Experimental investigation during wire electric discharge cutting of SiCp/6061 aluminum metal matrix composite.
Shandilya, Pragya ; Jain, Pramod Kumar ; Misra, Joy Prakash 等
1. INTRODUCTION
MMCs have become increasingly important in modern industrial
applications due to their 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
temperature [Miracle D.B. (2005); Taha M.A. (2001)]. Using traditional
machining processes to machine hard composite materials causes very high
tool wear due to abrasive nature of reinforcing particles [Yan B.H.
& Wang C.C. (1993)] thus shortening the cutting tool life. Although,
nontraditional machining techniques such as water jet machining (WJM)
and laser beam machining (LBM) have been used in past [Muller F. et. al.
(2000); Grabowski A. et. al. (2006) ] but their machining equipment is
expensive and height of the workpiece is a constraint in using these
processes. In this context, wire electric discharge machining (WEDM)
seems to be a better choice for machining the MMCs because it offers
easy control and has capability of machining intricate complex shapes
WEDM is a type of thermal advanced machining process capable of
accurately machining the parts having varying hardness, complex shapes
and sharp edges that are difficult to machine by other traditional and
nontraditional machining processes. Lot of research work has been on
WEDM but, very few investigations on WEDM of MMC have been done [Patil
N.G. et. al. (2006); Saha P. et. al. (2009)] and particularly there is
lack of published literature on WEDM of Al-based MMCs. This paper
presents the experimental findings on the wire electric discharge
cutting (WEDC) of 6061 aluminum MMC reinforced with silicon carbide particulates (i.e. Si[C.sub.p]/6061 Al). In the present work effect of
servo voltage (SV) and pulse-on time ([T.sub.ON]) on the quality of cut
in terms of average cutting speed and microstructure of the cut surface
has been evaluated to bracket range of input parameters for carrying out
further research on WEDC of Si[C.sub.p]/6061 aluminum MMC.
2. EXPERIMENTATION
In this experiment, three types of 6061 aluminum based MMCs made by
stir casting and 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 mm. Table 1 shows the chemical
compositions of the matrix of the MMCs used in this study.
The experiments were conducted on the ECOCUT WEDM Machine from
Electronica India Pvt Ltd. A diffused brass wire of 0.25 mm diameter was
used as the cutting tool. The deionized water was used as dielectric.
The input parameters were varied during the experiments namely servo
voltage (SV) in the range of 70-100 V, and pulse-on time ([T.sub.ON]) in
the range of 1-10 [micro]s to study their effects on the average cutting
speed and microstructure of the cut surface. The experiments were
conducted using one-factor-at-a-time experiment strategy in which only
one input parameter was varied while all others input parameters were
kept constant at the middle point of their respective range. Average
cutting speed was calculated by dividing the length of cut by the total
cutting time which was recorded using a stop watch having a least count
of 0.01 seconds while, the microstructure of the cut surface was
examined using SEM.
3. EXPERIMENTAL RESULTS AND ANALYSIS
Machining characteristics. Fig. 1(a) shows the effect of voltage on
the average cutting speed indicating that as the average cutting speed
decreases continuously with increase in the voltage for all three MMCs
and that at any value of the voltage, the average cutting speed is
maximum for the MMC with 7.5% Si[C.sub.p]. The frequency of wire
breakage increases significantly when the voltage reaches less than 70
V. Fig. 1(b) depicts the variation of the average cutting speed with the
pulse-on time indicating that the average cutting speed increases
continuously with increase in the pulse-on time for all three percentage
of Si[C.sub.p] and its value being highest for the MMC with 7.5%
Si[C.sub.p] at any value of the pulse-on time. Surface Morphology. SEM
of the cut surface by WEDC was conducted to evaluate the effect of
machining parameters on the surface textures of the 6061 Al based MMC
reinforced with 7.5% SiC particles. Figs 2 (a)-(d) show the SEM images
of the cut surfaces for the end values of the bracketed input parameters
(i.e. voltage at 70 and 90 V; and [T.sub.ON] 1 and 4 us). It is clear
that the morphology of the WEDC surface was dependent on the applied
voltage and pulse-on time. The WEDC surface abounds with the craters and
ridged surface. The craters and ridge-rich surface were formed by the
melted material. When lower voltages (Fig. 2(a)), lower pulse-on time
(Fig. 2(c)) are used, the surface characteristics had minor hillocks and
valley. When the voltage and pulse-on time increases the cut surface
exhibits deeper craters and ridge-rich surfaces.
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
4. CONCLUSIONS
From the preliminary 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 average
cutting speed, lower value of voltage and higher value of pulse-on time
should be used. At any given value of any of the two input parameters
the MMC with 7.5% Si[C.sub.p] gives the highest value of the average
cutting speed among the % of the SiC particles considered in this work.
Through analysis of SEM, it has been observed that the depth of
micro-voids and micro-cracks increases as the voltage and pulse-on time
increase. In future the study can be extended using different work
material, process parameters and performance measures.
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Tab. 1 Chemical composition of Al6061 alloy
Si 0.4-0.8
Fe 0.7 max
Cu 0.15-0.40
Mn 0.15 max
Mg 0.8-1.2
Cr 0.04-0.35
Zn 0.25 max
Ti 0.15 max
Other elements 0.15 total, 0.05 max each
Al REM
