DYNAMIC STRESS ANALYSIS OF SPUR-MESH GEAR TOOTH USING FEM BASED ALGORITHM

Author’s Name : T.VADIVELU

Volume 03 Issue 02  Year 2016  ISSN No:  2349-3828  Page no: 23-27

Abstract:

Gears are the most common means for transmitting the power in the modern dynamic machines. Gears are used to change the speed and power ratio as well as direction between an input and output of the line shaft. The constant pressure to build less expensive, quieter running, light weight, and more powerful machinery has resulted in a steady improvement of gear designs. Despite having high cost, complicated manufacturing, need of precise alignment of shafts and lubrication, the gear drives are preferred over other power transmission drives. One of the important reasons of preference being that of efficiency which is very high in gear drives, even up to 99% in case of spur gears. Spur gears are the most simplest of the gear drives having teeth cut parallel to the axis of the shaft. In the present study a “spur gear is investigated using a two dimensional finite element model”. The two dimensional model offers significant advantages for dynamic gear analysis. The gear teeth are analyzed for different operating speeds. Displacements, stress distributions and strains were investigated using finite element analysis software “ANSYS 12 Mechanical APDL”. The emphasis of this study was to predict the displacements, strains and stress distributions for a spur gear tooth. The gear tooth model was generated in ANSYS 12 APDL package. Various mesh configurations were obtained in the meshing section of the package. The effect of rotational speed on dynamic stress was also studied and compared with the work of reference [4] for the same specifications. The obtained results show a good degree of agreement with the results of reference.

Keywords:

Spur Gear,ANSYS 12 ,APDL, Bending Stress, Finite Element Modeling.

References:

1. S. Shinde, A. Nikam and T. Mulla, “Static analysis of spur gear using finite element analysis,” Journal of Me-chanical and Civil Engineering, 2278-1684, pp. 26-31.
2. S. Tiwari and U. Joshi, “Stress analysis of mating in-volute spur gear teeth,” International Journal of Engi-neering Research and Technology, vol. 1, no. 9, 2012.
3. V. Bhandari, “Design of machine elements,” New Delhi: Tata McGraw-Hill, 2010.
4. T. Rani and T. Khalandar, “Spur Gear,” International Journal of computational Engineering Research, vol. 3 no. 11, pp. 7-12, 2013.
5. A. Hassan, G. Thanigaiyarasu, and V. Ramamurti, “Ef-fect of natural frequency and rotational speed on dy-namic stress in spur gear,” International Scholarly and Scientific Research & Innovation, vol. 2, no. 12, 2008
6. L. Wilcox and W. Coleman, “Application of Finite Elements to the Analysis of Gear Tooth Stresses,” Journal of Engineering for Industry, vol. 95, no. 4, p. 1139, 1973.
7. V. Ramamurti, N. Vijayendra and C. Sujatha, “Static and dynamic analysis of spur and bevel gears using FEM,” Mechanism and Machine Theory, vol. 33, no. 8, pp. 1177-1193, 1998
8. Z. Chen and Y. Shao, “Dynamic simulation of spur gear with tooth root crack propagating along tooth width and crack depth,” Engineering Failure Analysis, vol. 18, no. 8, pp. 2149-2164, 2011.
9. V. Ramamurti, N. Vijayendra and C. Sujatha, “Static and dynamic analysis of spur and bevel gears using FEM,” Mechanism and Machine Theory, vol. 33, no. 8, pp. 1177-1193, 1998.