Ultrasonic assisted of die sinking electrical discharge machining using standard equipments and devices.
Turc, Cristian--Gheorghe ; Belgiu, George ; Pamintas, Eugen 等
1. INTRODUCTION
The electrical discharge machining (EDM) is suitable for economical
machining of special hard metallic materials, or complex surfaces, that
is too expensive or impossible to machine by classical cutting methods.
There are a lot of machines for EDM, with massive electrode--the
so-called die sinking EDM that is used to machine by the coping of the
tool-electrode shape, or with wire electrode--the so-called wire EDM
that is used for cutting out operations. Most of EDM machines are big,
because they are used especially for the manufacturing of the dies.
The material erosion mechanism primarily makes use of electrical
energy and turns it into thermal energy through a series of discrete
electrical discharges occurring between the electrode and work piece
immersed in a dielectric fluid. The thermal energy generates a channel
of plasma between the cathode and anode at a temperature usually in the
range of 8000 to 12,000 [degrees]C initializing a substantial amount of
heating and melting of material at the surface of each electrode. When
the pulsating direct current supply occurring at the rate of
approximately 20-30 kHz is turned off, the plasma channel breaks down,
causing a sudden reduction in the temperature allowing the circulating
dielectric fluid to implore the plasma channel and flush the molten
material from the electrode surfaces in the form of small, microscopic
debris. The volume of material removed per discharge is typically in the
range of [10.sup.-6]-[10.sup.-4] [mm.sup.3] and the material removal
rate is usually between 2 and 400 [mm.sup.3]/min depending on specific
application. Since the shaped electrode defines the area in which the
spark erosion will occur, the accuracy of the part produced after EDM is
fairly high (Ho & Newman, 2003).
The major disadvantage of the EDM consists on its small metal
removal rate (MRR). According some authors, the time spent for a mold
manufacturing is nearly 50% of the total manufacturing time, including
mold assembling and probes (Witzak, 1997).
During the EDM process development, there were introduce some
techniques in order to improve the MRR, such as (Abbas et. al., 2007):
* Rotating of the work piece or the tool-electrode;
* Improving of the dielectric liquid flushing;
* Using of CNC technology;
* Using of multi-electrode discharging system;
* Introducing of dry EDM;
* Process control improvements;
* Tool-electrode or work piece vibration.
2. ULTRASONIC ASSISTED EDM
Introduction of ultrasonic vibration to the electrode or work piece
is one of the methods used to expand the application of EDM and to
improve the machining performance on difficult to machine materials
(Abbas et. al., 2007). The study of the effects on ultrasonic vibration
of the tool-electrode on die sinking EDM has been undertaken since
1980s. The higher MRR gained by the employment of ultrasonic vibration
is mainly attributed to the improvement in dielectric circulation which
facilitates the debris removal and the creation of a large pressure
change between the electrode and the work piece, as an enhancement of
molten metal ejection from the surface of the work piece. Later, it was
proposed spark erosion with ultrasonic frequency using a DC power supply
instead of the usual EDM pulse power supply (Zhang et al., 1997). The
pulse discharge is produced by the motion between the tool-electrode and
work piece simplifying the equipment and reducing its cost. They have
indicated that it is easy to produce a combined technology which
benefits from the virtues of ultrasonic machining and EDM. Ghoreishi and
Atkinson compared the effects of axial vibration of the tool-electrode,
rotation of the tool-electrode and combinations of the methods
(vibro-rotary) in respect of MRR, tool wear ratio and surface quality in
EDM die sinking and found that vibro-rotary increases MRR by up to 35%
compared with vibration EDM and by up to 100% compared with rotary EDM
in semi finishing (Ghoreishi & Atkinson, 2002). Prihandana et al.
have studied the effect of vibrated work piece, also. They have proven
that when the vibration was introduced on the work piece the flushing
effect increased, and that high amplitude combined with high frequency
increase the MRR (Prihandana et al., 2006).
Most of the studies regarding ultrasonic assisted EDM (UAEDM) were
carried out on experimental systems. This is the reason why the
industrial applications of this new combined technology are not
wide-spread yet, despite the good experimental results in improving the
MRR.
3. UAEDM DEVELOPMENT
In our opinion, the future development of the ultrasonic assisted
EDM technology is possible through standardization, applying specific
equipments and devices that are already in the industrial use. Thus, our
research is focused on the aspect of linking the existing solutions
using a minimum set of adapting devices. Figure 1 presents a possible
combined set of devices, specific to both ultrasonic and EDM
technologies. Thus, the ultrasonic stack, consisting of the transducer
(converter) 4, the booster 6 and the sonotrode (horn) 7 is attached to
the clamping journal 2 through a pair of dedicated parts: the ultrasonic
stack housing 5 and the custom pallet 3. The whole assembly is then
mounted into the tool clamper 1, which is attached to the EDM machine
tailstock. The set-up also needs an ultrasonic generator that supplies
the transducer. In order to avoid the undesirable interferences, the
pallet 3 should be made of an insulating material. Except the ultrasonic
stack housing, the pallet and the sonotrode 7, which is designed
according to the cavity to machine and can be manufactured through rapid
prototyping technique (Cosma et. al., 2006), all the set-up components
should be standard supplied. Thus, the tool clamper (figure 2) and the
clamping journal (figure 3.a) are standard solutions in EDM fixturing
systems. The insulating pallet should be designed according to the
fixturing system specifications, as shown in figure 3.b (Hirschmann,
2009).
[FIGURE 1 OMITTED]
The ultrasonic stack type depends on the specific process needs. A
wide range of typo-dimensional ultrasonic stacks are delivered by a lot
of manufacturers. Figure 4 presents an ultrasonic booster and transducer
design that is suitable for averages UAEDM operations (Krell
Engineering, 2009).
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
4. FURTHER RESEARCH
The further researches will be focused on the development of a
methodology in choosing the right ultrasonic stack (type, power,
frequency), and in developing of a parametric design for the ultrasonic
stack housing and pallet that are necessary to assembly the ultrasonic
stack into the specific fixturing system.
5. CONCLUSION
The present study presents some elements on an easier way to
implement ultrasonic assisted die sinking EDM operations by using on a
large scale of the existing tooling solutions. This approach will lead
to a significantly development of UAEDM.
6. REFERENCES
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Effect of vibrated electrode in electrical discharge machining.
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