Application of Grey Relational Analysis Along with Principal Component Analysis for Multi-Response Optimization of Hard Turning
 |
International Journal of Engineering Trends and Technology (IJETT) | 
|
| © 2016 by IJETT Journal | ||
| Volume-38 Number-5 |
||
| Year of Publication : 2016 | ||
| Authors : Suha K. Shihab, Zahid A. Khan, Arshad Noor Siddiquee |
||
| DOI : 10.14445/22315381/IJETT-V38P243 |
Citation
Suha K. Shihab, Zahid A. Khan, Arshad Noor Siddiquee"Application of Grey Relational Analysis Along with Principal Component Analysis for Multi-Response Optimization of Hard Turning", International Journal of Engineering Trends and Technology (IJETT), V38(5),238-245 August 2016. ISSN:2231-5381. www.ijettjournal.org. published by seventh sense research group
Abstract
Investigation on the effect of cutting speed, feed
rate, depth of cut and different cutting conditions on the
machining force components and surface roughness during
hard turning of AISI 52100 has been presented in this paper.
Nine turning experiments as per Taguchi’s standard L9
orthogonal array were performed on AISI 52100 hard alloy
steel using a CNC lathe machine and cutting force
component as well as surface roughness were measured.
Subsequently, multi-response optimization was performed by
employing grey relational and principal component
analyses. The results revealed that grey relational analysis
along with the principal component analysis is a simple as
well as effective method for solving the multi-response
optimization problem and it provides the optimal
combination of hard turning parameters. Further, the
analysis of variance (ANOVA) was also employed to identify
the most significant parameter based on percentage of
contribution of each machining parameter.
References
[1] Y. Huang, Y.K. Chou, and S.Y. Liang. “CBN tool wear in
hard turning: a survey on research progresses,” Int J Adv
Manuf Technol. Vol.35, 443-53, 2007.
[2] H. Aouici, M.A. Yallese, K. Chaoui, T. Mabrouki, and Rigal
J-F. “Analysis of surface roughness and cutting force
components in hard turning with CBN tool: prediction model
and cutting conditions optimization,” Measurement. Vol.45,
344-53, 2012.
[3] Manna, A., and Salodkar, S. “Optimization of machining
conditions for effective turning of E0300 alloy steel,”
journal of materials processing technology. 203, 147-153,
2008.
[4] P. Chinnaiyan, and A. K. Jeevanantham. “Multi-Objective
Optimization of Single Point Incremental Sheet Forming of
AA5052 using Taguchi based Grey Relational Analysis
Coupled with Principal Component Analysis,” International
Journal of Precision Engineering and Manufacturing. Vol.15,
2309-2316, 2014
[5] K. Yang. “Improving automotive dimensional quality by
using principal component analysis,” Qual Reliab Eng Int.
vol.12, 1401-409, 1996.
[6] C-T. Su, L-I. Tong. “Multi-response robust design by
principal component analysis,” Total Qual Manage. Vol.8,
no.6, 409-416, 1997
[7] L-I. Tong, and C.H. Wang. “Multi-response optimization
using principal component analysis and grey relational
analysis,” Int J Ind Eng, vol. 9, no.4, 343-350, 2002.
[8] C.-H. Wang. “Dynamic multi-response optimization using
principal component analysis and multiple criteria evaluation
of the grey relation model,” Int J Adv Manuf Technol. Vol.
32, 617-624 , 2007.
[9] D. Philip Selvaraj, P Chandramohan., and M. Mohanraj.
“Optimization of surface roughness, cutting force and tool
wear of nitrogen alloyed duplex stainless steel in a dry
turning process using Taguchi method,” Measurement. vol.
49, 205-215, 2014.
[10] E. Kuram, and B. Ozcelik. “Multi-objective optimization
using Taguchi based grey relational analysis for micromilling
of Al 7075 material with ball nose end mill,”
Measurement. Vol.46, 1849-1864, 2013.
[11] T. Kivak. “Optimization of surface roughness and flank wear
using the Taguchi method in milling of Hadfield steel with
PVD and CVD coated inserts,” Measurement.vol.50, 19-28,
2014.
[12] S. Karabulut. “Optimization of surface roughness and cutting
force during AA7039/Al2O3 metal matrix composites
milling using neural networks and Taguchi method,”
Measurement. Vol.66, 139-149, 2015.
[13] N. Masmiati, and A. A.D. Sarhan. “Optimizing cutting
parameters in inclined end milling for minimum surface
residual stress -Taguchi approach,” Measurement. Vol.60,
267-275,2015.
[14] R. K. Pandey, and S.S. Panda, “Multi-performance
optimization of bone drilling using Taguchi method based on
membership function,” Measurement. Vol.59, 9-13, 2015.
[15] I. Asilturk, and H. Akkus. “Determining the effect of cutting
parameters on surface roughness in hard turning using the
Taguchi method,” Measurement. vol.44, 1697-1704, 2011.
[16] Jagadish, and A. Ray. “Optimization of process parameters
of green electrical discharge machining using principal
component analysis (PCA),” Int J Adv Manuf Technol. Vol.
1-13. [DOI 10.1007/s00170-014-6372-8], 2015.
[17] S.K. Shihab, Z. A. Khan, A. Mohammad, and A. N.
Siddiquee. “Investigation of Surface Integrity during Wet
Turning of Hard Alloy Steel,” Int. J. Machining and
Machinability of Materials. Vol. 16, no.1, 22-37, 2014.
[18] A. N. Siddiquee, Z. A. Khan, and Z. Mallick. “Grey
relational analysis coupled with principal component analysis
for optimisation design of the process parameters in in-feed
centreless cylindrical grinding,” Int J Adv Manuf Technol.
Vol.46, no.9, 983-992, 2010.
[19] Z.C. Lin, and C.Y. Ho. “Analysis and application of grey
relation and ANOVA in chemical-mechanical polishing
process parameters,” Int J Adv Manuf Technol. Vol.21: 10-
14, 2003.
[20] K. Pearson. “On lines and planes of closest fit to systems of
points in space,” Phil Manag Ser. Vol.62, 559-572, 1901.
[21] H. Hotelling. “Analysis of a complex of statistical variables
into principal components,” J Educ Psychol. Vol.24, 417-
441, 1993.
[22] F-C. Chen, Y-F. Tzeng, M-H. Hsu, and W-R. Chen.
“Combining Taguchi Method, Principal Component Analysis
and Fuzzy Logic to the Tolerance Design of A Dual-Purpose
Six-Bar Mechanism,” Transactions of the Canadian Society
for Mechanical Engineering. Vol. 34, no.2, 277-293, 2010.
Keywords
Hard turning, Optimization, Taguchi
method, Grey relational analysis, Principal
component analysis.