下載/瀏覽

Download Report

Transcript 下載/瀏覽 

Materials and Manufacturing Processes
A Hybrid Machining Process Combining Micro-EDM and
Laser Beam Machining of Nickel-Titanium Based Shape
Memory Alloy
A. Al-Ahmariab, M. Sarvar Rasheeda, Muneer Khan Mohammeda & T. Saleha
a FARCAMT,
b Industrial
Advanced Manufacturing Institute, King Saud University, Riyadh, Saudi Arabia
Engineering Department, College of Engineering, King Saud University, Riyadh,
Saudi Arabia
Advisor : Tzu-Yao Tai
Advisee : Lung-yu Chang
Department of Mechanical Engineering & Institute of Nanotechnology,
Southern Taiwan University of Science and Technology, Tainan, TAIWAN
Date ﹕2015/06/08
Outline
Abstract
Experimental
Result and discussion
Conclusions
2
Abstract
Micro-EDM is a slow process as compared to laser machining, on the
contrary laser machining lacks good surface quality. To overcome the
drawbacks of both these processes, this paper suggests a hybrid
machining process which combines laser and micro-EDM processes for
drilling micro-holes in advanced engineering materials such as NickelTitanium (Ni-Ti) based shape memory alloy. To achieve the objective of
the suggested hybrid process, pilot holes are drilled with laser machine
and rimmed out by micro-EDM drilling. The suggested process requires
investigation of various combinations of micro-EDM drilling process
conditions to obtain optimum machining parameters for the hybrid
process. It has been found that the proposed hybrid machining process
resulted in 50-65% reduction in machining time without affecting the
quality of micro-holes as compared to the standard micro-EDM
process.
3
Experimental
Figure 1 Schematic diagram of Micro-EDM
Figure 2 Electrical Power Supply R C Circuit
4
Experimental
Process Conditions
Values
Electrode material and
diameter
Brass
Diameter = 200 µm
Workpiece material
Ni-Ti alloy (SMA)
Polarity
Electrode = -ve
Workpiece = +ve
Pulse generator Type
RC
Dielectric fluid
Kerosene
Discharge voltage
80 V
100 V
Capacitor
155 pF
475 pF
Table 1: Micro-EDM Experimental Conditions
5
Experimental
Figure 4 Components of the laser unit
Figure 3 Micro-EDM Experimental Set-up
based on Masuzawa, 2000
Wavelength
1064 nm
Pulse duration
10 µs
Frequency
30 KHz
Laser spot diameter
30 µm
Table 2: Laser parameters
6
Results and Discussion
Figure 5 Variation of Overcut with Discharge energy
7
Results and Discussion
Figure 6 Variations of Taperness with Discharge energy
8
Results and Discussion
Figure 7 Variation of Material removal rate with Discharge Energy
9
Results and Discussion
220.012 µm
206.381 µm
206.061 µm
204.681 µm
221.143 µm
218.884 µm
208.879 µm
218.947 µm
223.885 µm
225.462 µm
189.144 µm
192.572 µm
214.860 µm
225.161 µm
206.877 µm
204.007 µm
Figure 8 SEM images showing hole diameter at entrance (left) and exit (right) for
different energy levels (a) 7.525μJ (b) 4.816μJ (c) 2.375μJ (d) 1.52μJ
10
Results and Discussion
Figure 9 Comparison of micro-holes diameter at entrance and exit
produced by (a) LBM and (b) LEDM
10
Results and Discussion
Figure 10 Comparison of Overcut in
μ-EDM and LEDM
(Hybrid Process)
Figure 11 Comparison of Taper angle in
μ-EDM and LEDM
(Hybrid Process)
11
Results and Discussion
Figure 12 Illustration of Hybrid
machining
Figure 13 Comparison of Material Removal Rates in
μ-EDM and LEDM
(Hybrid Process)
12
Results and Discussion
Machining Type
µ-EDM
Laser Machining
Hybrid Machining
MRR (mm3/min)
0.001422
0.002674
0.002082
Table 3: MRR comparison in µ-EDM, Laser, Hybrid Machining
13
Results and Discussion
Figure 14 SEM images of micro-holes produced on (a) standard μ-EDM, (b) Laser machining
14
Results and Discussion
Figure 14 SEM images of micro-holes produced on (c) Hybrid Machining
15
Conclusions
1. The laser machining of micro-holes the material removal rate was
very high but the quality of micro-holes produced was not good.
On the other hand the micro-holes produced by micro-EDM were
of high quality with good surface morphology but however the
material removal rate was very low. Therefore, in order to
overcome this problem and to take the advantage from the both
the machining processes (high MRR during laser machining and
good surface morphology with micro-EDM).
2. The hybrid machining process has resulted in the 50-65%
reduction of machining time and about 40% to 65% increase in
material removal rate (MRR) without effecting the quality of
micro-hole.
15
Thank you for your attention
18