AIMS Energy, 2018, 6(2): 358-375. doi: 10.3934/energy.2018.2.358.

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Numerical investigation of solar and wind energy assisted plugged in hybridized engine driven auto-rickshaw/three-wheeler

Department of Mechanical Engineering, Rajshahi University of Engineering & Technology, Rajshahi-6204, Bangladesh

In South-Asian region, Auto-rickshaw (electric/engine driven) is a well-known vehicle. Mostly in India and Bangladesh, people prefer auto-rickshaw for traveling small to medium distances. However, no reliable study has been conducted using both solar and wind energy in auto-rickshaw. This paper is basically a research on using both solar and wind energy in engine driven auto-rickshaw along with a plugged-in hybrid technology. Placement of a wind turbine on the roof of the vehicle is not an effective idea. For this reason, a model of the vehicle is proposed for the placement of the turbine inside the vehicle and the model is validated by ANSYS CFX simulation. The theory and the simulation results match perfectly. From the analysis, it has been found that both the renewable energies will provide approximately 29.34% of the total power to run the vehicle altogether. The vehicle will not only reduce the pressure on national grid electricity but also reduce the greenhouse gas emissions by a large amount, if the conventional one is replaced by the proposed one. A custom drive cycle is also obtained using the vehicle properties and comparing with Asian Urban Drive Cycle. A novel CFD simulation is conducted for wind turbine blade considering reasonable data. Feasibility study of the proposed vehicle is also analyzed in this paper considering cost, weight and emission and a future recharging infrastructure is also proposed for running the vehicle on 100% green energy. Finally, this paper would help researchers for the further development of the combined system.
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Keywords auto-rickshaw; wind energy; solar energy; renewable energy; plug-in-hybrid; emission reduction; environment-friendly vehicle

Citation: Md. Arman Arefin, Avijit Mallik. Numerical investigation of solar and wind energy assisted plugged in hybridized engine driven auto-rickshaw/three-wheeler. AIMS Energy, 2018, 6(2): 358-375. doi: 10.3934/energy.2018.2.358


  • 1. Mehrdad E, Gao Y, Longo S, et al. (2018) Design and control methodology of series–parallel (torque and speed coupling) hybrid drivetrain, In: Mehrdad E, Gao Y, Longo S, et al. Modern electric, hybrid electric, and fuel cell vehicles, 10 Eds., CRC Press, 255–270.
  • 2. Scott C, Robert MW, Russ C (2017) Summary report on the SAE 2016 range extenders for electric vehicles symposium. Available from:
  • 3. Lane B, Brendan S, Samuelsen GS (2017) Plug-in fuel cell electric vehicles: A California case study. Int J Hydrogen Energ 42: 14294–14300.    
  • 4. Ejaz S, Anwar K, Ashraf M, et al. (2009) Anti-angiogenic activities associated with exposure of environmental smoke solutions from 2-stroke auto-rickshaw. Environ Toxicol Phar 28: 42–51.    
  • 5. Mulhall P, Lukic SM, Wirasingha SG, et al. (2010) Solar-assisted electric auto rickshaw three-wheeler. IEEE T Veh Technol 59: 2298–2307.    
  • 6. Kumarage, Amal S, Bandara M (2010) Analysis of the economic and social parameters of the Three-Wheeler Taxi service in Sri Lanka. Res Transp Econ 29: 395–400.    
  • 7. Chowdhury SJ, Rahman R, Azad A (2015) Power conversion for environment friendly electrically assisted rickshaw using photovoltaic technology in Bangladesh. Transp Electrification Conf Expo 2015: 1–6.
  • 8. Kelly JC, Macdonald JS, Keoleian GA (2012) Time-dependent plug-in hybrid electric vehicle charging based on national driving patterns and demographics. Appl Energ 94: 395–405.    
  • 9. Mani A (2012) Sustainable urban transport in India: Role of the auto-rickshaw sector. Available from:
  • 10. Siddique ARM, Sakib SN, Tahsien SM, et al. (2014) Performance evaluation of a microcontroller-based solar powered auto-rickshaw. Electr Eng Inf Commun Technol 2014: 1–6.
  • 11. Shaha N, Uddin MB (2014) Hybrid energy assisted electric auto rickshaw three-wheeler. Electr Inform Commun Technol 7: 1–6.
  • 12. Rashid MJA, Rahman A, Siddique ARM, et al. (2017) A novel approach of improving battery performance and longevity of the developed electrically assisted triwheeler vehicle by implementing torque sensor technology. Int J Veh Technol 2017: 1–16.
  • 13. Adak P, Sahu R, Elumalai SP (2016) Development of emission factors for motorcycles and shared auto-rickshaws using real-world driving cycle for a typical Indian city. Sci Total Environ 544: 299–308.    
  • 14. Arefin MA, Mallik A (2017) Solar assisted micro hybridized auto-rickshaw (engine driven). J Mech Eng Res Dev 40: 660–672.
  • 15. Awal MR, Jusoh M, Sakib MN, et al. (2015) Design and implementation of vehicle mounted wind turbine. ARPN J Eng Appl Sci 10: 8699–8860.
  • 16. Chen Z, Xiong R, Wang K, et al. (2015) Optimal energy management strategy of a plug-in hybrid electric vehicle based on a particle swarm optimization algorithm. Energies 8: 3661–3678.    
  • 17. Serrao L, Onori S, Rizzoni G (2011) A comparative analysis of energy management strategies for hybrid electric vehicles. J Dyn Syst Meas Control 133: 1–9.
  • 18. Delgado J, Faria R, Moura P, et al. (2018) Impacts of plug-in electric vehicles in the portuguese electrical grid. Transp Res Part D 62: 372–385.    
  • 19. Ferdous SM, Khaled WB, Ahmed B, et al. (2011) Electric vehicle with charging facility in motion using wind energy. World Renew Energ Congr-Sweden, 3629–3636
  • 20. Fernandez-Gamiz U, Zulueta E, Boyano A, et al. (2017) Microtab design and implementation on a 5 MW wind turbine. Appl Sci 7: 536.    
  • 21. Masud MH, Naim-Ul-Hasan, Arefin AME, et al. (2017) Design modification of airfoil byintegrating sinusoidal leading edge and dimpled surface. AIP Conf Proc 1851: 191–209.
  • 22. Mulhall P, Lukic SM, Wirasingha SG, et al. (2010) Solar-assisted electric auto rickshaw three-wheeler. IEEE T Veh Technol 59: 2298–2307.    
  • 23. Lukic SM, Mulhall P, Emadi A (2008) Energy autonomous solar/battery auto rickshaw. JAEV 6: 1135–1143.    
  • 24. Fernandez-Gamiz U, Zulueta E, Boyano A, et al. (2017) Five megawatt wind turbine power output improvements by passive flow control devices. Energies 10: 742.    
  • 25. Joardder MUH (2013) Socio-economic & environmental impacts of battery driven auto rickshaw at Rajshahi city in Bangladesh. Int Conf Mech.
  • 26. Furch J (2016) A model for predicting motor vehicle life cycle cost and its verification. Trans Famena 40: 15–26.
  • 27. Gransberg D (2010) Life cycle costing for engineers. Constr Manage Econ 28: 1113–1114.    
  • 28. Mai ZQ, Xu TT, Sun L, et al. (2012) Cost estimation of product life cycle. Adv Mat Res 421: 582–585.
  • 29. Seo KK, Park JH, Jang DS, et al. (2002) Prediction of the life cycle cost using statistical and artificial neural network methods in conceptual product design. Int J Comput Integ Manuf 15: 541–554.    
  • 30. Cai X, Tyagi S (2014) Development of a product life-cycle cost estimation model to support engineering decision-making in a multi-generational product development environment. J Cost Anal Parametrics 7: 219–235.    
  • 31. Walker PD, Roser HM (2015) Energy consumption and cost analysis of hybrid electric powertrain configurations for two wheelers. Appl Energ 146: 279–287.    
  • 32. Requia WJ, Adams MD, Arain A, et al. (2017) Carbon dioxide emissions of plug-in hybrid electric vehicles: A life-cycle analysis in eight Canadian cities. Renew Sust Energ Rev 78: 1390–1396.    
  • 33. Rao AB, Rubin ES (2002) A technical, economic, and environmental assessment of amine-based CO2 capture technology for power plant greenhouse gas control. Environ Sci Technol 36: 4467–4475.    


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