The use of the Taguchi-Grey based to optimize high ...

Materials Science Forum Vols. 505-507 (2006) pp 835-840 Online available since 2006/Jan/15 at www.scientific.net © (2006) Trans Tech Publications, Switzerland doi:10.4028/www.scientific.net/MSF.505-507.835

The use of the Taguchi-Grey based to optimize high speed end milling with multiple performance characteristics S. J. Hwanga

Y. L. Hwangb

B. Y. Leec

Department of Mechanical Design Engineering a ,b Department of Mechanical Manufacture Engineering c 64 Wen-Hua Road, Huwei Yunlin, Taiwan 63201 National Formosa University a

[email protected],

b

[email protected],

c

[email protected],

Keywords: Optimization; High speed machining; Tool life; Surface roughness Abstract. This paper presents a new approach for the optimization of the high speed machining (HSM) process with multiple performance characteristics based on the orthogonal array with the grey relational analysis has been studied. Optimal machining parameters can then be determined by the grey relational grade as the performance index. In this study, the machining parameters such as cutting speed, feed rate and axial depth of cut are optimized under the multiple performance characteristics including, tool life, surface roughness, and material removal rate(MMR). As shown experimental results, machining performance in the HSM process can be improved effectively through this approach. Introduction High speed machining technology is one of the important aspects of advanced manufacturing technology, it’s a cost effective method of machining hardened steels for moulds and dies to obtain a precise surface and high productivity [1-4]. Machining parameters such as cutting speed, feed rate, and depth of cut deeply affect both dimensional precision and surface quality, Therefore, an optimal selection of these machining parameters is very important in order to obtain high precision parts and to reduce the manual fit operations and the manufacturing cost. The grey relational analysis based on the grey system theory can be used to solve the complicated interrelationships among the multiple performance characteristics effectively [5-7]. As a result, optimization of the complicated multiple performance characteristics can be converted into optimization of a single grey relational grade. It is shown by this study that the use of the Taguchi method with the grey relational analysis can greatly simplify the optimization procedure for determining the optimal HSM parameters with the multiple performance characteristics in the HSM process. Experiment design Experiments were carried out on a high speed machining center (Papars B8) using 10mm diameter end mill with TiAlN coated for machining of SKD61 Tool Steel blocks. The cutting tools were 10 mm diameter four teeth corner-radius end-mill. The helical angle is 45 ° and the All rights reserved. No part of contents of this paper may be reproduced or transmitted in any form or by any means without the written permission of the publisher: Trans Tech Publications Ltd, Switzerland, www.ttp.net. (ID: 140.130.17.62-16/09/10,11:02:40)

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corner-radius is 0.5 mm. The schematic diagram of the experimental set-up is shown in Fig.1. According to Taguchi method, a robust design [8] and an L 27 (313 ) orthogonal array table was

chosen for the experiments (table 1). Three machining parameters are considered as controlling factors (Cutting speed, feed rate and axial depth of cut) and the radial depth of cut (Ae) was kept constant for all cutting tests at 0.5mm. The machining results after HSM process were evaluated in terms of the following measured machining performance: (1) Tool life (L, min); (2) surface roughness (Ra, µm ); and (3) metal removal rate (MRR, mm 3 ). The Tool life obtained with a flanked wear threshold of Vb≦0.2mm is used as a criterion (ISO 3002/1).The features of the flank wear land on the end-mill is shown in Fig.2. In Fig.2, the value of A、B、C、D is the end cutting edge of end-mill, the value of E、F、G、H is the peripheral cutting edge of end-mill. In the experiments, the flank wear land was measured by both cutting edges of the end-mill using a tool microscope (OLYMPUS STM5-BDZ). HKF UF440A-4ENSR-D10-R0.5 tools were used in the experiments.

Fig 1. The schematic of experimental setup of high speed machining

Fig 2. Features of the flank wear land on the end-mill.

Results and Analysis of Experiments

The first step of parameter design is to switch the quality characteristic to S/N ratio (signal-to-noise ratio). To obtain the optimal machining performance, the minimum surface roughness and the maximum tool life and material removal rate are desired. The first criterion selects the-smaller-the-better characteristic of the surface roughness. The calculation of the S/N ratio η ij for the ith experiment at the jth test is as follows:

η ij = −10 log(

1 n 2 ∑ yij ) n j =1

(1)

where y ij is the ith experiment at the jth test and n is the number of tests. The second criterion selects the-large-the-better characteristic for the tool life and material removal rate. The equation of the S/N ratio is as follows:

η ij = −10 log(

1 n 1 ∑ ) n j =1 yij2

Table 2 shows the Experimental results and its corresponding S/N ratio.

(2)

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Table 1 Machining parameters and their levels Machining parameter

Unit

Range and levels 1

2

3

v: Cutting speed

m/min

314

471

628

f:

m/min

6

3

0.6

Feed rate

d: Axial depth of cut mm 1.5 1 0.5 Table 2 Experimental layout using L 27 Orthogonal array and Experimental results and its S/N ratio L No

v

f

Ra

d (min)

( µm )

MRR (mm 3 )

S/N (L)

S/N

S/N MRR

(Ra)

1

1

1

3

208

0.62

0.1125

46.36127

4.15217 -18.9770

2

1

1

2

218

0.61

0.075

46.76913

4.29340 -22.4988

3

1

1

1

223

0.34

0.0375

46.96610

9.37042 -28.5194

4

1

2

3

203

0.35

0.05625

46.14992

9.11864 -24.9976

5

1

2

2

213

0.24

0.0375

46.56759 12.39577 -28.5194

6

1

2

1

224

0.2

0.01875

47.00496 13.97940 -34.5400

7

1

3

3

228

0.09

0.01125

47.15870 20.91515 -38.9770

8

1

3

2

243

0.07

0.0075

47.71212 23.09804 -42.4988

9

1

3

1

364

0.05

0.00375

51.22203 26.02060 -48.5194

10

2

1

3

103

0.45

0.075

40.25674

6.93575 -22.4988

11

2

1

2

122

0.42

0.05

41.72720

7.53501 -26.0206

12

2

1

1

138

0.4

0.025

42.79758

7.95880 -32.0412

13

2

2

3

110

0.3

0.0375

40.82785 10.45757 -28.5194

14

2

2

2

130

0.29

0.025

42.27887 10.75204 -32.0412

15

2

2

1

152

0.25

0.0125

43.63687 12.04120 -38.0618

16

2

3

3

101

0.09

0.0075

40.08643 20.91515 -42.4988

17

2

3

2

129

0.08

0.005

42.21180 21.93820 -46.0206

18

2

3

1

175

0.08

0.0025

44.86076 21.93820 -52.0412

19

3

1

3

53.5

0.26

0.05625

34.56707 11.70053 -24.9976

20

3

1

2

64.5

0.29

0.0375

36.19119 10.75204 -28.5194

21

3

1

1

72

0.28

0.01875

37.14665 11.05684 -34.5400

22

3

2

3

54

0.23 0.028125

34.64788 12.76544 -31.0182

23

3

2

2

68

0.22

0.01875

36.65018 13.15155 -34.5400

24

3

2

1

80

0.24 0.009375

38.06180 12.39577 -40.5606

25

3

3

3

53

0.11 0.005625

34.48552 19.17215 -44.9976

26

3

3

2

85

0.12

38.58838 18.41637 -48.5194

27

3

3

1

141

0.00375

0.1 0.001875

42.98438

20 -54.5400

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Grey relational analysis In the grey relational analysis method, experimental data (tool life, surface roughness and metal removal rate) are first normalized in the range between zero and one, which is also called the grey relational generation. The normalized SN ratio xIJ for the i th experiment results in the j th

experiment can be expressed as x IJ =

y ij − min j yij

(3)

max j y ij − min j y ij

Table 3 The data preprocessing of the each Performance characteristic. Next, the Grey relational coefficients are calculated to express the relationship between the ideal and the actual normalized SN ratio. The grey relational coefficient ξ ij can be expressed as:

ξ ij =

min i min j xi0 − xij + ζ max i max j xi0 − xij

(4)

xi0 − xij + ζ max i max j xi0 − xij

where xi0 is the ideal normalized results for the ith performance characteristics and ζ is the distinguishing coefficient which is defined in the range 0 ≤

ζ ≤ 1. After averaging the grey

relational coefficients, the grey relational grade can be obtained, that is: 1 m γ j = ∑ ξ ij m i =1

(5)

where m is the number of performance response. Table 4 presents the overall grey relational coefficient and the corresponding grey relational grade values for all the experimental runs. The mean of the grey relational grade for each level of the process parameters is calculated (Table 5). The larger the mean of the grey relational grade, the better is the multiple process response. The ANOVA is performed to determine which parameters significantly affect the performance characteristic. The results of ANOVA for grey relational grade values with v, f and d are shown in table 6. Results show that the cutting speed is the most significant parameter and feed rate the significant factor for affecting the multi-response characteristics. The larger the grey relational grade, the better is the multiple process response. Therefore, the optimal high speed machining parameters level combination is v1f 3 d 3 . The final step is to predict and verify the improvement of the performance characteristic using the optimal level of the machining parameters. The estimated grey relational grade of the optimal machining parameters combination can be calculated as: q

η opt = η m + ∑ (ηi − η m )

(6)

i =1

where η m is the total mean of the grey relational grade, ηi is the Grey relational grade at the optimal level and q is the number of the machining parameters that significantly affects the multiple response characteristics. Table 7 shows the results of the confirmation experiment using the optimal machining parameters. As shown in Table 7, the tool life is increased from 152 to 228 min, the material removal rate is decrease from 0.0125 to 0.01125 mm 3 and the surface roughness is

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improved from 0.25 to 0.09 µm . It is clearly shown that the multiple performance characteristics in the HSM process are greatly improved. Table 3 The data preprocessing of the each Performance characteristic Ra L MRR N

Table 4 The Grey relational coefficient and Grey relational grade N

Grey relational coefficient L

o

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27

Ra

MRR

0.3333 0.3348 0.3964 0.3928 0.4452 0.4759 0.6817 0.7891 1 0.3642 0.3717 0.3771 0.4126 0.4173 0.4389 0.6812 0.7281 0.7281 0.433 0.4173 0.4222 0.452 0.4593 0.4452 0.6149 0.5898 0.6449

1 0.8347 0.6508 0.747 0.6508 0.5333 0.4706 0.4305 0.3757 0.8347 0.7162 0.5764 0.6508 0.5764 0.4823 0.4305 0.3967 0.3497 0.747 0.6508 0.5333 0.5962 0.5333 0.4517 0.4059 0.3757 0.3333

o

0.70957 0.73394 0.74571 0.69694 0.72189 0.74803 0.75721 0.79028 1 0.34482 0.43268 0.49664 0.37895 0.46565 0.54679 0.33465 0.46164 0.61991 0.00487 0.10191 0.15900 0.00970 0.12933 0.21368 0 0.24514 0.50780

0 0.00646 0.23862 0.22711 0.37696 0.44938 0.76654 0.86636 1 0.12728 0.15469 0.17406 0.28833 0.30179 0.36074 0.76653 0.81331 0.81331 0.34517 0.30179 0.31573 0.39386 0.41152 0.37696 0.68683 0.65227 0.72468

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27

0.6326 0.6527 0.6629 0.6226 0.6426 0.6649 0.6731 0.7045 1 0.4328 0.4685 0.4983 0.446 0.4834 0.5245 0.4291 0.4815 0.5681 0.3344 0.3576 0.3729 0.3355 0.3648 0.3887 0.3333 0.3984 0.5039

Grey relational grade 0.6553 0.6074 0.5700 0.5875 0.5795 0.558 0.6085 0.6414 0.7919 0.5439 0.5188 0.4839 0.5032 0.4924 0.4819 0.5136 0.5354 0.5487 0.5048 0.4752 0.4428 0.4613 0.4525 0.4286 0.4514 0.4547 0.4941

0.7 0.6 0.5 0.4 v1 v2 v3

Mean value of the grey relational grade = 0.5630

f1 f2 f3

d1 d2 d3

Fig 3. Grey relational grade graph

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Table 6 Results of the analysis of variance for the grey relational grade Symbol Machining parameter

Degrees of freedom

Sum of square

Mean square

F

Contribution (%)

V

Cutting speed

2

0.119290

0.059645

32.67

89.55

f

Feed rate

2

0.013609

0.006804

3.73

10.22

d

Axial depth of cut

2

0.000293

0.000146

0.08

0.23

Error

20

0.036509

0.001825

Total

26

0.169701

Table 7 Results of HSM performance using the initial and optimal HSM process parameters Initial process parameters

Optimal process parameters Prediction v 1f 3 d 3

Experiment v 1f 3 d 3

Level

v 2 f 2 d1

Tool life

152

228

Surface roughness

0.25

0.09

material removal rate

0.0125

0.01125

Grey relational grade.

0.4819

0.5646

0.6085

Improvement of grey relational grade=0.1266 Conclusions The use of the Taguchi-Grey based method to determine the HSM parameters with

consideration of multiple performance characteristics has been reported in this paper. A grey relational analysis of the S/N ratios can convert the optimization of the multiple performance characteristics into the optimization of a single performance characteristic called the grey relational grade. By grey relational analysis, the optimal machining parameters’ setting can be obtained for the simultaneous consideration of the maximum tool life, material removal rate and minimum surface roughness. References [1] J. Tlusty, Int. J. CIRP, 42, 733 (1993).

[2] S. Smith, J. Tlusty, ASME J. Eng. Ind. 119, 664 (1997) [3] H. Schulz and T. Moriwaki, CIRP Ann. 41(2), 637 (1992) [4] J. Vivancos, C.J. Luis, L. Costa, J.A. Ortiz, J. Mater. Process. Technol. 155–156, 1505 (2004) [5]. J. L. Deng, J. Grey Syst. 1 (1), 1 (1989) [6] Z. Wang, L. Zhu, J. H. Wu, J. Grey Syst, 8 (1), 73 (1996) [7] N. Logothetis, A. Haigh, Quality Reliabil, Int, 4 (5), 159 (1988) [8] D. C. Montgomery, “Design and Analysis of Experiments,” 6th ed., Wiley, New York, (2005).

Progress on Advanced Manufacture for Micro/Nano Technology 2005 doi:10.4028/www.scientific.net/MSF.505-507 The Use of the Taguchi-Grey Based to Optimize High Speed End Milling with Multiple Performance Characteristics doi:10.4028/www.scientific.net/MSF.505-507.835