Analysis of axle shaft fatigue failure and anti-fatigue system design

• Autorzy: İrsel G.

Identyfikatory

DOI

10.12913/22998624/75887

• Języki publikacji: EN

Abstrakty

EN

In this study, an axle shaft subjected to static deformation and fatigue damage was considered by using computer-aided engineering. This shaft system was modeled with CATIA and subjected to dynamic fatigue analyses with Ansys workbench. The damaged fracture surfaces of the shaft have been examined. Thus, the fatigue and damage was revealed in greater detail. For the present system, a design with a minimum cost, short production process, minimum weight was sought together with methodical construction principles. By means of CATIA and ANSYS, the product development design with reasonable tension and deformation values was formed for endless life fatigue. A design was produced in a short space of time with the help of 2D CATIA drawings and field tests were carried out. The design was used through 560.000 cycles and damage was not observed.

Słowa kluczowe

EN

CATIA; ANSYS; fatigue analysis; redesign; shaft fatigue; product development

• Wydawca: Lublin University of Technology ; Polish Society of Ecological Engineering (PTIE), Branch of PTIE in Lublin
• Czasopismo: Advances in Science and Technology. Research Journal
• Rocznik: 2017
• Tom: Vol. 11, no 3
• Strony: 150--163
• Opis fizyczny: Bibliogr. 22 poz., fig., tab.

Twórcy

autor

İrsel G.

• Trakya University, Faculty of Engineering, Mechanical Engineering Department, 22180, Edirne, Turkey

Bibliografia

• 1. Osi O.: Fatigue Failure Of A Rear Axle Shaft Of An Automobile, Engineering Failure Analysis, 13, 2006, 1293-1302.
• 2. Basnet A., Rajgadia S., Karki A., Das D., Jaiswal P., Jaiswal R., Jha A.R., Barman R.N.: Design And Analysis Of Solid Crank Shaft Using Catia And Ansys Workbench, International Journal Of Advanced Research İn Biology Engineering Science And Technology, 2, 2016, 86-99.
• 3. Budynas R.G., Nisbett J. K.: Shigley’s Mechanical Engineering Design, Eighth Edition in SI Units, 2016.
• 4. Cavdar K., Babalik C.F.: Methodic In Designing Hydraulic Systems Using Construction Principles, Iii. National Hydraulic Pneumatic Congress And Exhibition, 2003, 377-387.
• 5. Espadafor F.J., Villanueva J.B., García M.T.: Analysis Of A Diesel Generator Crankshaft Failure, Engineering Failure Analysis, 16, 2009, 2333–2341.
• 6. Fonte M., Reis L., Romeiro F., Li B., Freitas M,: The Effect Of Steady Torsion On Fatigue Crack Growth In Shafts, International Journal Of Fatigue, 28, 2016, 609-617.
• 7. Goksenli A., Eryurek I.B.: Failure Analysis Of An Elevator Drive Shaft, Engineering Failure Analysis, 16, 2009, 1011-1019.
• 8. Hasan S.G.A., Kumar G.S., Fatima S.S.: Fınıte Element Analysıs And Fatıgue Analysıs Of Spur Gear Under Random Loadıng, Fınıte Element Analysıs And Fatıgue Analysıs Of Spur Gear Under Random Loadıng, 4, 2015, 523-534.
• 9. Jha A., Jaiswal R., Karki A., Basnet A., Jaiswal P., Rajgadia S., Das D., Barman R.N.: Design And Finite Element Analysis Of Knuckle Joint Using Catıa And Ansys Workbench, International Journal Of Research In Mechanical Engineering, 4, 2016, 1-5.
• 10. Kutay G.: http://www.guven-kutay.ch/
• 11. Li W., Yan Q., Xue J.: Analysis Of A Crankshaft Fatigue Failure, Engineering Failure Analysis, 55, 2015, 139-147.
• 12. Panda S., Behera D.N., Tripathy S.N.: Modelıng And Structural Analysıs Of Alloy Wheel Usıng Ansys, Internatıonal Journal Of Engıneerıng Scıences & Research Technology, 5, 3, 2016, 467-474.
• 13. Panda S.S., Gurung J., Chatterjee U.K., Sahoo S.: Modelıng-And-Fatıgue-Analysıs-Of- Automotıve- Wheel-Rım, Internatıonal Journal Of Engıneerıng Scıences & Research Technology, 5, 2016, 428-435.
• 14. Parkash O., Gupta V., Mittal V.: Optimizing The Design Of Connecting Rod Under Static And Fatigue Loading, International Journal Of Research İn Management, Science & Technology, 1, 2013, 39-43.
• 15. Prasad T.S., Krishnaiah T., Iliyas J.M., Reddy M.J.: A Review On Modeling And Analysis Of Car WheelRim Using Catıa & Ansys, International Journal Of Innovative Science And Modern Engineering (Ijısme), 2, 2014, 1-5.
• 16. Shelke S.S., Dhamejani C.L., Gadhave A.S.: Modeling And Analysis Of The Crankshaft Using Ansys Software, International Journal Of Engineering Science And Computing, 6, 2016, 6796-6800.
• 17. Singh A, Soni V., Singh A.: Structural Analysis of Ladder Chassis for Higher Strength, International Journal of Emerging Technology and Advanced Engineering, 4, 2014, 253-259.
• 18. Talikoti B.S., Kurbet S.N., Kuppast V.V.: Statıc Structural Analysıs Of 2-Cylınder Crankshaft Usıng Ansys, International Journal For Technological Research In Engineering, 3, 2015, 242-245.
• 19. Thriveni K., Chandraiah B.J.: Modeling And Analysis Of The Crankshaft Using Ansys Software, International Journal Of Computational Engineering Research, 3, 2013, 84-89.
• 20. Vogwell J.: Analysıs Of A Vehıcle Wheel Shaft Faılure, Engineering Failure Analysis, 5, 1998, 2071-2077.
• 21. Yao W., Ye B., Zheng L.: A Verification Of The Assumption Of Anti-Fatigue Design, International Journal Of Fatigue, 23, 2001, 271-277.
• 22. Zangeneh S., Ketabchi M., Kalaki A.: Fracture Failure Analysis Of Aısı 304l Stainless Steel Shaft, Engineering Failure Analysis, 36, 2014, 155-165.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017)