Failure Mode and Effect Analysis a Tool for Reliability Evaluation: Review



Abstract Views
949

Downloads
625

Citations

Share

##plugins.themes.bootstrap3.article.sidebar##

Submitted Feb 28, 2018
Published Apr 30, 2018
10.24018/ejeng.2018.3.4.636

Abstract viewed = 949 times

Table of Contents

##plugins.themes.bootstrap3.article.main##

The purpose of safety designing is generally not on cost, but rather on saving life and nature, and consequently bargains just with specific risky system failure modes. High reliability levels are the consequence of good designing, scrupulousness and dependably never the aftereffect of re-dynamic failure management. Failure mode and effect analysis (FMEA) is a helpful technique analyzing engineering system reliability. The study focused on the use of FMEA technique to analyze the reliability of engineering equipment or components in selected areas such as: Wind Turbine component, Manufacturing Industries, Medical field and in evaluating the performances of Robots in different fields. The study showed the importance of FMEA as used widely in analyzing engineering equipment with regards to reliability.

Keywords: FMEA Reliability Failure Mode Review Engineering and Safety

Downloads

Download data is not yet available.

References

  1. A. Hoseynabadi, P. J Oraee, and P. J. Tavner. 2010. “Failure Modes and Effects Analysis (FMEA) for Wind lines.” International Journal of Electrical Power and Energy Systems 2010., 32(7):817–24.
     Google Scholar
  2. S. A Afolalu, S.B Adejuyigbe, O.R Adetunji. Impacts of temperature and holding time on wear of high speed steel cutting tools. International Journal of Scientific & engineering Research, Volume 6, Issue 5, 2015., 905-909’
     Google Scholar
  3. S. A. Afolalu, S.B., Adejuyigbe, O.R Adetunji. and O.I Olusola. Production of Cutting Tools from Recycled Steel with Palm Kernel Shell as Carbon Additives. International Journal of Innovation and Applied Studies, 12(1), 2015 p.110.
     Google Scholar
  4. I. Veza, B. Bilic, “An Integrated Lean Approach to Failure Mode and Effect Analysis (PFMEA): A Case Study from Automotive Industry.” Advances in Production Engineering & Management, 2016. 11:355–65.
     Google Scholar
  5. Chin, Ying-ming Wang, Gary Ka, Kwai Poon, and Jian-bo Yang. “Failure Mode and Effects Analysis by Data Envelopment Analysis.” Decision Support Systems 48(1): 2009. 246–56.
     Google Scholar
  6. Jui-sheng and Wan-ting Tu, “Failure Analysis and Risk Management of a Collapsed Large Wind Turbine Tower.” Engineering Failure Analysis 2011. 18(1):295–313.
     Google Scholar
  7. K. Kadir and Metin Celik. “Application of Failure Modes and Effects Analysis to Main Engine Crankcase Explosion Failure On-board Ship.” Safety Science 2013. 51(1):6–10.
     Google Scholar
  8. E.Y. Salawu., I.P Okokpujie., S.A Afolalu, Ajayi, O.O. J. Azeta 2018. Investigation of Production Output for Improvement. International Journal of Mechanical and Production Engineering Research and Development, 8(1), 2018, pp.915-922
     Google Scholar
  9. G. H. Simon Watson, Peter Tavner, and Jiangping Xiang. “Reliability Analysis for Wind Turbines with Incomplete Failure Data Collected from after the Date of Installation.” Reliability Engineering and System Safety 2009. 94:1057–63.
     Google Scholar
  10. H. A. Ali Siadat, Jean-yves Dantan, and Patrick Martin, “Robotics and Computer-Integrated Manufacturing Conceptual Process Planning – an Improvement Approach Using QFD,FMEA, and ABC Methods.” Robotics and Computer Integrated Manufacturing 2010. 26(4):392–401.
     Google Scholar
  11. D. Imran, V. Seppo, B., Pi A. K. Verma. 2014. “Functional Failure Modes Cause-Consequence Logic Suited for Mobile Robots Used at Scientific Facilities.” Reliability Engineering and System Safety 2014 129:10–18.
     Google Scholar
  12. O., Issn., P. Issn, and Mehta Gauravkumar Bharatbhai.. “Failure Mode and Effect Analysis of Repower 5M Wind Turbine.” International Journal of Advance Research in Engineering, Science& Technology 2015. 2(5):1–8.
     Google Scholar
  13. J. Kang, S. Liping, S. Hai, and W. Chunlin Wu. “Risk Assessment of Floating Off Shore Wind Turbine Based on Correlation-.” Ocean Engineering 2017. 017129(154):382–88.
     Google Scholar
  14. B. Karatop and S. Mehmet. 2017. “The Risk Analysis by Failure Mode and Effect Analysis (FMEA) and Fuzzy-FMEA of Supercritical Water Gasi Fi Cation System Used in the Sewage Sludge Treatment.” Journal of Environmental and Chemical Engineering 5:1261–68.
     Google Scholar
  15. S. Kiran., K.P Prajeeth, B. Sreejith, and M. Muralidharan. 2016. “Reliability Evaluation and Risk Based Maintenance in a Process Plant.” Procedia Technology 24:576–83.
     Google Scholar
  16. M.S Kirkire, S. R. Santosh and R.J Jagdish. “Risk Management in Medical Product Development Process Using Traditional FMEA and Fuzzy Linguistic Approach: A Case Study.” Journal of Industrial Engineering International 2012 11(4):595–611.
     Google Scholar
  17. K. P, Faisal et al. “Application of Fmea Method in a Manufacturing Organization Focused on Quality.” International Journal of Engineering and Innovative Technology 2015 4(7):64–70.
     Google Scholar
  18. E. Lillie, S. Peter S, and H. David, “Assessing the Value of a Lead-Free Solder Control Plan Using Cost-Based FMEA.” Microelectronics Reliability 55(6):969–79.
     Google Scholar
  19. Y. N. Maddahi,. H. Sepehri,. Ghorabi, and A. Maddahi. 2010. “Testing Robotic Manipulators: Improvement and Experience.” International Journal of Systems Applications, Engineering and Development 4(2).
     Google Scholar
  20. S. Mahmood, S.A Ami, 2014. “Application of FMEA and AHP in Lean Maintenance.” International Journal of Modern Engineering Science (September):61–73.
     Google Scholar
  21. R.A. Munteanu., D. Iudean, V. Zaharia, C. Muresan, and T. Cretu. Implementing a Failure Mode and Effect Analysis for Small and Medium Electric Motors Powered from Photovoltaic Panels. IFAC. 2013
     Google Scholar
  22. B. O. Orisanmi, S.A Afolalu, O.R Adetunji, O. R., Salawu, E. Y., & Okokpujie, I. P. (2017). Cost of Corrosion of Metallic Products in Federal University of Agriculture, Abeokuta. International Journal of Applied Engineering Research, 12(24), 14141-14147
     Google Scholar
  23. S. Pandey and Z. Xufang. “System Reliability Analysis of the Robotic Manipulator with Random Joint Clearances.” Mechanism and Machine Theory, 2012., 58:137–52.
     Google Scholar
  24. M. Shafiee and D. Fateme Dinmohammadi. “An FMEA-Based Risk Assessment Approach for Wind Turbine Systems: A Comparative Study of Onshore and Offshore. Energy” www.mdpi.com/journal/energies, 2013, 619–42.
     Google Scholar
  25. S.Sujan,r and F. Massimo. 2012. “Combining Failure Mode and Functional Resonance Analyses in Healthcare Settings.” www.dblue.it, 2012, 364–75.
     Google Scholar
  26. G. Indra, and T. Stenly. 2015. “Modified Failure Mode and Effect Analysis (FMEA) Model for Accessing the Risk of Maintenance Waste.” Procedia Manufacturing 4(Iess):23–29.
     Google Scholar
  27. A Tavner, H. Higgins, H. Arabian, H. Long, and Y. Feng. 2010. “Using an FMEA Method to Compare Prospective Wind Turbine Design Reliabilities.” European Wind Energy Conference (EWEC, 2010) (Ewec):1–10.
     Google Scholar
  28. U. Saluja, N. Barshah. 2012. “Information Risk Management Qualitative or Quantitative? Cross Industry Lessons from Medical and Financial Fields.” Systematics, Cybernetics and Informatics 2012. 10(3):54–59.
     Google Scholar
  29. S. A. Afolalu, E.Y Salawu, I.P. Okokpujie, A. A. Abioye., O.P. Abioye, M. Udo & O. M. Ikumapayi, Experimental Analysis of the Wear Properties of Carburized HSS (ASTM A600) Cutting Tool. International. Journal of Applied Engineering Research, 12(19), 2017, 8995-9003.
     Google Scholar