Parametric optimization of ECH process for gear finishing by RSM and SAA.
Misra, Joy Prakash ; Jain, Pramod Kumar ; Dwivedi, Dheerendra Kumar 等
Abstract: This paper presents the parametric optimization of
Electrochemical Honing (ECH) of gears using Response Surface Methodology (RSM) and Simulated Annealing Algorithm (SAA) to predict the surface
quality of gear teeth profile. A three factors three levels Box Behnken
Design (BBD) of Response Surface Methodology (RSM) has been designed to
investigate and analyse the effects of input variables: voltage,
rotating speed and electrolyte concentration on percentage improvement
in average and maximum surface roughness ([PIR.sub.a] / [PIR.sub.tm])
values. Regression models were developed and were used as objective
function for optimizing the process parameters using SAA. The results
established the feasibility of using the process to improve the surface
quality of gear teeth profile.
Key words: electrochemical honing (ECH), response surface
methodology (RSM), box-behnken design (BBD), simulated annealing
algorithm (SAA)
1. INTRODUCTION
The Helical gears are used to transmit motion and/or power between
two parallel or crossed axes shafts or between shaft and rack by gradual
engagement of teeth. This type of gears has higher load carrying
capacity and used for high speed application. But, gears running at high
speed are subjected to additional dynamic forces due to discontinuities
in tooth profile. The discontinuities namely scratches, cut marks,
notches, pits present at the gear teeth profile act as stress
concentrator and enhances the chances of fatigue failure. The errors of
gear tooth profile can be significantly reduced by gear finishing
processes. Conventional gear finishing processes such as gear grinding,
gear shaving, gear honing, gear lapping are costly, have low
productivity, and gear material hardness limitation. This necessitates
exploration of alternative gear finishing processes such as
Electrochemical honing (ECH) which is a hybrid micro-finishing process
combining electrochemical machining (ECM) and honing, having potential
to overcome most of the limitations of both the process and at the same
time offers most of the capabilities of individuals.
1.1 ECH of Gears
ECH is a hybrid finishing process of ECM and mechanical honing;
combining the faster material removal capability of ECM and the
correcting capability for shape-related errors of honing into a single
process. Fig. 1 describes the working principle of ECH of gears
described by Chen et al. (1981), in which an anodic workpiece gear
meshes with a specially shaped cathodic gear and a honing gear
simultaneously and also reciprocates axially as indicated by the arrow.
An inter-electrode gap (IEG) is provided between the workpiece and
cathode gear to prevent short-circuiting by sandwiching a conducting
gear between two non-conducting gears and undercutting the profile of
the conducting gear as compared with that of the non-conducting gears. A
low D.C. voltage is applied across the electrolyte flooded IEG for
controlled electrochemical (EC) dissolution of the anodic gear. But, due
to electrolytic passivation a thin insulated metal oxide microfilm is
formed on the teeth profile of the workpiece gear and protects the metal
from being further removed. Honing gear scrubs this insulated layer and
accelerates the ECM process.
There are very few references available on ECH of gears. Though the
process was initiated by Capello and Bertoglio in 1979, the modelling of
the process was probably started by Yi et al. in 2002. They explained
the electrochemical tooth-profile modification based on real time
control and developed a mathematical model of the process using an
artificial neural network. Misra et al. (2010) have investigated on ECH
of helical gears but to the best knowledge of authors the optimization
of the process parameters using evolutionary optimization technique is
not reported till date. In the present study, parametric optimization of
the process has been carried out using RSM and SAA.
[FIGURE 1 OMITTED]
2. EXPERIMENTATION
The experimentation has been carried out in an indigenously
developed experimental setup for ECH of helical gears. The detail of the
same has been available in reference (Misra et al., 2010).
In the present study, voltage (V), rotating speed of workpiece gear
(S) and electrolyte concentration (C) are used as input process
parameters while percentage improvement in average and maximum surface
roughness values ([PIR.sub.a] / [PIR.sub.tm]) are used as response
parameters. The surface roughness values before and after ECH are
measured with a Wyko NT 1100 optical profilometer interfaced with
Vision[R]32 software. The experimentation was planned according to the
Box-Behnken Design of Response Surface Methodology (RSM) approach. The
experimental study contained three factors each at three levels and
therefore number of experimental run required was fifteen including
three replications of centre point.
3. RESULTS AND DISCUSSIONS
The effects of process parameters on [PIR.sub.a] and [PIR.sub.tm]
are shown in Fig. 2(a) and (b), respectively. The regression models
developed for [PIR.sub.a] and [PIR.sub.tm] in terms of actual values are
described by equations (1) and (2) respectively.
[PIR.sub.a] = - 173.75771 + 13.90969xV + 1.43058xS + 4.2770xC -
0.23315 x [V.sup.2] - 0.010933x[S.sup.2] - 0.17800x[C.sup.2] (1)
[PIR.sub.tm] = - 167.99383 + 13.08875xV + 1.33719xS + 4.84850xC -
0.23315x[V.sup.2] - 0.010080x[S.sup.2] - 0.21447x[C.sup.2] (2)
[FIGURE 2 OMITTED]
The improvement in surface roughness values (i.e.
[PIR.sub.a]/[PIR.sub.tm]) initially increase with voltage upto a certain
level and then start decresing as volumetric material removal rate is
proportional to the voltage while voltage is inversely proportional to
the IEG. It is evident from Fig. 1 and 2, that there exists an optimum
value of rotating speed of the workpiece gear to achieve the optimum
coordination between the electrolytic action and mechanical abrasion.
The [PIR.sub.a]/[PIR.sub.tm] values increase with increasing electrolyte
concentration as more number of ions is available in electrolytic
solution.
3.1 Simulated Annealing Algorithm
In the present study, SA is used as an optimization technique for
solving a bound-constrained optimization problem. The technique imitates
the cooling process of metal during annealing to achieve the
minimization of function values (Chandrasekaran et al., 2010). The
regression models developed by RSM have been used as objective function
and the upper and lower bounds of parameters are identified by
conducting experiments. The problem can be formulated as given below.
The main aim is to maximize the [PIR.sub.a] and [PIR.sub.tm] value.
So, the objective functions:
Minimize Z = [W.sub.1.sup.*](-[PIR.sub.a]) +
[W.sub.2.sup.*](-[PIR.sub.tm]); [W.sub.1], [W.sub.2] are arbitrarily
choosen parameters to represent the importance of each response
parameter and taken as 0.5. Subjected to, 26 [less than or equal to] V
[less than or equal to] 34; 50 [less than or equal to] S [less than or
equal to] 80; C [less than or equal to] 10.
The optimization is carried out in MATLAB (Version: 7.6.0.324)
environment. Fig. 3 depicts the current function value at each
iteration.
[FIGURE 3 OMITTED]
4. CONCLUSION AND FUTURE SCOPE
In the present work, parametric optimization using Response Surface
Methodology and Simulated Annealing Algorithm has been carried out.
Based on the results, 28.4 V as voltage, 65 rpm as rotating speed and
10% as electrolyte concentration are found optimum and at optimum
setting of the parameters, the process shows an improvement of 91% in
surface quality of gear teeth profile. Thus, the process is very much
useful for improving the fatigue life and service life of gears. But, in
present study, parametric optimization has been carded out only for
voltage, rotating speed and electrolyte concentration. An eleaborate
experimental investigation is required to optimize other ECH parameters.
Moreover, the developed experimental setup is not capable to accommodate
the gear of different sizes and therefore, a vigorous study is required
to develop an experimental setup with modular tooling system to
accommodate gear of different sizes and to carry out ECM, honing and ECH
process in a single setup to transform it into a matured manufacturing
technology and for its successful industrial applications and
commercialization.
5. REFERENCES
Capello, G. & Bertoglio, S. (1979). A New Approach by
Electrochemical Finishing of Hardened Cylindrical Gear Tooth Face. CIRP Annals, Vol. 28, No. 1, 103-107, 00078506
Chandrasekaran, M.; Muralidhar, M.; Murali Krishna, C. & Dixit,
U. S. (2010). Application of Soft Computing Techniques in Machining
Performance Prediction and Optimization: A Literature Review.
International Journal of Advanced Manufacturing Technology, Vol. 46,
445-464, 02683768
Chen, C. P.; Liu, J.; Wei, G. C.; Wan, C. B. & Wan, J. (1981).
Electrochemical Honing of Gears: A New Method of Gear Finishing. CIRP
Annals, Vol. 30, No. 1, 103-106, 00078506
Misra, J. P.; Jain, N. K. & Jain, P. K. (2010). Investigations
on precision finishing of helical gears by electrochemical honing (ECH)
process, Proc. IMechE: Journal of Engineering Manufacture, Vol. 224, No.
12, 1817-1830, 20412975
Yi, J.; Zhang, J.; Yang, T.; Xia, D. & Hu, D. (2002). Solving
the control problem for electrochemical gear tooth-profile modification
using an artificial neural network. International Journal of Advanced
Manufacturing Technology, Vol. 19, No. 1, 8-13, 14333015
