Effect of machining parameters on MRR during wire electric discharge cutting of SICP/6061 AL MMC.
Shandilya, Pragya ; Jain, Pramod Kumar
Abstract: This paper reports experimental investigations of the
effect of machining parameters namely servo voltage (SV), pulse-on time
([T.sub.ON]), pulse-off time ([T.sub.OFF]) and wire feed rate (WF) on
material removal rate (MRR) during wire electrical discharge machining
(WEDC) of [SiC.sub.p]/6061 Al metal matrix composite (MMC). The
experiments were conducted using one-factor-at-a-time experiment
strategy in which only one input parameter was varied while keeping all
others input parameters constant. It was found that maximum value of MRR
is obtained at lower value of voltage, higher value of pulse-on time,
lower value of pulse-off time and lower value of wire feed rate.
Keywords: metal matrix composite (MMC), wire electric discharge
cutting (WEDC), material removal rate (MRR)
1. INTRODUCTION
Concerning industrial applications, MMCs now have a proven record
of accomplishment as successful high-technology materials due to the
properties such as high strength-to-weight ratio, high toughness, lower
value of coefficient of thermal expansion, good wear resistance, and
capability of operating at elevated temperatures (Taha, 2001; Rosso,
2006). MMCs are fabricated using several processes such as casting,
forging and extrusion. However, cutting and finishing operations of MMCs
are not well understood. The use of traditional machining processes to
machine hard composite materials causes serious tool wear due to
abrasive nature of reinforcing particles thus shortening tool life (Yan
and Wang, 1993; Monaghan and Reilly, 1992). Although, nontraditional
machining techniques such as water jet machining (WJM) and laser beam
machining (LBM) can be used but the machining equipment is expensive,
height of the workpiece is a constraint, and surface finish obtained is
not good (Muller and Monaghan, 2000). On the other hand, some techniques
such as electric discharge machining (EDM) and wire electric discharge
machining (WEDM) are quite successful for machining of MMCs. EDM has
limited applications as it can be used only for drilling purpose. WEDM
which is a derived process of EDM seems to be a better choice as it
conforms to easy control and can machine intricate and complex shapes.
WEDM is a thermo-electrical process in which material is eroded from the
workpiece by a series of discrete sparks between the workpiece and the
wire electrode (tool) separated by a thin film of dielectric fluid which
is continuously forced in to the machining zone to flush away the eroded
particles. The movement of the wire is controlled numerically to achieve
the desired three-dimensional shape and accuracy for the workpiece (as
shown in Fig. 1). The setting for the various process parameters
required in WEDC process play crucial role in achieving optimal
performance. Lot of research work has been done on WEDM, but very few
investigations have been done on WEDM of MMCs (Saha P. et al., 2009).
Previous research work on WEDM focuses on one-factor-at-a time approach
only on cutting speed and surface roughness; however no work has been
reported on MRR. This paper presents the effect of input process
parameters on MRR during WEDC of [SiC.sub.p]/6061 A1 MMC.
[FIGURE 1 OMITTED]
2. EXPERIMENTATION
The experiments were conducted on the ECOCUT WEDM from Electronica
India Pvt Ltd. 6061 aluminum based MMC, made by stir casting having 5%,
7.5% and 10% SiC particles (by weight) as reinforcement were used as the
workpieces. The workpieces were of rectangular shape having a thickness
of 6 ram. The deionized water was used as dielectric. The dielectric
temperature was kept at 20[degrees]C. A diffused brass wire of 0.25 mm
diameter was used as the cutting tool. The four input parameters namely
servo voltage (SV), pulse-on time ([T.sub.ON]), pulse-off time
([T.sub.OFF]) and wire feed rate (WF) were chosen as variables to study
their effect on the quality of cut in machining of [SiC.sub.p]/6061
aluminum MMC with MRR as response parameters. To calculate the MRR, the
following equation (Nito et al., 2006) is considered:
MRR = [M.sub.f] - [M.sub.i]/[rho]t (1)
Where Mi, Mf are masses (in gm) of the work material before and
after machining respectively, [rho] is the density of workpiece material
and t is the time of machining in minutes. An electronic weighing
machine with an accuracy of 0.1 mg is used to weight the material.
3. EXPERIMENTAL RESULTS AND ANALYSIS
Fig. 2(a) shows the effect of voltage on the MRR indicating that as
the MRR decreases continuously with increase in the voltage for all
three MMCs and that at any value of the voltage, the MRR is maximum for
the MMC with 5% SiCp. Fig. 2(b) depicts the variation of the MRR with
the pulse-on time indicating that the MRR increases continuously with
increase in the pulse-on time for all three percentage of [SiC.sub.p]
and its value being highest for the MMC with 5% [SiC.sub.p] at any value
of the pulse-on time. Fig. 2(c) shows the effect of pulse-off time on
the MRR depicting that the MRR continuously decreases with increase in
pulse-off time and value of MRR is maximum for 5% [SiC.sub.p]. Fig. 2(d)
shows the effect of wire feed rate on the MRR. From this graph it is
evident that the MRR decreases with increase in the wire feed rate for
all the three percentage of SiC particles. It is also clear from these
graphs that MRR is maximum for the MMC with 5% SiC particles, which
shows that as the percentage of SiC particles increases MRR decreases.
[FIGURE 2 OMITTED]
4. CONCLUSIONS
From the experimental investigations on WEDC of 6061 aluminum alloy
based MMC reinforced with three different percentage of the SiC
particles it can be conclude that to achieve higher value of the MRR,
lower value of voltage, higher value of pulse-on time, lower value of
pulse-off time and lower value of wire feed rate should be used. At any
given value of any of the four parameters the MMC with 5% [SiC.sub.p]
gives the highest value of the MRR among the three % of the SiC
particles considered in this work. The present work is focused on the
WEDC of [SiC.sub.p]/6061 A1 MMCs up to 10% SiC particles. In future the
study can be extended using different work material, process parameters
and performance measures. Levels of process parameters like wire
tension, table feed rate etc. that have been fixed during this study may
be varied for further investigations to determine the machinability of
MMCs during WEDC process.
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