Investigation of abrasive water jet cutting parameters influence on 6082 aluminium alloy surface roughness/Aliuminio lydinio 6082 pjovimo abrazyvine vandens srove parametru itakos tyrimas pavirsiaus siurkstumui.
Gyliene, V. ; Jurenas, V. ; Krasauskas, P. 等
1. Introduction
Many machining technologies, so-called high speed technologies are
included in the category of Non-Traditional Machining Processes (NTMP).
These are nontraditional in the sense that traditional tools are not
employed; instead, energy in its direct form is utilized [1]. Abrasive
Water Jet (AWJ) cutting technology uses a jet of high pressure and
abrasive water slurry to cut the material by means of erosion. The
impact of single solid particles is the basic event in the material
removal by abrasive water jets [2].
In some technological applications the AWJ process has the target
of "cold" cutting process [3], but combining the temperature
it was observed that the AWJ produces high quality holes free of
chipping and gouging [4]. The process uses a fine-bore nozzle to form a
coherent, high velocity jet, which has a pressure up to 400 MPa and a
velocity of up to 1000 m s-1. AWJ cutting of the work-piece results from
failure and micro-machining and comparing with traditional and most
NTMP, AWJ cutting technology offers the following advantages [3]:
--no thermal distortion,
--high flexibility,
--high machining versatility,
--small machining force.
Whereas the AWJ technology is well defined but different techniques
like numerical study [5, 6] and cutting head oscillation techniques [3,
7, 8] are used for the optimisation of AWJ.
Nevertheless, many aspects of AWJ are still in development. AWJ
process investigation overview has showed that process has some
limitations on the thickness of material to cut [1, 3, 9]. The cut layer
of the material is characterized by two AWJ parameters: 1) cutting zone
or smooth roughness zone and 2) deformation zone or rough roughness
zone. Smooth roughness and rough roughness zones are limited by critical
depth [h.sub.crit]. According to Hashish, the so-called critical depth
[h.sub.crit] can be found in each surface [9]. The zone above the
critical depth is cutting zone [h.sub.c] and the zone below it is the
deformation zone [h.sub.d]. Author Valicek [9] also proposed the
parameters for surface quality evaluation below the critical zone: the
retardation of cutting trace [Y.sub.ret] and the angle [delta] of
deviation. These mentioned parameters are the nozzle effect on surface
due the working parameters.
Fig. 1 demonstrates the main parameters in cut-wall surface
roughness evaluation. Also, it can be seen, that striations resulting on
the cutting surface has a typical structure and are opposite to the
direction of cutting. The cutting zone is considered to be of good
quality and the deformation zone of poor quality. This critical depth
depends on the traverse speed of the cutting head.
The literature analysis [10] of surface roughness profile data
showed, that cutting workpiece of 30 mm according to traverse speed can
generate the smoother surface roughness comparing to other NTMP
techniques. For example, by oxygen cutting with economical working
parameters, the surface roughness [R.sub.a] can be reached in the range
of 25-6.3 [micro]m (N11-N9 according to standard ISO 1302). Meanwhile
surface roughness using AWJ technique depending on the traverse speed is
gained in the range of 6.3-3.2 [micro]m.
It can be concluded that the main parameters of AWJ which describes
surface quality are [1-9]: pressure, traverse speed (cutting speed) and
abrasive material as well dimension.
[FIGURE 1 OMITTED]
The aim of this work was to investigate traverse speed influence on
the surface roughness of 6082-Al alloy, to define the critical depth of
AWJ cut and examine the ability to increase maximum smooth surface zone
cut depth.
2. The experimental technique
The pentagonal shape workpiece was selected as a test specimen and
was cut from 6082-Al alloy with a thickness of 30 mm using a Resato ACM
Waterjet machine equipped with a 2.5D cutting head (5-axis) (Fig. 2).
The cutting was performed using five different traverse speeds, keeping
other cutting parameters constant: e.g. abrasive flow rate (180 g/min),
pump pressure (3600 bar) and the inside diameter of the cutting nozzle
(0.762 mm).
GMA Garnet MESH80 abrasive type (abrasive dimensions
300-150[micro]m) was chosen, which is ideally suited for all material
applications for precision cutting. AWJ cutting program was written to
control the nozzle path and traverse speed in order to cut pentagonal
specimen with different traverse speed for each pentagon walls (Fig. 3).
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
The surface roughness measurements were performed using portable
roughness tester TR200 and special Time Surf software.
The surface quality parameter employed to indicate the surface
quality in this experimental study was the arithmetic mean roughness
[R.sub.a].
3. Experimental results
Five straight wall cutting tests were performed with different
traverse speed starting from 163.5 mm/min (X-ROUGH wall cut) to 37.8
mm/min (X-FINE wall cut). Total cutting length comprises 300.4 mm and
time of cutting 7 min 46 s.
The surface roughness results of generated samples are presented in
Fig. 4. The surface profile measurements were performed in so-called
smooth roughness zone (or cutting zone). It is seen on the samples that
increase of traverse speed can be very effective. Also it is seen that
surface profile on surfaces X-ROUGH, ROUGH has clearly defined roughness
zones: cutting zone and deformation zone. The striations of tool path
are left in the deformation zone, due to the deflection of the nozzle in
high cutting speed. Visually, the results of samples MEDIUM, FINE,
X-FINE not presents the critical depth, as it seen in samples X-ROUGH
and ROUGH. The investigation of surface roughness according to cutting
depth was performed.
[FIGURE 4 OMITTED]
In the next stage, the surface roughness measuring in the
longitudinal direction was performed with the interval of 2 mm, so 14
measurement positions in total were defined for each specimen wall. The
surface evaluation was performed starting from cutting side. Each
measurement was performed at least 6 times and then averaged.
The surface roughness measurement results are presented in Fig. 5.
[FIGURE 5 OMITTED]
The surface roughness evolution according to the cutting depth
allowed defining the critical depth for concrete traverse speed.
Regarding the results of surface roughness according to the depth
of cut it was concluded that in our performed experiment the critical
depth for 30 mm 6082-Al alloy specimen varied according to traverse
speed.
Summarised surface roughness measurement results are presented in
Table 1.
It is seen, that samples X-ROUGH and ROUGH have striations, which
are formed in rough cutting (deformation) zone. These striations are
formed due to high traverse speed, which causes the deviation of the
water jet.
Specimens FINE and MEDIUM in cutting zone are practically of
identical surface quality of [R.sub.a] = 4.2 [micro]m. But starting from
26 mm (FINE machining) and 22 mm (MEDIUM machining) of cutting the
surface quality differs according to traverse speed. The same tendency
is observed in the samples X-ROUGH and ROUGH. In the cutting zone of
both mentioned samples the surface roughness is 4.8-4.9 [micro]m.
Only X-FINE (37.8 mm/min) cut showed the same surface results on
all specimens' length of 30 mm. So, the decrease of traverse speed
on the same workpiece allows increasing the cutting depth.
Finally, it has been demonstrated how surface roughness depends on
the traverse speed.
Fig. 6 presents the results of cutting depth dependence on cutting
speed. The results of surface roughness dependence according to traverse
speed in cutting zone are presented in Fig. 7.
Under the critical depth the trajectory of the jet is no more
vertical. It has been found that cutting head traverse speed decrease
from 163. to 37.8 mm/min calls the decrease of the surface roughness by
1 [micro]m. Due to the peculiarities of AWJ technique the main effect on
the admissible surface quality the workpiece surface roughness is the
thickness.
Data presented in Fig. 7 enable to conclude that surface roughness
in the cutting zone in dependence on cutting speed can be expressed by
equation:
[R.sub.a] = 2.25 [v.sup.0.155] (1)
Data presented in this study could be used by the manufacturers to
predict required surface roughness for water jet cutting considering to
the aluminum sheets thickness.
[FIGURE 6 OMITTED]
[FIGURE 7 OMITTED]
4. Conclusions
1. Abrasive Water Jet experimental research has been performed by
cutting 6082-Al alloy specimen of the thickness of 30 mm. Also the
influence of the traverse speed on surface roughness was examined.
2. AWJ experimental research has shown that traverse speed is the
main factor influencing the cutting depth achieving the admissible
surface roughness:
* the use of traverse speed of 37.8 mm/min allows cutting the 30 mm
6082-Al alloy workpiece in the range of surface quality 3.75-4.0
[micro]m,
* the use of traverse speed of 48.9 mm/min allows cutting the 26 mm
workpiece in the range of surface quality 4.0-4.75 [micro]m,
* the use of traverse speed of 68.1 mm/min allows cutting the 22 mm
workpiece in the range of surface quality 4.0-4.6 [micro]m,
* the use of traverse speed of 97.2 mm/min allows cutting the 20 mm
workpiece in the range of surface quality 4.5-5.2 [micro]m,
* the use of traverse speed of 163.5 mm/min allows cutting the 16
mm workpiece in the range of surface quality 4.7-5.2 [micro]m.
3. Finally, it has been concluded that the traverse speed of 37.8
mm/min in cutting 6082-Al alloy allows to achieve the surface roughness
of [R.sub.a] = 3.9 [micro]m for the workpiece with the wall thickness of
30 mm.
4. Also it has been found, that the decrease of traverse speed from
163.5 mm/min to 37.8 mm/min decrease the surface roughness by 1
[micro]m. But here the limitation of cutting depth to 16 mm is achieved,
by using the highest traverse speed.
Received September 08, 2014
Accepted December 15, 2014
Acknowledgement
Authors are very grateful to the company "Karbonas",
where abrasive water jet experimentation was being performed.
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V. Gyliene, Kaunas University of Technology, Studentu 56, LT-51424
Kaunas, Lithuania, E-mail: virginija.gyliene@ktu.lt
V. Jurenas, Kaunas University of Technology, Studentu 56, LT-51424
Kaunas, Lithuania, E-mail: vytautas.jurenas@ktu.lt
P. Krasauskas, Kaunas University of Technology, Studentu 56,
LT-51424 Kaunas, Lithuania, E-mail: povilas.krasauskas@ktu.lt
[cross.sup.ref] http://dx.doi.org/ 10.5755/j01.mech.20.6.8865
