Impact of cutting parameters on the quality of laser cutting.
Cus, Franc ; Milfelner, Matjaz ; Zuperl, Uros 等
Abstract: The paper discusses the use of the laser system in
production and the influence of laser cutting parameters on the quality
of manufacture In order to reach high accuracies of laser cutting it is
necessary to introduce new machining technologies, to automate the
cutting process and to adapt the cutting process to different sizes and
shapes of workpieces and to other requirements in machining. The paper
describes the influence of various technological parameters on the
quality of laser cutting for the [CO.sub.2] laser system. Initially, the
cutting parameters (cutting speed, output power of laser beam,
frequency, working mode, gas pressure, etc.) are important for the
programmer of the laser system and in the second stage for the machine
operator.
Key words: Laser cutting, cutting parameters, cutting surface.
1. INTRODUCTION
The laser as a manufacturing tool has proved to be useful also in
production mechanical engineering, particularly because of its numerous
technological advantages. The advantages of this manufacturing
technology include very high quality, possibility of automation of the
process and adaptability to different sizes and shapes and to different
other requirements in manufacturing.
The starting point for analysis of the laser cutting is always
quality of the cut. Therefore it is very important that the cut achieved
s properly described with different characteristics of quality. The
usual way of action is that in the first stage the obtained quality of
cut (cut shape, waviness and/or roughness of the cut surface and
presence of burr on the workpiece lower edge) is usually evaluated.
Often, those evaluations are not accurate enough; therefore, measuring
of the individual characteristics must be performed. For evaluating the
quality usually the following geometrical characteristics of the cut are
used (top and bottom width, unevenness on the top and bottom edge,
height and width of burr on the lower part, measuring of the depth of
the heat affected zone (HAZ)).
2. MEASURING OF TEMPERATURE IN LASER CUTTING
Successful control of the laser manufacturing process is closely
connected to the familiarization with thermal conditions in the cutting
zone and its environment. Therefore, on the basis of the knowledge of
the temperature cycles, determined by measuring the temperatures by
thermo--couples placed at a certain distance of the cutting front from
the travelling source, it is possible to conclude what the conditions in
the cutting front are (Rajaram et al., 2003). Due to the narrow laser
beam and the small depth of the heat affected zone (HAZ) the temperature
measuring is very exacting, since accurate placing of thermo--couples at
the selected distance from the cutting front is extremely difficult.
Measurements showed that in case of great temperature gradients a
thin layer of molten material in the cutting front and a small thickness
of the heat affected zone are achieved, which, however, finally assures
better quality of the cut (El-Kurdi et al., 2003).
For evaluation of the critical cutting speed generally the
following findings apply:
--In case of small steel plate the thickness from 0,6 to 0,8 mm
rather high mean values of temperatures in the cutting front occur,
therefore, the critical cutting speeds are between 40 and 50 mm/s.
--For the steel plate thickness 1,0 and 1,5mm, with lower cutting
speeds the mean values of temperatures are almost constant and only when
the critical cutting speed is exceeded, the temperature swiftly drops.
For the said steel plate thicknesses the critical cutting speeds are 30
mm/s and/or 35 mm/s.
3. INFLUENCE OF TECHNOLOGICAL PARAMETERS ON QUALITY OF LASER
CUTTING
The paper describes the influence of different technological
parameters on the quality of cutting by [CO.sub.2] laser systems. These
are the parameters which, in the first stage, are important for the
programmer of the laser system and in the second stage for the operator.
Knowledge of the said parameters can considerably contribute to the
utilization of the laser system (Pietro & Yao, 2003).
Cutting speed; (vL) has a very great influence and is determined in
accordance with the laser cutting method itself. If long, straight lines
are cut, a high cutting speed is selected; on the other hand, when small
holes are cut or very precise cutting is required, a low cutting speed
is selected. Of course, the cutting speed depends also on the type of
material cut and its thickness (Haferkamp et al., 1998).
--The Laser beam output power (PL) is closely connected to the
speed of laser cutting. When the put power is too high for the selected
cutting speed, burning of the material will take place; in the opposite
case, incomplete cutting and/or the so-called formation of holes in
material will occur.
Frequency of electromagnetic waves significantly influences the
excitation itself in the laser medium. Higher frequency of laser waves
gives greater top output of the laser beam and, accordingly, greater
output power fed to the material cut.
Generally, high frequency is used for the so-called high-speed
cutting, whereas the low frequency is used for cutting at lower speeds.
It means that for cutting small holes and/or details always low
frequency of the laser beam is used. Thus, lower output power of the
laser beam acts on the material (Steen, 1991).
Assistant laser gases. For laser cutting, usually, oxygen, nitrogen
and compressed air are used assistant cutting gases. Oxygen is used to
cut softer materials. As it causes oxidation of the surface it is very
useful in cutting of thicker materials. With it, usually, the ordinary
and zinc--coated steel plates are cut. Also the stainless steel plates
can be cut with it, but during cutting an oxidation layer is left on the
surface of material, which results in dark edges. For cutting stainless
steel plates the so-called clean cut is required in most cases. In this
case cutting does not cause oxidation, but the gas used is N2 at 7--8
bar pressure. Compressed air is used for cutting of Al, stainless steel
plates and non--metallic materials; in this case the air pressure should
be 7-8 bar. This method causes a greater oxidation layer on the surface
of material, however, the cost of cutting are significantly lower.
The cutting gas pressure has a very great influence on the quality
of laser cutting. It must be properly set according to the material type
and thickness and shape of the product cut. For cutting of soft
materials the oxygen pressure is about 1 bar, 2 bars for cutting of
small holes and 3 bars for cutting of stainless steel plates. For
cutting of thick materials the pressure should be 7 bar. Nitrogen is
used for cutting of stainless steel plates and the gas pressure varies
between 7 and 8 bar. For cutting by air the cutting pressure is between
7 and 8 bar. The air as cutting gas is used for cutting stainless steel
and aluminium (Tonshoff et al., 2003).
The distance between nozzle and work piece is the distance between
the laser nozzle top and the workpiece surface. Usually, the distance
between the nozzle and workpiece is about 1,5 mm, however for cutting of
Al and stainless steel plates by high pressure much smaller distances
are used, i. e., between about 0,3 and 0,5 mm.
4. OPTIMISATION OF CUTTING PARAMETERS
The model of optimization by genetic algorithms based on natural
biological evolution principle was selected for optimization of cutting
parameters in laser cutting. If compared with conventional optimization
methods, the genetic algorithms are more robust and universal and can be
used in all research areas. From the performed measurements of the
output and speed of laser cutting for different workpiece materials and
thickness and from the analysis of the cut quality (cut shape, cut
surface waviness and/or roughness and presence of burr on the workpiece
lower edge) the data for optimization of the laser cutting process were
obtained.
The focal distance changes depending on the type of lens (5"
and 7.5") and depending on the type and thickness of the material
cut. The optimization of cutting parameters by genetic algorithms was
carried out on the basis of the measurement results and the interaction
of the cutting parameters in laser cutting. The optimization can be
carried out with one, two or three variables and/or cutting parameters.
Here below, a practical example of the laser cutting optimization is
presented. The example of laser cutting optimization for material
X2CrNiMo17-12-2 for [CO.sub.2] laser cutting is presented. Figure 1
shows the photos of surface of the laser cut with optimized values of
the laser cut and with recommended (non-optimized) values of cutting
(smaller and higher cutting power) and the changes on the surface itself
of the laser cut, taking place in case of deviation from ideal values.
The optimization of cutting parameters by genetic algorithms was carried
out on the basis of the measurement results and the interaction of the
cutting parameters in laser cutting. The optimization can be carried out
with one, two or three variables and/or cutting parameters. In order to
confirm and/or verify the results obtained from the optimization
process, the results had to be verified still in practice. Here below, a
practical example of the laser cutting optimization is presented. The
example of laser cutting optimization for material X2CrNiMo17-12-2 for
[CO.sub.2] laser cutting is presented.
[FIGURE 1 OMITTED]
5. CONCLUSION
The paper describes the influence of various technological
parameters on quality of laser cutting by [CO.sub.2] laser system. The
cutting parameters (cutting speed, laser beam output power, frequency,
mode of operation, gas pressure etc.) affect the utilization of the
laser system and reduction of production costs. Presentation of
applicability is based on the practical example of optimization from
production by genetic algorithm method. Advantages of use of laser
systems are saving of material, possibility of machining different
materials of different thickness, high quality and productivity and
reduction of production costs.
6. REFERENCES
El-Kurdi Z., Ahmed A. & Mathew P. (2003). Monitoring and
control of laser cutting. Proceeding of the 17-International Conference
on Production Research, pp. 4-7 August, Blacksburg, Virginia, USA.
Haferkamp H., Goede M., Busse A. & Thurk O. (1998). On line
quality monitoring during laser beam cutting using a thermographic
system. C-ICALEO, pp. 11-1, November, 1998, Orlanda, USA.
Pietro P. & Yao Y.L. (1994). An investigation in characterizing
and optimizing laser cutting quality. Int. Journal of Machine Tools
Manufacture, Vol. 34, No. 2, pp. 225-243.
Rajaram N., Sheikh-Ahmed J. & Cheraghi S.H. (2003). CO>
laser cut quality of 4130 steel. International Journal of Machine Tools
& Manufacture, Vol. pp. 43, 351-358.
Steen W.M. (1991). Laser Material Processing. Springer-Verlag
London Limited, Germany.
Tonshoff H.K., Ostendorf A., Krai V. & Hillers O. (1999).
Process and condition monitoring features incorporated in laser heads,
ICALEO, pp. E109-E11815-18, November, San Diego, USA.
Table 1. Measuring system for measuring the temperature
Recommended Optimized Greater
Values values values
Workpiece thickness [mm] 3 3 3
Laser output P [W] 350 400 500
Cutting speed [mm/min] 1150 1400 1500
Gas pressure [kPa] 125 150 175
Focal distance of lens f [mm] 63,5 63,5 63,5
Distance of focus from 0 0 0
workpiece surface [z.sub.f]
[mm]
Nozzle to workpiece 2 2 2
distance s [mm]
Nozzle diameter d [mm] 2 2 2
