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Reliability investigation of electric vehicle

  • Bharathi Sankar AmmaiyappanEmail author
  • Seyezhai Ramalingam
Original Research
  • 7 Downloads

Abstract

Investigation of reliability is of vital importance to design, implement and manage the operation of vehicles. This can be used as an important tool for the proper design and control of vehicles. The main components of the electric vehicle (EV) are the batteries and the electric drive. This paper focuses on the reliability aspects of the lead acid battery, motor controller and electric motor employed for the operation of electric vehicles. Battery is the most important and also the least reliable component in EV, which has a crucial effect on the reliability and cost of EV. The heat generation model, the methods of cooling and air flow in the battery are investigated. This paper presents the simulation model using MATLAB/SIMULINK for analyzing the reliability of electric vehicles. The model takes into account the variation of driving cycles, thermal stress, thermal cycling and fault analysis. This model is discussed in detail and the result of reliability estimation based on an electric vehicle is presented and analyzed. The results are verified experimentally with the working model of electric vehicle available in the laboratory. With this model and analysis, more accurate reliability prediction can be carried out by the designer.

Keywords

Electric Vehicle Driving cycle Reliability Thermal stress Fault analysis 

References

  1. Berthon A, Gustin F, Bendjedia M, Morelle J, Coquery G (2009) Inverter components reliability tests for hybrid electrical vehicles. In: Record of IEEE power electronics and motion control conference, pp 763–768Google Scholar
  2. Bierhoff M, Fuchs F (2004) Semiconductor losses in voltage source and current source IGBT converters based on analytical derivation. In: Record of IEEE power electronics specialists conference, pp 2836–2842Google Scholar
  3. Department of Defense (1991) Reliability prediction of electronic equipment. Technical Report, MIL-HDBK-217FGoogle Scholar
  4. Ehsani M, Gao Y, Emadi A (2009) Modern electric, hybrid electric, and fuel cell vehicles: fundamentals, theory, and design. Power electronics and applications series, 1st edn. CRC Press, Boca RatonGoogle Scholar
  5. Hirschmann D, Tissen D, Schroder S, De Doncker R (2007) Reliability prediction for inverters in hybrid electrical vehicles. IEEE Trans Power Electron 22:2511–2517CrossRefGoogle Scholar
  6. Hsu JS, Nelson SC, Jallouk PA et al (2005) Report on Toyota Prius motor thermal management. Oak Ridge National Laboratory, Technical Report, ORNL/TM-2005/33Google Scholar
  7. Leonhard W (2001) Control of electrical drives, 3rd edn. Springer, BerlinCrossRefGoogle Scholar
  8. Marchesoni M, Savio S (2005) Reliability analysis of a fuel cell electric city car. In: Record of European conference on power electronics and applications, pp 1–10Google Scholar
  9. Masrur M (2008) Penalty for fuel economy-system level perspectives on the reliability of hybrid electric vehicles during normal and graceful degradation operation. IEEE Syst J 2(4):476–483CrossRefGoogle Scholar
  10. Negarestani S, Ghahnavieh A, Mobarakeh A (2012) A study of the reliability of various types of the electric vehicles. In: Record of IEEE international electric vehicle conference, pp 1–6Google Scholar
  11. Qian K, Zhou C, Yuan Y, Allan M (2010) Temperature effect on electric vehicle battery cycle life in vehicle-to-grid applications. In: Record of China international conference on electricity distribution, pp 1–6Google Scholar
  12. Ranjbar A, Fahimi B (2010) Helpful hints to enhance reliability of DC DC converters in hybrid electric vehicle applications. In: Record of IEEE vehicle power and propulsion conference, pp 1–6Google Scholar
  13. Renken F, Ehbauer G, Karrer V, Knorr R, Ramminger S, Seliger N, Wolfgang E (2007) Reliability of high temperature inverters for HEV. In: Record of power conversion conference, pp 563–568Google Scholar
  14. Song Y, Wang B (2013) Survey on reliability of power electronic systems. IEEE Trans Power Electron 28(1):591–604CrossRefGoogle Scholar
  15. TR-332 Issue 6 (1997) Reliability prediction procedure for electronic equipment. Bell Communication Research, Inc., Technical Report, TR-332, Issue 6Google Scholar
  16. Union technique de L Electricite (2000) RDF 2000: Reliability data handbook. Technical Report, UTE C 20-810Google Scholar

Copyright information

© Society for Reliability and Safety (SRESA) 2019

Authors and Affiliations

  • Bharathi Sankar Ammaiyappan
    • 1
    Email author
  • Seyezhai Ramalingam
    • 1
  1. 1.Department of EEE, Renewable Energy Conversion LabSSN College of EngineeringChennaiIndia

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