 54:1156–1167. 10.1016/j.sbspro.2012.09.830
  • [20] Subasinghage K, Gunawardane K, Padmawansa N, Kularatna N, Moradian M. Modern Supercapacitors Technologies and Their Applicability in Mature Electrical Engineering Applications. Energies, 2022; 15,(20): 7752. 10.3390/en15207752
  • [21] Lü X, Wu Y, Lian J, Zhang Y. Energy management and optimization of PEMFC/battery mobile robot based on hybrid rule strategy and AMPSO. Renewable energy, 2021; 171:881–901. 10.1016/j.renene.2021.02.135
  • [22] Fathabadi H. Fuel cell hybrid electric vehicle (FCHEV): Novel fuel cell/SC hybrid power generation system. Energy Conversion and Management, 2018; 156: 192–201. 10.1016/j.enconman.2017.11.001
  • [23] Wagner L. Overview of energy storage methods. 15. Mora Assoc 2007; http://moraassociates.com/reports/0712%20Energy%20storage.pdf
  • [24] Abumeteir H, Vural M. The Determining factors of selecting energy storage systems for the renewable energy sources in the energy–efficient building. 6th International Engineering Conference on Energy–Efficient Buildings. Islamic University of Gaza, 25–26 October 2016: 96–101. https://peeb.iugaza.edu.ps/Portals/290/Theme%203-Paper%204.pdf
  • [25] Hannan MA, Hoque MM, Mohamed A, Ayob A. Review of energy storage systems for electric vehicle applications: Issues and challenges. Renewable and Sustainable Energy Reviews, 2017; 69: 771–789. 10.1016/j.rser.2016.11.171
  • [26] Hedlund M, Lundin J, De Santiago J, Abrahamsson J, BernhoffH. Flywheel energy storage for automotive applications. Energies, 2015; 8(10): 10636–10663. 10.3390/en81010636
  • [27] Chapter 2, Technologies of energy storage systems. Grid–scale Energy Storage Systems and Application, 2019; 17–56. 10.1016/B978-0-12-815292-8.00002-2
  • [28] Brockbank C. Application of a variable drive to supercharger & turbo compounder applications. SAE Technical Paper, 2009; 8. 10.4271/2009-01-1465
  • [29] Brockbank C, Greenwood C. Fuel economy benefits of a flywheel & CVT based mechanical hybrid for city bus and commercial vehicle applications. SAE International Journal of Commercial Vehicles, 2010; 2(2): 115–122. 10.4271/2009–01–286810. 10.4271/2009-01-2868
  • [30] Yan X, Nie S, Chen B, Yin F, Ji H, Ma Z. Strategies to improve the energy efficiency of hydraulic power unit with flywheel energy storage system. Journal of Energy Storage, 2023; 59: 106515. 1016/j.est.2022.106515
  • [31] Amiryar ME, Pullen KRA. review of flywheel energy storage system technologies and their applications. Applied Science, 2017; 7(3): 286. 10.3390/app7030286
  • [32] Carbone GL, Mangialardi L, Mantriota G. A comparison of the performances of full and half toroidal traction drives. Mechanism and machine theory, 2004; 39(9): 921–942. 10.1016/j.mechmachtheory.2004.04.003
  • [33] Khodadoost Arani AA, Karami H, Gharehpetian GB, Hejazi MSA. Review of Flywheel Energy Storage Systems structures and applications in power systems and microgrids. Renewable and Sustainable Energy Reviews, 2017; 69: 9–18. 10.1016/j.rser.2016.11.166
  • [34] Faraji F, Majazi A, Al–Haddad K. A comprehensive review of flywheel energy storage system technology. Renewable and Sustainable Energy Reviews, 2017; 67: 477–490. 10.1016/j.rser.2016.09.060
  • [35] Horn M, MacLeod J, Liu M, Webb J, Motta N. Supercapacitors: A new source of power for electric cars?. Economic Analysis and Policy, 2019; 61: 93–103. 10.1016/j.eap.2018.08.003
  • [36] Habib AA, Motakabber SMA, Ibrahimy MI. A comparative study of electrochemical battery for electric vehicles applications. In 2019 IEEE International Conference on Power. IEEE, 29 November–01 December 2019: 43–47. 10.1109/PEEIACON48840.2019.9071955
  • [37] Xing Y, Ma EW, Tsui KL, Pecht M. Battery management systems in electric and hybrid vehicles. Energies, 2011; 4(11): 1840–1857. 10.3390/en4111840
  • [38] Center, AFD. Batteries for Hybrid and Plug–In Electric Vehicles. AFDC, Available: https://afdc. energy. gov/vehicles/electric_basics_ev. html. (Accessed 15 May 2019).
  • [39] Zakeri B, Syri S. Electrical energy storage systems: A comparative life cycle cost analysis. Renewable and Sustainable Energy Reviews, 2016; 42:569–596. 10.1016/j.rser.2014.10.011
  • [40] Li W, Sengupta N, Dechent P, Howey D, Annaswamy A, Sauer DU. Online capacity estimation of lithium–ion batteries with deep long short–term memory networks. Journal of power sources, 2021; 482: 228863. 10.1016/j.jpowsour.2020.228863
  • [41] Lukic SM, Cao J, Bansal, RC, Rodrigue F, Emadi A. Energy storage systems for automotive applications. IEEE Transactions on industrial electronics, 2008; 55(6): 2258–2267. 10.1109/TIE.2008.918390
  • [42] Díaz–González F, Sumper, A, Gomis–Bellmunt O, Villafáfila–Robles R. A review of energy storage technologies for wind power applications. Renewable and sustainable energy reviews, 2012; 16(4): 2154–2171. 10.1016/j.rser.2012.01.029
  • [43] Oman H, Gross S. Electric–vehicle batteries. IEEE Aerospace and Electronic Systems Magazine, 1995; 10(2): 29–35. 10.1109/62.350734
  • [44] Khaligh A, Li Z. 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. IEEE transactions on Vehicular Technology, 2010; 59(6): 2806–2814. 10.1109/TVT.2010.2047877
  • [45] Gerssen–Gondelach SJ, Faaij APC. Performance of batteries for electric vehicles on short and longer term. Journal of Power Sources, 2012; 212: 111–129. 10.1016/j.jpowsour.2012.03.085
  • [46] May GJ, Davidson A, Monahov B. Lead batteries for utility energy storage: A review. Journal of energy storage, 2018; 15: 145–157. 10.1016/j.est.2017.11.008
  • [47] Bernard P, Lippert M. Nickel–cadmium and nickel–metal hydride battery energy storage. In Electrochemical energy storage for renewable sources and grid balancing, 2015; 223–251. 10.1016/B978-0-444-62616-5.00014-0
  • [48] Sakai T, Uehara I, Ishikawa H. R&D on metal hydride materials and Ni–MH batteries in Japan. Journal of Alloys and Compounds, 1999; 293: 762–769. 10.1016/S0925-8388(99)00459-4
  • [49] Liu Y, Pan H, Gao M, Wang Q. Advanced hydrogen storage alloys for Ni/MH rechargeable batteries. Journal of Materials Chemistry, 2011; 21(13): 4743–4755. 10.1039/C0JM01921F
  • [50] Ouyang L, Huang J, Wang H, Liu J, Zhu M. Progress of hydrogen storage alloys for Ni–MH rechargeable power batteries in electric vehicles. A review Materials Chemistry and Physics, 2017; 200: 164–178. 10.1016/j.matchemphys.2017.07.002
  • [51] Karden E, Ploumen S, Fricke B, Miller T, Snyder K. Energy storage devices for future hybrid electric vehicles. Journal of Power Sources, 2007; 168(1): 2–11. 10.1016/j.jpowsour.2006.10.090
  • [52] Ekici YE, Dikmen, İC, Nurmuhammed M, Karadağ T. Efficiency analysis of various batteries with real–time data on a hybrid electric vehicle. International Journal of Automotive Science And Technology, 2021; 5(3): 214–223. 10.30939/ijastech..946047
  • [53] Abdin Z, Khalilpour KR. Single and polystorage technologies for renewable–based hybrid energy systems. In Polygeneration with polystorage for chemical and energy hubs, 2019; 77–131. 10.1016/B978-0-12-813306-4.00004-5
  • [54] Li J, Zhang G, Fu C, Deng L, Sun R, Wong CP. Facile preparation of nitrogen/sulfur co–doped and hierarchical porous graphene hydrogel for high–performance electrochemical capacitor. Journal of Power Sources, 2017; 345: 146–155. 10.1016/j.jpowsour.2017.02.011
  • [55] Okonkwo PC, Collins E, Okonkwo E. Application of biopolymer composites in super capacitor. In Biopolymer composites in electronics, 2017; 487–503. 10.1016/B978-0-12-809261-3.00018-8
  • [56] Javaid A, Noreen S. Mechanically robust structural hybrid supercapacitors with high energy density for electric vehicle applications. Journal of Energy Storage, 2022; 55: 105818. 10.1021/acs.nanolett.5b01394
  • [57] Dinçer I. Comprehensive Energy Systems. Oshawa, CANADA: Elsevier, 1:72–87, 2018.
  • [58] Wahab YA, Naseer MN, Zaidi AA, Umair T, Khan H, Siddiqi MM, Javed MS. Super Capacitors in Various Dimensionalities: Applications and Recent Advancements, 2022; 55. 10.1016/B978-0-12-819723-3.00020-2
  • [59] Goswami M, Kumar S, Siddiqui H, Chauhan V, Singh N, Sathish N, Kumar S. Hybrid energy storage devices: Li–ion and Na–ion capacitors. In Emerging Trends in Energy Storage Systems and Industrial Applications, 2023; 223–258. 10.1016/B978-0-323-90521-3.00016-8
  • [60] Kang YJ, Chung H, Kim W. 1.8–V flexible supercapacitors with asymmetric configuration based on manganese oxide, carbon nanotubes, and a gel electrolyte. Synthetic metals, 2013; 166: 40–44. 10.1016/j.synthmet.2013.01.013
  • [61] Faraji S, Ani FN. The development supercapacitor from activated carbon by electroless plating—A review. Renewable and Sustainable Energy Reviews, 2015; 42: 823–834. 10.1016/j.rser.2014.10.068
  • [62] Sagadevan S, Marlinda, AR, Chowdhury ZZ, Wahab YBA, Hamizi NA, Shahid, MM, Johan MR. Fundamental electrochemical energy storage systems. Advances in Supercapacitor and Supercapattery, 2021; 27–43. 10.1016/B978-0-12-819897-1.00001-X
  • [63] Burke A, Miller M. The power capability of ultracapacitors and lithium batteries for electric and hybrid vehicle applications. Journal of Power Sources, 2011; 196(1): 514–522. 10.1016/j.jpowsour.2010.06.092
  • [64] Pay S, Baghzou Y. Effectiveness of battery–supercapacitor combination in electric vehicles. In 2003 IEEE Bologna Power Tech Conference Proceedings IEEE, 23–26 June 2003: 6. 10.1109/PTC.2003.1304472
  • [65] Şahin ME, Blaabjerg F, Sangwongwanich A. A comprehensive review on supercapacitor applications and developments. Energies 2022; 15(3): 674. 10.3390/en15030674
  • [66] Namirian Z. Comprehensıve overvıew of hybrıd vehıcle drıvetraıns. International Research Journal of Engineering and Technology, 2020; 7(8). https://www.irjet.net/archives/V7/i8/IRJET-V7I801.pdf
  • [67] Balali Y, Stegen S. Review of energy storage systems for vehicles based on technology, environmental impacts, and costs. Renewable and Sustainable Energy Reviews, 2021; 135: 110185. https://www.irjet.net/archives/V7/i8/IRJET-V7I801.pdf
  • [68] Wang D, Ren C, Sivasubramaniam A, Urgaonkar B, Fathy H. Energy storage in datacenters: what, where, and how much?. In Proceedings of the 12th ACM SIGMETRICS/PERFORMANCE joint international conference on Measurement and Modeling of Computer Systems, 2012; 187–198. 10.1145/2254756.2254780
  • [69] Zhou ML,Wei L, Wen JB. The Parameters Matching and Simulation of Pure Electric Vehicle Composite Power Supply Based on CRUISE. In Applied Mechanics and Materials, 2014; 602: 2836–2839. 10.4028/www.scientific.net/AMM.602-605.2836
  • [70] Griffo A, Wan J. Modeling and stability analysis of hybrid power systems for the more electric aircraft. Electric power systems research, 2012; 82(1): 59–67. 10.1016/j.epsr.2011.08.017
  • [71] Zhao G, Wang X, Negnevitsky M. Connecting battery technologies for electric vehicles from battery materials to management. Iscience, 2022; 25(2): 103744. 10.1016/j.isci.2022.103744
  • [72] Song Z, Li J, Hou J, Hofmann H, Ouyang M, Du J. The battery–supercapacitor hybrid energy storage system in electric vehicle applications: A case study. Energy, 2018; 154: 433–441. 10.1016/j.energy.2018.04.148
  • [73] Hannan MA, Azidin FA., Mohamed A. Hybrid electric vehicles and their challenges: A review. Renewable and Sustainable Energy Reviews, 2014; 29: 135–150. 10.1016/j.rser.2013.08.097
  • [74] Arslan S, Mellah H. Analysis and testing of internal combustion engine driven linear alternator. Electrical Engineering & Electromechanics, 2023; 1: 3–9. 10.20998/2074-272X.2023.1.01
  • [75] García P, Fernández LM, Torreglosa JP, Jurado, F. Operation mode control of a hybrid power system based on fuel cell/battery/ultracapacitor for an electric tramway. Computers & Electrical Engineering, 2013; 39(7) :1993-2004. 10.1016/j.compeleceng.2013.04.022
  • [76] Li Q, Chen W, Li Y, Liu S, Huang J. Energy management strategy for fuel cell/battery/ultracapacitor hybrid vehicle based on fuzzy logic. International Journal of Electrical Power & Energy Systems, 2012; 43(1): 514–525. 10.1016/j.ijepes.2012.06.026
  • [77] García P, Torreglosa JP, Fernández L.M, Jurado F. Control strategies for high–power electric vehicles powered by hydrogen fuel cell, battery and supercapacitor. Expert Systems with Applications, 2013; 40(12): 4791–4804. 10.1016/j.eswa.2013.02.028
  • [78] Al Sakka, M., Van Mierlo, J., Gualous, H., Brussel, U. Electric Vehicles–Modelling and Simulations. Belgium, France: Intech, 2011.
  • [79] Kumar D, Neman RK, Gupta S. A comparative review on power conversion topologies and energy storage system for electric vehicles. International Journal of Energy Research, 2020; 44(10): 7863–7885. 10.1002/er.5353
  • [80] Kurtulmuş ZN, Karakaya A. Review of lithium–ion, fuel cell, sodium–beta, nickel–based and metal–air battery technologies used in electric vehicles. International Journal of Energy Applications and Technologies, 2023; 10(2): 103–113. 10.31593/ijeat.1307361
  • [81] Yi F, Lu D, Wang X, Pan C, Tao Y, Zhou J, Zhao C. Energy management strategy for hybrid energy storage electric vehicles based on pontryagin’s minimum principle considering battery degradation. Sustainability, 2022; 14(3): 1214. 10.3390/su14031214
  • [82] Erhan K, Ayaz M, Özdemir E. Elektrikli Araç Şarj İstasyonlarının Güç Kalitesi Üzerine Etkileri Impact of Charging Stations for Electric Vehicles on Power Quality; Akıllı Şebekeler ve Türkiye Elektrik Şebekesinin Geleceği Sempozyumu, 2013: 1–5. https://www.emo.org.tr/ekler/264416dd9186ef8_ek.pdf
  • [83] Barelli L, Bidini G, Bonucci F, Castellini L, Fratini A, Gallorini F, Zuccari A. Flywheel hybridization to improve battery life in energy storage systems coupled to RES plants. Energy, 2019; 173: 937–95. 10.1016/j.energy.2019.02.143
  • [84] Alpaslan E, Çetinkaya SA, Yüksel Alpaydın C, Korkmaz SA, Karaoğlan MU. Colpan, CO, Gören A. A review on fuel cell electric vehicle powertrain modeling and simulation.. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2021; 1–37. 10.1080/15567036.2021.1999347
  • [85] Yildiz A, Özel MA. A comparative study of energy consumption and recovery of autonomous fuel–cell hydrogen–electric vehicles using different powertrains based on regenerative braking and electronic stability control system. Applied Sciences, 2021; 11(6): 2515. 10.3390/app11062515
  • [86] Boyacıoğlu NM, Kocakulak T, Batar M, Uyumaz A, Solmaz, H. Modeling and Control of a PEM Fuel Cell Hybrid Energy System Used in a Vehicle with Fuzzy Logic Method. International Journal of Automotive Science And Technology, 2023; 7(4): 295–308. 10.30939/ijastech..1340339
  • [87] Kurtulmus ZN, Karakaya A. Efficiency Analysis of Regenerative Brake System Using Flywheel Energy Storage Technology in Electric Vehicles. Technical Gazette: Tehnički Vjesnik, 2023; 7(1): 13. 10.17559/TV-20230611000719.

Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles

Year 2024, Volume: 8 Issue: 1, 44 - 51, 31.03.2024
https://doi.org/10.30939/ijastech..1357392

Abstract

The population rate in the world is increasing rapidly. Depending on the population, the need for transportation increases at the same rate. Traditional vehicles, which provide great convenience in transportation, bring with them some disadvantages. For example, the fossil fuel used in conventional vehicles creates greenhouse gases such as CO2 and N2O. This has a negative impact on global warming. To eliminate these negativities, interest in electric vehicle (EV) and hybrid electric vehicles (HEV) technology studies has increased recently. Some problems have arisen with these technological studies. The range problem in vehicles is the biggest of these problems. Therefore, various solutions are sought for energy storage problems in vehicles. In this article, studies on HEV and energy storage in EVs are examined. According to the data obtained because of this examination, the performance analysis of the Energy Storage Systems (ESS) was made. The performances of the electrochemical batteries used in HEVs and EVs were compared. In addition to these, flywheel energy storage system was also investigated in HEVs and EVs to recover the energy lost because of braking.

References

  • [1]   Oladunni OJ, Mpofu K, Olanrewaju OA. Greenhouse gas emissions and its driving forces in the transport sector of South Africa. Energy Reports, 2022; 8: 2052–2061. 10.1016/j.egyr.2022.01.123
  • [2]   Ntombela M, Musasa K, Moloi K. A Comprehensive Review for Battery Electric Vehicles (BEV) Drive Circuits Technology, Operations, and Challenges. World Electric Vehicle Journal, 2023; 14(7): 195. 10.3390/wevj14070195
  • [3]   Kim J, Oh J, Lee H. Review on battery thermal management system for electric vehicles. Applied thermal engineering, 2019; 149:192–212. 10.1016/j.applthermaleng.2018.12.020
  • [4]   Wu S, Xiong R, Li H, Nian V, Ma S. The state of the art on preheating lithium–ion batteries in cold weather. Journal of Energy Storage, 2020; 27:101059. 10.1016/j.est.2019.101059
  • [5]   Hu X, Zheng Y, Howey DA, Perez H, Foley A. Pecht, M. Battery warm–up methodologies at subzero temperatures for automotive applications: Recent advances and perspectives. Progress in Energy and Combustion Science, 2020; 77: 100806. 10.1016/j.pecs.2019.100806
  • [6]   Karakaş O, Şeker UB, Solmaz H. Modeling of an Electric Bus Using MATLAB/Simulink and Determining Cost Saving for a Realistic City Bus Line Driving Cycle. Engineering Perspective, 2021; 1 (2): 52–62. 10.29228/eng.pers.51422.
  • [7]   Goud, PVS, Chary ASVP. Evaluation of Electrification of 4W Light Commercial Vehicle. Engineering Perspective, 2023; 3(1): 9–17. 10.29228/eng.pers.69296
  • [8]   Ziegler D, Abdelkafi N. Business models for electric vehicles: Literature review and key insights. Journal of Cleaner Production ,2022; 330: 129803. 10.1016/j.jclepro.2021.129803
  • [9]   Dong Y. Analysis of consumers’ willingness to accept of government subsidies for electric vehicles. Transportation Research Procedia, 2022; 61: 90–97. 10.1016/j.trpro.2022.01.016
  • [10] Mohammadi F, Saif MA. Comprehensive Overview of Electric Vehicle Batteries Market. e–Prime–Advances in Electrical Engineering Electronics and Energy, 2023; 3: 100127. 10.1016/j.prime.2023.100127
  • [11] PR Newswire. Global nickel–metal hydride (Ni–MH) battery market 2018–2022. Available: https://www.prnewswire.com/news–releases/global–nickel–metal–hydride–ni–mh–battery–market–2018–2022–300667854.html. (Jun. 18, 2018).
  • [12] Zelinsky MA, Koch JM, Young KH. Performance comparison of rechargeable batteries for stationary applications (Ni/MH vs. Ni–Cd and VRLA). Batteries, 2017; 4(1): 1. 10.3390/batteries4010001
  • [13] Zhang Z, Dong Y, Han Y. Dynamic and control of electric vehicle in regenerative braking for driving safety and energy conservation. Journal of Vibration Engineering & Technologies, 2020; 8:179–197. 10.1007/s42417-019-00098-0
  • [14] Erhan K, Özdemir E. Prototype production and comparative analysis of high–speed flywheel energy storage systems during regenerative braking in hybrid and electric vehicles. Journal of Energy Storage, 2021; 43:103237. 10.1016/j.est.2021.103237
  • [15] Zhao W, Wu G, Wang C, Yu L, Li Y. Energy transfer and utilization efficiency of regenerative braking with hybrid energy storage system. Journal of Power Sources, 2019; 427: 174–183. 10.1016/j.jpowsour.2019.04.083
  • [16] González EL, Cuesta JS, Fernandez FJV, Llerena FI, Carlini MAR, Bordons C, Elfes A. Experimental evaluation of a passive fuel cell/battery hybrid power system for an unmanned ground vehicle. International journal of hydrogen energy, 2019; 44(25): 12772–12782. 10.1016/j.ijhydene.2018.10.107Get rights and content
  • [17] Di Trolio P, Di Giorgio P, Genovese M, Frasci E, Minutillo M. A hybrid power–unit based on a passive fuel cell/battery system for lightweight vehicles. Applied Energy, 2020; 279:115734. 10.1016/j.apenergy.2020.115734
  • [18] Esfahanian M, Safaei A, Nehzati H, Esfahanian V, Tehrani MM. Matlab–based modeling, simulation and design package for eletric, hydraulic and flywheel hybrid powertrains of a city bus. International Journal of Automotive Technology, 2014; 15:1001–1013. 10.1007/s12239-014-0105-8
  • [19] Perrotta D, Ribeiro, B, Rossetti RJ, Afonso JL. On the potential of regenerative braking of electric buses as a function of their itinerary. Procedia–Social and Behavioral Sciences, 2012; 54:1156–1167. 10.1016/j.sbspro.2012.09.830
  • [20] Subasinghage K, Gunawardane K, Padmawansa N, Kularatna N, Moradian M. Modern Supercapacitors Technologies and Their Applicability in Mature Electrical Engineering Applications. Energies, 2022; 15,(20): 7752. 10.3390/en15207752
  • [21] Lü X, Wu Y, Lian J, Zhang Y. Energy management and optimization of PEMFC/battery mobile robot based on hybrid rule strategy and AMPSO. Renewable energy, 2021; 171:881–901. 10.1016/j.renene.2021.02.135
  • [22] Fathabadi H. Fuel cell hybrid electric vehicle (FCHEV): Novel fuel cell/SC hybrid power generation system. Energy Conversion and Management, 2018; 156: 192–201. 10.1016/j.enconman.2017.11.001
  • [23] Wagner L. Overview of energy storage methods. 15. Mora Assoc 2007; http://moraassociates.com/reports/0712%20Energy%20storage.pdf
  • [24] Abumeteir H, Vural M. The Determining factors of selecting energy storage systems for the renewable energy sources in the energy–efficient building. 6th International Engineering Conference on Energy–Efficient Buildings. Islamic University of Gaza, 25–26 October 2016: 96–101. https://peeb.iugaza.edu.ps/Portals/290/Theme%203-Paper%204.pdf
  • [25] Hannan MA, Hoque MM, Mohamed A, Ayob A. Review of energy storage systems for electric vehicle applications: Issues and challenges. Renewable and Sustainable Energy Reviews, 2017; 69: 771–789. 10.1016/j.rser.2016.11.171
  • [26] Hedlund M, Lundin J, De Santiago J, Abrahamsson J, BernhoffH. Flywheel energy storage for automotive applications. Energies, 2015; 8(10): 10636–10663. 10.3390/en81010636
  • [27] Chapter 2, Technologies of energy storage systems. Grid–scale Energy Storage Systems and Application, 2019; 17–56. 10.1016/B978-0-12-815292-8.00002-2
  • [28] Brockbank C. Application of a variable drive to supercharger & turbo compounder applications. SAE Technical Paper, 2009; 8. 10.4271/2009-01-1465
  • [29] Brockbank C, Greenwood C. Fuel economy benefits of a flywheel & CVT based mechanical hybrid for city bus and commercial vehicle applications. SAE International Journal of Commercial Vehicles, 2010; 2(2): 115–122. 10.4271/2009–01–286810. 10.4271/2009-01-2868
  • [30] Yan X, Nie S, Chen B, Yin F, Ji H, Ma Z. Strategies to improve the energy efficiency of hydraulic power unit with flywheel energy storage system. Journal of Energy Storage, 2023; 59: 106515. 1016/j.est.2022.106515
  • [31] Amiryar ME, Pullen KRA. review of flywheel energy storage system technologies and their applications. Applied Science, 2017; 7(3): 286. 10.3390/app7030286
  • [32] Carbone GL, Mangialardi L, Mantriota G. A comparison of the performances of full and half toroidal traction drives. Mechanism and machine theory, 2004; 39(9): 921–942. 10.1016/j.mechmachtheory.2004.04.003
  • [33] Khodadoost Arani AA, Karami H, Gharehpetian GB, Hejazi MSA. Review of Flywheel Energy Storage Systems structures and applications in power systems and microgrids. Renewable and Sustainable Energy Reviews, 2017; 69: 9–18. 10.1016/j.rser.2016.11.166
  • [34] Faraji F, Majazi A, Al–Haddad K. A comprehensive review of flywheel energy storage system technology. Renewable and Sustainable Energy Reviews, 2017; 67: 477–490. 10.1016/j.rser.2016.09.060
  • [35] Horn M, MacLeod J, Liu M, Webb J, Motta N. Supercapacitors: A new source of power for electric cars?. Economic Analysis and Policy, 2019; 61: 93–103. 10.1016/j.eap.2018.08.003
  • [36] Habib AA, Motakabber SMA, Ibrahimy MI. A comparative study of electrochemical battery for electric vehicles applications. In 2019 IEEE International Conference on Power. IEEE, 29 November–01 December 2019: 43–47. 10.1109/PEEIACON48840.2019.9071955
  • [37] Xing Y, Ma EW, Tsui KL, Pecht M. Battery management systems in electric and hybrid vehicles. Energies, 2011; 4(11): 1840–1857. 10.3390/en4111840
  • [38] Center, AFD. Batteries for Hybrid and Plug–In Electric Vehicles. AFDC, Available: https://afdc. energy. gov/vehicles/electric_basics_ev. html. (Accessed 15 May 2019).
  • [39] Zakeri B, Syri S. Electrical energy storage systems: A comparative life cycle cost analysis. Renewable and Sustainable Energy Reviews, 2016; 42:569–596. 10.1016/j.rser.2014.10.011
  • [40] Li W, Sengupta N, Dechent P, Howey D, Annaswamy A, Sauer DU. Online capacity estimation of lithium–ion batteries with deep long short–term memory networks. Journal of power sources, 2021; 482: 228863. 10.1016/j.jpowsour.2020.228863
  • [41] Lukic SM, Cao J, Bansal, RC, Rodrigue F, Emadi A. Energy storage systems for automotive applications. IEEE Transactions on industrial electronics, 2008; 55(6): 2258–2267. 10.1109/TIE.2008.918390
  • [42] Díaz–González F, Sumper, A, Gomis–Bellmunt O, Villafáfila–Robles R. A review of energy storage technologies for wind power applications. Renewable and sustainable energy reviews, 2012; 16(4): 2154–2171. 10.1016/j.rser.2012.01.029
  • [43] Oman H, Gross S. Electric–vehicle batteries. IEEE Aerospace and Electronic Systems Magazine, 1995; 10(2): 29–35. 10.1109/62.350734
  • [44] Khaligh A, Li Z. 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. IEEE transactions on Vehicular Technology, 2010; 59(6): 2806–2814. 10.1109/TVT.2010.2047877
  • [45] Gerssen–Gondelach SJ, Faaij APC. Performance of batteries for electric vehicles on short and longer term. Journal of Power Sources, 2012; 212: 111–129. 10.1016/j.jpowsour.2012.03.085
  • [46] May GJ, Davidson A, Monahov B. Lead batteries for utility energy storage: A review. Journal of energy storage, 2018; 15: 145–157. 10.1016/j.est.2017.11.008
  • [47] Bernard P, Lippert M. Nickel–cadmium and nickel–metal hydride battery energy storage. In Electrochemical energy storage for renewable sources and grid balancing, 2015; 223–251. 10.1016/B978-0-444-62616-5.00014-0
  • [48] Sakai T, Uehara I, Ishikawa H. R&D on metal hydride materials and Ni–MH batteries in Japan. Journal of Alloys and Compounds, 1999; 293: 762–769. 10.1016/S0925-8388(99)00459-4
  • [49] Liu Y, Pan H, Gao M, Wang Q. Advanced hydrogen storage alloys for Ni/MH rechargeable batteries. Journal of Materials Chemistry, 2011; 21(13): 4743–4755. 10.1039/C0JM01921F
  • [50] Ouyang L, Huang J, Wang H, Liu J, Zhu M. Progress of hydrogen storage alloys for Ni–MH rechargeable power batteries in electric vehicles. A review Materials Chemistry and Physics, 2017; 200: 164–178. 10.1016/j.matchemphys.2017.07.002
  • [51] Karden E, Ploumen S, Fricke B, Miller T, Snyder K. Energy storage devices for future hybrid electric vehicles. Journal of Power Sources, 2007; 168(1): 2–11. 10.1016/j.jpowsour.2006.10.090
  • [52] Ekici YE, Dikmen, İC, Nurmuhammed M, Karadağ T. Efficiency analysis of various batteries with real–time data on a hybrid electric vehicle. International Journal of Automotive Science And Technology, 2021; 5(3): 214–223. 10.30939/ijastech..946047
  • [53] Abdin Z, Khalilpour KR. Single and polystorage technologies for renewable–based hybrid energy systems. In Polygeneration with polystorage for chemical and energy hubs, 2019; 77–131. 10.1016/B978-0-12-813306-4.00004-5
  • [54] Li J, Zhang G, Fu C, Deng L, Sun R, Wong CP. Facile preparation of nitrogen/sulfur co–doped and hierarchical porous graphene hydrogel for high–performance electrochemical capacitor. Journal of Power Sources, 2017; 345: 146–155. 10.1016/j.jpowsour.2017.02.011
  • [55] Okonkwo PC, Collins E, Okonkwo E. Application of biopolymer composites in super capacitor. In Biopolymer composites in electronics, 2017; 487–503. 10.1016/B978-0-12-809261-3.00018-8
  • [56] Javaid A, Noreen S. Mechanically robust structural hybrid supercapacitors with high energy density for electric vehicle applications. Journal of Energy Storage, 2022; 55: 105818. 10.1021/acs.nanolett.5b01394
  • [57] Dinçer I. Comprehensive Energy Systems. Oshawa, CANADA: Elsevier, 1:72–87, 2018.
  • [58] Wahab YA, Naseer MN, Zaidi AA, Umair T, Khan H, Siddiqi MM, Javed MS. Super Capacitors in Various Dimensionalities: Applications and Recent Advancements, 2022; 55. 10.1016/B978-0-12-819723-3.00020-2
  • [59] Goswami M, Kumar S, Siddiqui H, Chauhan V, Singh N, Sathish N, Kumar S. Hybrid energy storage devices: Li–ion and Na–ion capacitors. In Emerging Trends in Energy Storage Systems and Industrial Applications, 2023; 223–258. 10.1016/B978-0-323-90521-3.00016-8
  • [60] Kang YJ, Chung H, Kim W. 1.8–V flexible supercapacitors with asymmetric configuration based on manganese oxide, carbon nanotubes, and a gel electrolyte. Synthetic metals, 2013; 166: 40–44. 10.1016/j.synthmet.2013.01.013
  • [61] Faraji S, Ani FN. The development supercapacitor from activated carbon by electroless plating—A review. Renewable and Sustainable Energy Reviews, 2015; 42: 823–834. 10.1016/j.rser.2014.10.068
  • [62] Sagadevan S, Marlinda, AR, Chowdhury ZZ, Wahab YBA, Hamizi NA, Shahid, MM, Johan MR. Fundamental electrochemical energy storage systems. Advances in Supercapacitor and Supercapattery, 2021; 27–43. 10.1016/B978-0-12-819897-1.00001-X
  • [63] Burke A, Miller M. The power capability of ultracapacitors and lithium batteries for electric and hybrid vehicle applications. Journal of Power Sources, 2011; 196(1): 514–522. 10.1016/j.jpowsour.2010.06.092
  • [64] Pay S, Baghzou Y. Effectiveness of battery–supercapacitor combination in electric vehicles. In 2003 IEEE Bologna Power Tech Conference Proceedings IEEE, 23–26 June 2003: 6. 10.1109/PTC.2003.1304472
  • [65] Şahin ME, Blaabjerg F, Sangwongwanich A. A comprehensive review on supercapacitor applications and developments. Energies 2022; 15(3): 674. 10.3390/en15030674
  • [66] Namirian Z. Comprehensıve overvıew of hybrıd vehıcle drıvetraıns. International Research Journal of Engineering and Technology, 2020; 7(8). https://www.irjet.net/archives/V7/i8/IRJET-V7I801.pdf
  • [67] Balali Y, Stegen S. Review of energy storage systems for vehicles based on technology, environmental impacts, and costs. Renewable and Sustainable Energy Reviews, 2021; 135: 110185. https://www.irjet.net/archives/V7/i8/IRJET-V7I801.pdf
  • [68] Wang D, Ren C, Sivasubramaniam A, Urgaonkar B, Fathy H. Energy storage in datacenters: what, where, and how much?. In Proceedings of the 12th ACM SIGMETRICS/PERFORMANCE joint international conference on Measurement and Modeling of Computer Systems, 2012; 187–198. 10.1145/2254756.2254780
  • [69] Zhou ML,Wei L, Wen JB. The Parameters Matching and Simulation of Pure Electric Vehicle Composite Power Supply Based on CRUISE. In Applied Mechanics and Materials, 2014; 602: 2836–2839. 10.4028/www.scientific.net/AMM.602-605.2836
  • [70] Griffo A, Wan J. Modeling and stability analysis of hybrid power systems for the more electric aircraft. Electric power systems research, 2012; 82(1): 59–67. 10.1016/j.epsr.2011.08.017
  • [71] Zhao G, Wang X, Negnevitsky M. Connecting battery technologies for electric vehicles from battery materials to management. Iscience, 2022; 25(2): 103744. 10.1016/j.isci.2022.103744
  • [72] Song Z, Li J, Hou J, Hofmann H, Ouyang M, Du J. The battery–supercapacitor hybrid energy storage system in electric vehicle applications: A case study. Energy, 2018; 154: 433–441. 10.1016/j.energy.2018.04.148
  • [73] Hannan MA, Azidin FA., Mohamed A. Hybrid electric vehicles and their challenges: A review. Renewable and Sustainable Energy Reviews, 2014; 29: 135–150. 10.1016/j.rser.2013.08.097
  • [74] Arslan S, Mellah H. Analysis and testing of internal combustion engine driven linear alternator. Electrical Engineering & Electromechanics, 2023; 1: 3–9. 10.20998/2074-272X.2023.1.01
  • [75] García P, Fernández LM, Torreglosa JP, Jurado, F. Operation mode control of a hybrid power system based on fuel cell/battery/ultracapacitor for an electric tramway. Computers & Electrical Engineering, 2013; 39(7) :1993-2004. 10.1016/j.compeleceng.2013.04.022
  • [76] Li Q, Chen W, Li Y, Liu S, Huang J. Energy management strategy for fuel cell/battery/ultracapacitor hybrid vehicle based on fuzzy logic. International Journal of Electrical Power & Energy Systems, 2012; 43(1): 514–525. 10.1016/j.ijepes.2012.06.026
  • [77] García P, Torreglosa JP, Fernández L.M, Jurado F. Control strategies for high–power electric vehicles powered by hydrogen fuel cell, battery and supercapacitor. Expert Systems with Applications, 2013; 40(12): 4791–4804. 10.1016/j.eswa.2013.02.028
  • [78] Al Sakka, M., Van Mierlo, J., Gualous, H., Brussel, U. Electric Vehicles–Modelling and Simulations. Belgium, France: Intech, 2011.
  • [79] Kumar D, Neman RK, Gupta S. A comparative review on power conversion topologies and energy storage system for electric vehicles. International Journal of Energy Research, 2020; 44(10): 7863–7885. 10.1002/er.5353
  • [80] Kurtulmuş ZN, Karakaya A. Review of lithium–ion, fuel cell, sodium–beta, nickel–based and metal–air battery technologies used in electric vehicles. International Journal of Energy Applications and Technologies, 2023; 10(2): 103–113. 10.31593/ijeat.1307361
  • [81] Yi F, Lu D, Wang X, Pan C, Tao Y, Zhou J, Zhao C. Energy management strategy for hybrid energy storage electric vehicles based on pontryagin’s minimum principle considering battery degradation. Sustainability, 2022; 14(3): 1214. 10.3390/su14031214
  • [82] Erhan K, Ayaz M, Özdemir E. Elektrikli Araç Şarj İstasyonlarının Güç Kalitesi Üzerine Etkileri Impact of Charging Stations for Electric Vehicles on Power Quality; Akıllı Şebekeler ve Türkiye Elektrik Şebekesinin Geleceği Sempozyumu, 2013: 1–5. https://www.emo.org.tr/ekler/264416dd9186ef8_ek.pdf
  • [83] Barelli L, Bidini G, Bonucci F, Castellini L, Fratini A, Gallorini F, Zuccari A. Flywheel hybridization to improve battery life in energy storage systems coupled to RES plants. Energy, 2019; 173: 937–95. 10.1016/j.energy.2019.02.143
  • [84] Alpaslan E, Çetinkaya SA, Yüksel Alpaydın C, Korkmaz SA, Karaoğlan MU. Colpan, CO, Gören A. A review on fuel cell electric vehicle powertrain modeling and simulation.. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2021; 1–37. 10.1080/15567036.2021.1999347
  • [85] Yildiz A, Özel MA. A comparative study of energy consumption and recovery of autonomous fuel–cell hydrogen–electric vehicles using different powertrains based on regenerative braking and electronic stability control system. Applied Sciences, 2021; 11(6): 2515. 10.3390/app11062515
  • [86] Boyacıoğlu NM, Kocakulak T, Batar M, Uyumaz A, Solmaz, H. Modeling and Control of a PEM Fuel Cell Hybrid Energy System Used in a Vehicle with Fuzzy Logic Method. International Journal of Automotive Science And Technology, 2023; 7(4): 295–308. 10.30939/ijastech..1340339
  • [87] Kurtulmus ZN, Karakaya A. Efficiency Analysis of Regenerative Brake System Using Flywheel Energy Storage Technology in Electric Vehicles. Technical Gazette: Tehnički Vjesnik, 2023; 7(1): 13. 10.17559/TV-20230611000719.
There are 87 citations in total.

Details

Primary Language English
Subjects Hybrid and Electric Vehicles and Powertrains
Journal Section Review Articles
Authors

Zeyneb Nuriye Kurtulmuş 0000-0001-7480-4907

Abdulhakim Karakaya 0000-0003-1119-6945

Publication Date March 31, 2024
Submission Date September 8, 2023
Acceptance Date January 10, 2024
Published in Issue Year 2024 Volume: 8 Issue: 1

Cite

APA Kurtulmuş, Z. N., & Karakaya, A. (2024). Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles. International Journal of Automotive Science And Technology, 8(1), 44-51. https://doi.org/10.30939/ijastech..1357392
AMA Kurtulmuş ZN, Karakaya A. Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles. IJASTECH. March 2024;8(1):44-51. doi:10.30939/ijastech.1357392
Chicago Kurtulmuş, Zeyneb Nuriye, and Abdulhakim Karakaya. “Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles”. International Journal of Automotive Science And Technology 8, no. 1 (March 2024): 44-51. https://doi.org/10.30939/ijastech. 1357392.
EndNote Kurtulmuş ZN, Karakaya A (March 1, 2024) Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles. International Journal of Automotive Science And Technology 8 1 44–51.
IEEE Z. N. Kurtulmuş and A. Karakaya, “Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles”, IJASTECH, vol. 8, no. 1, pp. 44–51, 2024, doi: 10.30939/ijastech..1357392.
ISNAD Kurtulmuş, Zeyneb Nuriye - Karakaya, Abdulhakim. “Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles”. International Journal of Automotive Science And Technology 8/1 (March 2024), 44-51. https://doi.org/10.30939/ijastech. 1357392.
JAMA Kurtulmuş ZN, Karakaya A. Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles. IJASTECH. 2024;8:44–51.
MLA Kurtulmuş, Zeyneb Nuriye and Abdulhakim Karakaya. “Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles”. International Journal of Automotive Science And Technology, vol. 8, no. 1, 2024, pp. 44-51, doi:10.30939/ijastech. 1357392.
Vancouver Kurtulmuş ZN, Karakaya A. Review of Mechanical, Electrochemical, Electrical, and Hybrid Energy Storage Systems Used for Electric Vehicles. IJASTECH. 2024;8(1):44-51.


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