Abstract
The mean arithmetic deviation of the roughness profile was investigated during cylindrical milling of the board edges. The machined materials were a medium-density fiberboard, medium-density fiberboard with single-sided lamination, and edge-glued spruce panel. Contactless and contact profilometers were used to measure the roughness. Both methods were evaluated and compared. Tungsten carbide blades with three different compositions and treatments were used. The effect of the cutting speed (20 m/s, 30 m/s, 40 m/s, and 60 m/s) and feed rate (4 m/min, 8 m/min, and 11 m/min) on the surface roughness was also monitored. The results of this study compared two different methods for determining the surface roughness. The measurements were more accurate with a contactless profilometer, but the price is higher than that of the contact method. The operation was also more complicated, and the measurement itself took longer with a contactless profilometer. The evaluation of individual surface quality variables was faster with a contact device. The best results in terms of the surface quality were achieved by lowering the feed rate and increasing the cutting speed.
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Medium-density Fiberboard (MDF) and Edge-glued Panels (EGP) after Edge Milling – Surface Roughness after Machining with Different Parameters
Miroslav Sedlecký, Monika Sarvašová Kvietková, and Richard Kminiak *
The mean arithmetic deviation of the roughness profile was investigated during cylindrical milling of the board edges. The machined materials were a medium-density fiberboard, medium-density fiberboard with single-sided lamination, and edge-glued spruce panel. Contactless and contact profilometers were used to measure the roughness. Both methods were evaluated and compared. Tungsten carbide blades with three different compositions and treatments were used. The effect of the cutting speed (20 m/s, 30 m/s, 40 m/s, and 60 m/s) and feed rate (4 m/min, 8 m/min, and 11 m/min) on the surface roughness was also monitored. The results of this study compared two different methods for determining the surface roughness. The measurements were more accurate with a contactless profilometer, but the price is higher than that of the contact method. The operation was also more complicated, and the measurement itself took longer with a contactless profilometer. The evaluation of individual surface quality variables was faster with a contact device. The best results in terms of the surface quality were achieved by lowering the feed rate and increasing the cutting speed.
Keywords: Roughness; Feed rate; Cutting speed; Edge milling; Medium-density fiberboard; Edge-glued panel
Contact information: Department of Wood Processing, Czech University of Life Sciences Prague, Kamýcká 1176, Prague 6- Suchdol, 16500 Czech Republic; *Corresponding author: risko.kminiak@gmail.com
INTRODUCTION
Wood is a readily available natural material that has been used by people throughout history. This raw material has become a part of everyday life without people realizing its immense significance and benefits. Wood is a renewable source of energy, and is used in various forms in everyday activities (Bekhtam et al. 2014; Gaff et al. 2016; Gottlöber et al. 2016). Processing wood into a usable material is a very complex technological process that has a long history (Kminiak and Gaff 2015; Kubš et al. 2016).
Wood processing primarily involves the homogenization of the mechanical and structural properties of the wood so that it is a technically defined material, and the transformation of sawmill waste into a material intended for further processing (Afanasiev 1962). Wood utilization is diverse, and its processing methods are equally so. Milling is currently coming to the forefront of processing. Milling is a chip-forming method in which a layer of the material is removed from the workpiece in the form of small individual chips by use of a multi-blade rotary tool, which is called a milling cutter (Kvietková 2015; Kvietková et al. 2015b; Kvietková et al. 2015c; Lahtela and Kärki 2016; Metsä-Kortelainen and Viitanen 2017).
During milling, the milling cutter rotates around its axis (main motion of the process) and its teeth gradually cut through the workpiece, which simultaneously moves against the tool (secondary motion of the process) (Prokeš 1982). Each blade of the milling cutter gradually removes short chips from the machined material, so that the cutting process is not interrupted (Lisičan 1996).
The aim of milling is to create a workpiece with the required dimensions, shape, and surface quality (Welzbacher et al. 2011; Kvietková et al. 2015a). By using various types of milling tools, it is possible to machine external and internal surfaces that are primarily flat, but also surfaces that are shaped, irregular, slanted, have grooves, half grooves, rotary surfaces, etc. (Mikolášik 1981). The possibility of precision production and its wide application have given milling an important place in production. Milling is used to machine an increasing number of materials, not only wood, but also wood-based materials, such as agglomerated materials, and new materials.
A summary of all of the factors that affect the milling process can be defined as the cutting conditions (Bekéš et al. 1999; Welzbacher and Brischke 2008). For optimal milling, i.e. a process that is productive and economically-viable, it is necessary to understand the individual milling conditions and their interconnection (Kotěšovec 1981). The basic cutting conditions are the feed rate, cutting speed, and cutting depth. However, the milling process is also largely affected by other factors, such as the machined material, dimensions and shape of the cross section of the chip, overall stiffness of the machining system, and tool geometry (Sova 2001). The optimal conditions in the milling process are affected by different cutting conditions, as well as other factors, such as the machine tool and requirements given by the technical documentation. It is therefore very important to adhere to the parameters recommended by the manufacturers.
The roughness (Ra) of a milled surface is of technological, technical, and kinematic origin. Roughness results from the cutting of cells and annual rings, moisture content, and regularity of the wood grain (Sedlecký and Sarvašová Kvietková 2017; Söğütlü 2017). Even though the quality of the surface is much smoother than that of cut surfaces in most cases, they are still not perfectly smooth and will always have a certain degree of Ra. The technical causes of Ra lie in the precision of the knife setting in the shaper cutter head (or the precision of the milling cutter grinding), degree of blade dullness, and vibration and chatter of the milling cutter. These causes manifest themselves by the pulling of wood fibers by dull blades and irregularity of the width of waves on the milled surface (Lisičan 1996; Očkajová et al. 2016; Mračková et al. 2016).
The kinematic factor that affects Ra is the cycloid shape of the relative motion of the blade in the wood, and as a result it is impossible to theoretically achieve a perfectly flat surface with a rotary tool, even if there were no technological or technical causes. This is simply because each tool cutter creates a cutting surface that is curved. The advantages of milling are a relatively high performance and good surface quality. The workpieces exhibit some surface Ra after milling, which is manifested by microscopic (Ra) or macroscopic changes (waviness, depressions, ridges, and partially pulled fibers). The overall possibilities for evaluating the surface are given in the standard ČSN EN ISO 4287 (1999). All of the parameters defined in the standard can be applied to the primary, roughness, and waviness profiles. The quality of the surface of products created by the woodworking industry is most often evaluated by its mean arithmetic deviation of the profile (Pa, Ra, Wa). The aim of this article was to monitor variations in the surface quality, which was evaluated based on the mean arithmetic deviation of the roughness profile (Ra).
EXPERIMENTAL
Materials
The following three materials were machined: a medium-density fiberboard (MDF), medium-density fiberboard with single-sided lamination (MDF-L), and edge-glued panel (SEGP) from Norway spruce (Picea abies L.). The boards were used to make 500 mm x 500 mm x 18 mm samples. All of the samples were stored under standard conditions in a climatized room (relative humidity = 65% ± 3% and temperature = 20 °C ± 2 °C) for two weeks to achieve a moisture content of 12%. The density was determined according to ČSN EN 323 (1994) and is given in Table 1.
Table 1. Properties of the Construction Materials
Methods
Edge milling was performed with a one-spindle edge milling machine (FVS) with a STEFF 2034 feeding system (Maggi Technology, Certaldo, Italy). The milling cutters were mounted on a two-blade milling cutter head (Felder, Hall in Tirol, Austria). Both blades were always engaged, and the material removal thickness was 1 mm. The side of the board was milled three times along its length. The variable parameters of the edge milling and tool geometry are listed in Table 2.
Table 2. Cutting Parameters of the Edge Milling and Cutter Geometry
Three types of milling cutters were selected for the milling process, which were HW1, HW2, and HW1 CrTiN. The milling cutters were manufactured by Leitz GmbH & Co. KG (Oberkochen, Germany). The HW1 milling cutter is primarily designed for machining solid wood, HW2 is designed for agglomerated materials, and the HW1 CrTiN milling cutter is designed for hard agglomerated materials. The last milling cutter is made of the same material as the HW1 milling cutter and has a CrTiN coating. The coating was applied by a physical vapor deposition method by SHM, s.r.o. (Šumperk, Czech Republic). The basic properties of the milling blades are listed in Table 3.
Table 3. Properties of the Milling Blades
Based on the combination of the milling parameters (cutting speed and feed rate), tools (material and treatment of blades), and materials (MDF, MDF-L, and SEGP), 108 samples were created for edge milling.
An optical profilometer (LEXT 3D, Olympus, Praha, Czech Republic) with a measuring laser microscope (OLS4100, Olympus, Praha, Czech Republic) (contactless measurement) and profilometer (Form Talysurf 50 Intra, Taylor Hobson, Leicester, UK) (contact measurement) were used for taking measurements. The Ra was measured according to ČSN EN ISO 4287 (1999).
When measuring the surface quality with the contactless profilometer, optics predefined for measuring surface quality were used (MPlanApoN, 50x/0.95 LEXT, ∞/0/FN18). The light beam radius (R) was 0.2 µm. Additionally, a λc profile filter was used.
A standard arm with a conical tip R of 2 µm was used for measuring with the contact method. Additionally, a λc profile filter was used.
Table 4. Basic Lengths for Measuring the Ra
Settings used for both profilometers are colored in blue
ln – evaluated length (length in X direction used for assessment of the evaluated profile
RSm – average width of roughness elements (arithmetic mean diameter Xs of profile elements in the range lc
lc – base length (ln = 5 x lc); λc – cut-off value; λc = c
lt – total measured length (ln increased by start and stop)
rtip– arm radius
The Ra values were evaluated with STATISTICA 13 software (Statsoft Inc., Tulsa, USA) using an analysis of variance. The analysis used a 95% confidence interval, which represented a significance level of 0.05 (P < 0.05).
RESULTS AND DISCUSSION
Based on the level of significance, it was clear that each of the monitored factors and their interaction had a significant effect on the Ra after edge milling for both of the measuring methods (Tables 5 and 6).
Table 5. Effect of the Factors and their Interaction on the Ra – Contactless Method
Table 6. Effect of the Factors and their Interaction on the Ra – Contact Method
When comparing the two methods of measuring the Ra, a significant difference was found between all of the monitored cutting speeds (Fig. 1). The closest Ra values were measured at a cutting speed of 30 m/s. The average Ra values measured by the contactless method were 13.5% higher than those from the contact method. The greatest differences were measured at a cutting speed of 20 m/s. The average Ra values from the contactless method were 26.39% higher than those from the contact method. The contactless method exhibited higher Ra values.
After the effect of the cutting speed on the surface Ra was evaluated, it was concluded that increasing the cutting speed improved the surface quality. A similar finding was confirmed by the research by Yasir et al. (2016).
Fig. 1. Effect of the cutting speed on the Ra
When comparing the contact and contactless methods for assessing the effect of the feed rate on the surface Ra, a significant difference was found at all of the feed rates. Figure 2 shows that the individual curves were almost the same as each other at similar intervals. The average Ra values for the contactless method at a feed rate of 4 m/min were 19.7% higher than those for the contact method. At a feed rate of 8 m/min, the average Ra values for the contactless method were 18.8% higher, and at the highest monitored feed rate, they were 17.1% higher. Based on the results obtained in the evaluation of the feed rate, it was found that higher Ra values were exhibited by the contactless method.
According to Maher (2008), the surface Ra increased with the feed rate, which was also confirmed by this research when comparing the feed rates of 4 m/min with 8 m/min, and 4 m/min with 11 m/min. The research by Wilkowski et al. (2015) clearly showed that decreasing the feed rate improved the quality of the machined surface, but machining itself naturally took longer.
Fig. 2. Effect of the feed rate on the Ra
Figure 3 shows the effect of the cutter type on the resulting Ra of the milled surface. The largest range of values was found when using the HW1 CrTiN blade, where the average Ra values measured by the contactless method were 27.0% higher than those from the contact method. With the HW1 blade, the average Ra values measured by the contactless method were 15.2% higher than those measured by the contact method. The smallest difference was found with the HW2 blade, where the average Ra values measured by the contactless method were 13.6% higher than those measured by the contact method. The results recorded during the evaluation of the cutter type showed that the contactless method exhibited higher Ra values. For both surface Ra measurement methods, the HW1 milling cutter was the most suitable. Laina et al. (2017) found that the machining process and wood species greatly affects the resulting surface Ra.
Fig. 3. Effect of the cutter type on the Ra
Fig. 4. Effect of the material type on the Ra
Even for the last criterion (material type), a significant difference was found between the contact and contactless methods of measuring the surface Ra. The average Ra values of the SEGP measured by the contactless method were 14.9% higher than the average Ra values measured by the contact method. In the case of the MDF, there was an increase of 14.3%. The greatest percentage increase in the average Ra values was recorded for the MDF-L (25.01%). As with the other monitored factors, the contactless method also exhibited higher Ra values for the different material types (Fig. 4).
It was confirmed that the material density has a great effect on the machinability characteristics (Lin et al. 2006). Based on the results measured by the contact and contactless methods, it was concluded that the highest Ra values were observed in the MDF, which had the highest density, and the lowest Ra values were observed in the SEGP, which had the lowest density. The type of material was proven to have a very significant effect on the Ra of the machined surface.
Table 7. Percentage Differences between the Contact and Contactless Methods for Measuring the Ra
vc – cutting speed; vf – feed rate; ΔRa – percentage difference between the measured Ravalues
Table 7 shows the percentage differences between the methods used for determining the Ra. The results indicated that higher Ra values were measured by the contactless method with the same settings for both of the profilometers in all of the cases. The total difference in the average Ra values was 15.5%. These differences were mainly because of the different R values of the arm or optical beam (2 µm/0.2 µm). Hendarto et al. (2006) determined the effect of various methods of the surface Ra evaluation and the changes in values between methods depending on the filtration used and partial difference of certain methods. The conclusions of the research by Budakçı et al. (2013) indicated that the laser method is more suitable for determining the surface quality than the contact method.
Table 8 shows an evaluation of the effect of factors on the surface Ra measured by the contactless method using Duncan’s test. The Ra values measured by the contactless method indicated that there was a statistically significant difference between the cutting speeds of 20 m/s and 30 m/s. There was no statistically significant difference in the Ra values between the cutting speeds of 40 m/s and 60 m/s. This can be seen in Fig. 4, where it was clear that the differences in the Ra were not large after increasing the cutting speed from 40 m/s to 60 m/s. No statistically significant difference in the Ra values was confirmed between the feed rates of 8 m/min and 11 m/min. As with the contact method for measuring the Ra, the effects of the tool and material types were confirmed to be significant with a significance level of 0.000 for the contactless method.
Table 8. Comparison of the Effects of the Factors on the Ra using Duncan’s Test – Contactless Method
Table 9 shows an evaluation of the effect of factors on the surface Ra measured by the contact method using Duncan’s test. A statistically significant difference was observed between the Ra values at the cutting speeds of 20 m/s and 30 m/s. At a cutting speed of 30 m/s, a significant difference was confirmed in comparison with all of the cutting speeds. The tool and material types were proven to be factors that very significantly affected the resulting surface Ra. For the feed rate, there was an insignificant difference between the feed rates of 8 m/min and 11 m/min.
Table 9. Comparison of the Effects of the Factors on the Ra Value Using Duncan’s Test – Contact Method
Figures 7, 8, and 9 show the synergistic effect of all of the monitored factors on the Ra values.
After using the contactless method for measuring the Ra of the MDF, it was discovered that the values ranged from 24 µm to 37 µm. The lowest Ra values were measured with the HW1 milling cutter at a feed rate of 4 m/min and cutting speed of 60 m/s. In contrast, the highest values were recorded with the HW1 CrTiN milling cutter at a feed rate of 4 m/min and cutting speed of 30 m/s.
The value range when evaluating the Ra with the contact method was 21 µm to 29 µm. The lowest values were found using the HW1 milling cutter at a feed rate of 4 m/min and cutting speeds of 20 m/s, 30 m/s, and 60 m/s.
The measured Ra values showed that most of the best Ra results were achieved using the HW1 blade, even though the lowest values were not achieved with all of the factor combinations. The effect of the other blades seemed ambiguous.
Fig. 5. Effect of the cutting speed, feed rate, and cutter type on the Ra of the MDF – contactless method on the left, contact method on the right
With the contact method for measuring the surface Ra of the MDF-L, the Ra values ranged from 19 µm to 27 µm (Table 9). The minimum values were found with the HW1 cutter at a feed rate of 4 m/min and cutting speed of 40 m/s, and with a feed rate of 11 m/min and cutting speed of 30 m/s. The highest Ra values were recorded with the HW2 and HW1 CrTiN cutters.
When measuring the Ra of the MDF-L with the contact profilometer, the Ra values ranged from 17 µm to 22 µm. The minimum mean Ra values were achieved with a feed rate of 4 m/min and cutting speeds of 40 m/s and 60 m/s for the HW1 milling cutter, and a feed rate of 4 m/min and cutting speed of 20 m/s for the HW1 CrTiN milling cutter.
Fig. 6. Effect of the cutting speed, feed rate, and cutter type on the Ra of the MDF-L – contactless method on the left, contact method on the right
The Ra values of the SEGP when measured by the contactless method were in the range of 2 µm to 13 µm. The lowest Ra value was measured with the HW2 milling cutter at a feed rate of 4 m/min and cutting speed of 60 m/s. In contrast, the highest Ra values were recorded with the HW1 CrTiN milling cutter at a feed rate of 4 m/min and cutting speed of 20 m/s.
Table 10. Average Ra Values – Contactless Method
Values in parentheses are the coefficients of variation (CV) in %
Table 11. Average Ra Values – Contact Method
Values in parentheses are the CV in %
Škaljić et al. (2009), who dealt with the dependence of the surface quality on the feed rate in the machining of spruce wood, confirmed similar dependencies, i.e. the Ra decreased as the cutting speed increased.
The Ra values of the SEGP were generally lower than for the other materials. The Ra ranged from 3 µm to 9 µm. The minimum Ra value was measured with the HW1 CrTiN milling cutter at a feed rate of 4 m/min and cutting speed of 60 m/s.
It was not possible to unequivocally determine which instrument was the most suitable from the results, mostly because of the heterogeneous structure of the SEGP in its cross section.
Fig. 7. Effect of the cutting speed, feed rate, and cutter type on the Ra of the SEGP – contactless method on the left, contact method on the right
Tables 10 and 11 show the average Ra values measured for each set of test specimens, as well as their coefficients of variation.
From the overall results, it was concluded that the optical contactless method was more accurate than the contact method. As was mentioned, the differences in the Ra values were caused by the different arm/beam R values. The contact method was limited by its own mechanical filter, which corresponded to the R of the arm (Fig. 8.).
For the machining parameter settings, the feed rates should be lower at higher cutting speeds to achieve the best results.
Fig. 8. Influence of radius on the measurement accuracy (left – contact method; right – contactless method)
CONCLUSIONS
- With the contactless method, a standard dependence between the cutting speeds of 20 m/s, 30 m/s, and 40 m/s was demonstrated, i.e. the surface Ra decreased as the cutting speed increased. With a further increase to 60 m/s, the surface quality slightly increased compared with the cutting speed of 40 m/s. These increased values were likely because of increased shaft vibrations. The differences in the Ra values were relatively insignificant for both methods.
- A clear dependence between the feed rate and surface quality was demonstrated. As the feed rate increased, the resulting quality declined. Both methods used to measure the Ra had an almost identical effect.
- When evaluating the individual types of milling cutters, it was found that the most suitable tool for machining the given materials was the HW1 milling cutter. With the contact method, the HW1 CrTiN milling cutter was shown to be more suitable than the HW2 milling cutter. In contrast, the HW2 milling cutter proved to be more suitable than the HW1 CrTiN milling cutter for the contactless method.
- The machined material significantly affected the milling process. The Ra values during the machining of the MDF and MDF-L were 3.5 times higher than during the milling of the SEGP for both methods.
- It was clear from the comparison of the contactless and contact methods for measuring the Ra that more accurate results were obtained by the contactless method. The Ra measured by the contactless method was 15.5% higher than those from the contact method. Therefore, it is better to use an optical profilometer to evaluate the Ra. The disadvantages of the optical profilometer are its higher purchase price, expensive maintenance, and complicated operation.
ACKNOWLEDGMENTS
The authors are grateful for the support of the Internal Grant Agency (IGA) of the Faculty of Forestry and Wood Sciences, project No. A 12 – 16.
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Article submitted: November 24, 2017; Peer review completed: January 7, 2018; Revised version received: January 28, 2018; Accepted: January 29, 2018; Published: January 30, 2018.
DOI: 10.15376/biores.13.1.2005-2021