Life Prediction of Spur Gear Under Fully Reversed Loading Using Total Life Approach and Crack-Initiation Method in FEM

Purushottam Karthik Janaswamy; J. Rangaraya Chowdary; C.tara Sasanka; Sameer Kumar Devarakonda

doi:10.29002/asujse.498344

Research Article

Year 2019, Volume: 3 Issue: 2, 82 - 98, 30.12.2019

Purushottam Karthik Janaswamy , J. Rangaraya Chowdary C.tara Sasanka Sameer Kumar Devarakonda

https://doi.org/10.29002/asujse.498344

Cited By: 2

Abstract

References

[1] J.P. Karthik, T.R. Sai, S.S. Praneeth, International Journal of Advanced Design and Manufacturing Technology 9(3) (2016) 49-56.
[2] S.G.A. Hasan, G.S. Kumar, S.S. Fatima, International Journal of Engineering Sciences & Research Technology 4(7) (2015) 523-534.
[3] X. Zheng, International Journal of Fatigue 23(9) (2001) 751-766.
[4] D.S. Kumar, K.N.S. Suman, International Journal of Engineering and Manufacturing (IJEM) 4(2) (2014) 31-41.
[5] J.P. Karthik, D.M. Kumar, J.R. Chowdary, International Journal of Applied Science and Engineering 13(1) (2015) 69-79.
[6] J.P. Karthik, K.L. Chaitanya, C.T. Sasanka, International Journal of Advanced Science and Technology 46 (2012) 143-156.
[7] S-C. Hwang, J-H. Lee, D-H. Lee, S-H. Han, K-H. Lee, Mathematical and Computer Modelling 57(1-2) (2013) 40-49.
[8] Y-L. Lee, J. Pan, R. Hathaway, M. Barkey, Fatigue testing and analysis, theory and practice, UK: Elsevier Butterworth-Heinemann (2005).
[9] A. Kalani, R. Jain, International Journal of Mechanical Engineering and Technology (IJMET) 6(5) (2015) 82-91.
[10] S.S. Manson, Experimental Mechanics 5(4) (1965) 193-226.
[11] J.D. Morrow, Fatigue Properties of Metal Fatigue Design Handbook, Society of Automotive Engineers (1968). [12] C.S. Bandara, S.C. Siriwardane, U.I. Dissanayake, R. Dissanayake, International Journal of Materials, Mechanics and Manufacturing 1(3) (2013) 256-260.
[13] K.N. Smith, P. Watson and T.H. Topper, Journal of Materials, JMLSA 5(4) (1970) 767-778.
[14] S.D. Galande, R.J. Patil, IPASJ International Journal of Mechanical Engineering (IIJME) 2(7) (2014) 25-31.

Life Prediction of Spur Gear Under Fully Reversed Loading Using Total Life Approach and Crack-Initiation Method in FEM

Year 2019, Volume: 3 Issue: 2, 82 - 98, 30.12.2019

Purushottam Karthik Janaswamy , J. Rangaraya Chowdary C.tara Sasanka Sameer Kumar Devarakonda

https://doi.org/10.29002/asujse.498344

Cited By: 2

Abstract

This paper focus
on the comparative fatigue life prediction of spur gears based on finite
element method under fully reversed load conditions. Gears being the vital
components of any automobiles, power generation systems and in heavy machinery
industries, need to have good fatigue properties such as fatigue life,
endurance limit and fatigue strength for better life and performance of the
equipment or machinery. Therefore, the main aim of this study is to simulate
fully reversed loading conditions in the fatigue life prediction on general
gear materials, SAE materials like ALSI4027, SAE1045-450-QT, SAED 5506 and SAE5160-825-QT. The finite element method (FEM) has been
performed on the gear models to observe the distribution of stress and damage.
A comparison was made on the fatigue life and the results were analyzed. Finally,
conclusions were given.

Keywords

Fatigue life, constant amplitude proportional loading, Spur gear, FEM

References

[1] J.P. Karthik, T.R. Sai, S.S. Praneeth, International Journal of Advanced Design and Manufacturing Technology 9(3) (2016) 49-56.
[2] S.G.A. Hasan, G.S. Kumar, S.S. Fatima, International Journal of Engineering Sciences & Research Technology 4(7) (2015) 523-534.
[3] X. Zheng, International Journal of Fatigue 23(9) (2001) 751-766.
[4] D.S. Kumar, K.N.S. Suman, International Journal of Engineering and Manufacturing (IJEM) 4(2) (2014) 31-41.
[5] J.P. Karthik, D.M. Kumar, J.R. Chowdary, International Journal of Applied Science and Engineering 13(1) (2015) 69-79.
[6] J.P. Karthik, K.L. Chaitanya, C.T. Sasanka, International Journal of Advanced Science and Technology 46 (2012) 143-156.
[7] S-C. Hwang, J-H. Lee, D-H. Lee, S-H. Han, K-H. Lee, Mathematical and Computer Modelling 57(1-2) (2013) 40-49.
[8] Y-L. Lee, J. Pan, R. Hathaway, M. Barkey, Fatigue testing and analysis, theory and practice, UK: Elsevier Butterworth-Heinemann (2005).
[9] A. Kalani, R. Jain, International Journal of Mechanical Engineering and Technology (IJMET) 6(5) (2015) 82-91.
[10] S.S. Manson, Experimental Mechanics 5(4) (1965) 193-226.
[11] J.D. Morrow, Fatigue Properties of Metal Fatigue Design Handbook, Society of Automotive Engineers (1968). [12] C.S. Bandara, S.C. Siriwardane, U.I. Dissanayake, R. Dissanayake, International Journal of Materials, Mechanics and Manufacturing 1(3) (2013) 256-260.
[13] K.N. Smith, P. Watson and T.H. Topper, Journal of Materials, JMLSA 5(4) (1970) 767-778.
[14] S.D. Galande, R.J. Patil, IPASJ International Journal of Mechanical Engineering (IIJME) 2(7) (2014) 25-31.

There are 13 citations in total.

Details

Primary Language	English
Subjects	Engineering
Journal Section	Research Article
Authors	Purushottam Karthik Janaswamy 0000-0002-4495-2789 J. Rangaraya Chowdary C.tara Sasanka Sameer Kumar Devarakonda
Publication Date	December 30, 2019
Submission Date	December 17, 2018
Acceptance Date	November 11, 2019
Published in Issue	Year 2019Volume: 3 Issue: 2

Cite

APA	Janaswamy, P. K., Chowdary, J. R., Sasanka, C., Devarakonda, S. K. (2019). Life Prediction of Spur Gear Under Fully Reversed Loading Using Total Life Approach and Crack-Initiation Method in FEM. Aksaray University Journal of Science and Engineering, 3(2), 82-98. https://doi.org/10.29002/asujse.498344