Research Article
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Year 2021, Volume: 5 Issue: 1, 63 - 66, 31.03.2021
https://doi.org/10.30939/ijastech..823415

Abstract

References

  • [1] Osman A. (2006). Fatigue failure of a helical gear in a gearbox. Eng Fail Anal, 13, 1116–1125.
  • [2] Kovan V., Sekercioglu T. (2007). Pitting failure of truck spiral bevel gear. Eng Fail Anal, 14, 614–619.
  • [3] Park S., Lee L., Moon U., Kim D. (2010). Failure analysis of a planetary gear carrier of 1200HP transmission. Eng Fail Anal, 17, 521–52.
  • [4] Yu Z., Xu X., (2010). Failure investigation of a truck diesel engine gear train consisting of crankshaft and camshaft gears. Eng Fail Anal, 17, 537–545.
  • [5] Rivera R., Chiminelli A., Gómez C., Núñez J.L. (2010). Fatigue failure analysis of a spring for elevator doors. Eng Fail Anal, 17, 731–738.
  • [6] Peng C., Liu, Z., Zhu W. (2011). Failure analysis of a gear tooth facture of a rolling mill decelerator. Eng Fail Anal, 18, 25–35.
  • [7] Heyes A.M. (1998). Automotive component failures. Eng Fail. Anal., 2, 129–141.
  • [8] Bayrakceken H., Tasgetiren S., Yavuz İ. (2007). Two cases of failure in the power transmission system on vehicles: A universal joint yoke and a drive shaft. Eng Fail Anal, 14, 716-724
  • [9] Yavuz İ., Bayrakçeken H. (2011). Failure Analysis of A Rear Axle Shaft of An Automobile. Electronic Journal of Vehicle Technologies, 3, 11-19
  • [10] Matveb.com/search/datasheet.aspx?matguid=00c8d94116c a4b32865b7999b0241cc6&n=1&ckck=1-2020
  • [11] Barker V. M., Johnson W. S., Adair B. S., Antolovich S. D., Staroselsky A. (2013). Load and temperature interaction modeling of fatigue crack growth in a Ni-base superalloy. International Journal of Fatigue, 52, 95–105.
  • [12] Liu H., Bao R., Zhang J., Fei B. (2014). A creep–fatigue crack growth model containing temperature and interactive effects. International Journal of Fatigue, 59, 34–42.
  • [13] Mahobia G.S., Paulose N., Mannan S.L., Sudhakar R.G., Chattopadhyay K., Srinivas N. C. S., Singh V. (2014). Ef-fect of hot corrosion on low cycle fatigue behavior of sup-eralloy IN718. Int. Journal of Fatigue, 59, 272–281.
  • [14] Li Y.D., Liu C.B., Xu N., Wu X.F., Guo W.M., Shi J.B., (2013). A failure study of the railway rail serviced for heavy cargo trains. Case Studies in Engineering Failure Analysis, 1, 243–248.
  • [15] Hormaza W., Mateus L., Maranon A. (2009). Failure anal-ysis of a cylinder sleeve from a turbocharged diesel engine, Engineering Failure Analysis, 16, 1355–1365
  • [16] Bayrakceken H., Tasgetiren S., Aksoy F. (2007). Failures of single cylinder diesel engines crank shafts, Engineering Failure Analysis, 14, 725–730.
  • [17] Pantazopoulos G., Vazdirvanidis A., Rikos A., Toulfatzis A. (2014). Analysis of abnormal fatigue failure of forklift forks. Case Studies in Engineering Fail. Analysis, 2, 9–14.
  • [18] Failure Analysis and Prevention, ASM Hand Book – 4, Volume:11, Chapter 5
  • [19] Chen B. S., Zhao Y. X., Yang B. (2012). Scale-induced effects on fatigue properties of a cast steel for bogie frames of China railway rolling wagons. Int. Jour. of Fat., 35, 45–55.
  • [20] Zambrano O. A., Coronado J. J., Rodrı´guez S. A., (2014). Failure analysis of a bridge crane shaft. Case Studies in En-gineering Failure Analysis, 2, 25–32

Failure Analysis of Distributor Gear

Year 2021, Volume: 5 Issue: 1, 63 - 66, 31.03.2021
https://doi.org/10.30939/ijastech..823415

Abstract

This study experimentally and theoretically investigated the fracture damage on the distributor gear of a front-wheel drive automobile. The experimental stud-ies initially analyzed the fracture surfaces of the gear in the scanning electron microscope (SEM). Subsequently, microstructure analysis and mechanical tests were performed. In the theoretical study, on the other hand, static analyses were performed using the finite element method on the ANSYS software program. Static analyses revealed equivalent stresses on the piece and determined its criti-cal regions. Finally, the theoretical and experimental studies were compared with literature data. As a result, the occurrence of a ductile fracture was observed and it was determined to be the area where the most critical fracture occurred.

References

  • [1] Osman A. (2006). Fatigue failure of a helical gear in a gearbox. Eng Fail Anal, 13, 1116–1125.
  • [2] Kovan V., Sekercioglu T. (2007). Pitting failure of truck spiral bevel gear. Eng Fail Anal, 14, 614–619.
  • [3] Park S., Lee L., Moon U., Kim D. (2010). Failure analysis of a planetary gear carrier of 1200HP transmission. Eng Fail Anal, 17, 521–52.
  • [4] Yu Z., Xu X., (2010). Failure investigation of a truck diesel engine gear train consisting of crankshaft and camshaft gears. Eng Fail Anal, 17, 537–545.
  • [5] Rivera R., Chiminelli A., Gómez C., Núñez J.L. (2010). Fatigue failure analysis of a spring for elevator doors. Eng Fail Anal, 17, 731–738.
  • [6] Peng C., Liu, Z., Zhu W. (2011). Failure analysis of a gear tooth facture of a rolling mill decelerator. Eng Fail Anal, 18, 25–35.
  • [7] Heyes A.M. (1998). Automotive component failures. Eng Fail. Anal., 2, 129–141.
  • [8] Bayrakceken H., Tasgetiren S., Yavuz İ. (2007). Two cases of failure in the power transmission system on vehicles: A universal joint yoke and a drive shaft. Eng Fail Anal, 14, 716-724
  • [9] Yavuz İ., Bayrakçeken H. (2011). Failure Analysis of A Rear Axle Shaft of An Automobile. Electronic Journal of Vehicle Technologies, 3, 11-19
  • [10] Matveb.com/search/datasheet.aspx?matguid=00c8d94116c a4b32865b7999b0241cc6&n=1&ckck=1-2020
  • [11] Barker V. M., Johnson W. S., Adair B. S., Antolovich S. D., Staroselsky A. (2013). Load and temperature interaction modeling of fatigue crack growth in a Ni-base superalloy. International Journal of Fatigue, 52, 95–105.
  • [12] Liu H., Bao R., Zhang J., Fei B. (2014). A creep–fatigue crack growth model containing temperature and interactive effects. International Journal of Fatigue, 59, 34–42.
  • [13] Mahobia G.S., Paulose N., Mannan S.L., Sudhakar R.G., Chattopadhyay K., Srinivas N. C. S., Singh V. (2014). Ef-fect of hot corrosion on low cycle fatigue behavior of sup-eralloy IN718. Int. Journal of Fatigue, 59, 272–281.
  • [14] Li Y.D., Liu C.B., Xu N., Wu X.F., Guo W.M., Shi J.B., (2013). A failure study of the railway rail serviced for heavy cargo trains. Case Studies in Engineering Failure Analysis, 1, 243–248.
  • [15] Hormaza W., Mateus L., Maranon A. (2009). Failure anal-ysis of a cylinder sleeve from a turbocharged diesel engine, Engineering Failure Analysis, 16, 1355–1365
  • [16] Bayrakceken H., Tasgetiren S., Aksoy F. (2007). Failures of single cylinder diesel engines crank shafts, Engineering Failure Analysis, 14, 725–730.
  • [17] Pantazopoulos G., Vazdirvanidis A., Rikos A., Toulfatzis A. (2014). Analysis of abnormal fatigue failure of forklift forks. Case Studies in Engineering Fail. Analysis, 2, 9–14.
  • [18] Failure Analysis and Prevention, ASM Hand Book – 4, Volume:11, Chapter 5
  • [19] Chen B. S., Zhao Y. X., Yang B. (2012). Scale-induced effects on fatigue properties of a cast steel for bogie frames of China railway rolling wagons. Int. Jour. of Fat., 35, 45–55.
  • [20] Zambrano O. A., Coronado J. J., Rodrı´guez S. A., (2014). Failure analysis of a bridge crane shaft. Case Studies in En-gineering Failure Analysis, 2, 25–32
There are 20 citations in total.

Details

Primary Language English
Subjects Material Production Technologies
Journal Section Articles
Authors

İbrahim Yavuz 0000-0002-4480-2342

Publication Date March 31, 2021
Submission Date November 9, 2020
Acceptance Date February 3, 2021
Published in Issue Year 2021 Volume: 5 Issue: 1

Cite

APA Yavuz, İ. (2021). Failure Analysis of Distributor Gear. International Journal of Automotive Science And Technology, 5(1), 63-66. https://doi.org/10.30939/ijastech..823415
AMA Yavuz İ. Failure Analysis of Distributor Gear. IJASTECH. March 2021;5(1):63-66. doi:10.30939/ijastech.823415
Chicago Yavuz, İbrahim. “Failure Analysis of Distributor Gear”. International Journal of Automotive Science And Technology 5, no. 1 (March 2021): 63-66. https://doi.org/10.30939/ijastech. 823415.
EndNote Yavuz İ (March 1, 2021) Failure Analysis of Distributor Gear. International Journal of Automotive Science And Technology 5 1 63–66.
IEEE İ. Yavuz, “Failure Analysis of Distributor Gear”, IJASTECH, vol. 5, no. 1, pp. 63–66, 2021, doi: 10.30939/ijastech..823415.
ISNAD Yavuz, İbrahim. “Failure Analysis of Distributor Gear”. International Journal of Automotive Science And Technology 5/1 (March 2021), 63-66. https://doi.org/10.30939/ijastech. 823415.
JAMA Yavuz İ. Failure Analysis of Distributor Gear. IJASTECH. 2021;5:63–66.
MLA Yavuz, İbrahim. “Failure Analysis of Distributor Gear”. International Journal of Automotive Science And Technology, vol. 5, no. 1, 2021, pp. 63-66, doi:10.30939/ijastech. 823415.
Vancouver Yavuz İ. Failure Analysis of Distributor Gear. IJASTECH. 2021;5(1):63-6.


International Journal of Automotive Science and Technology (IJASTECH) is published by Society of Automotive Engineers Turkey

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