dc.description.abstract |
Sustainable manufacturing aims to develop methods to convert materials into finished
products while reducing consumption of natural resources and energy, reducing
environmental emissions and contamination, reducing health and safety risks, and retaining
the goal of better performance and economy to the users. Machining, which is a highly
energy intensive process, is a key manufacturing process for many products. The energy
consumed in machining process is nearly completely converted into heat and traditionally a
cutting fluid or coolant is employed as a flood to remove the heat generated during
machining. The negative ecological aspects of conventional cutting fluids include waste
disposal, release of harmful substances into the environment and hazardous working
conditions for the operators. Skin contact and inhalation of MWFs loaded with
microorganisms, biocides and toxic metal particles is the main cause of occupational diseases
of industrial workers in the metalworking industry. Stringent environmental regulations have
necessitated research into the reduction or elimination of harmful cutting fluids from the
machining processes.
Various researchers have investigated many different approaches for reduction or
elimination of cutting fluids, which include the use of high pressure water jet, cold water
mist, chilled compressed air, cryogenic liquid nitrogen, carbon dioxide and super-critical CO 2
spray, and Minimum Quantity Lubrication (MQL) machining. In MQL machining systems a
very small amount of lubricant is supplied to the cutting point along with air or inert gas
stream and the lubricant gets consumed in the cutting process itself and is not re-circulated,
hence there are no serious disposal or ecological issues, when compared with coolant assisted
machining. Mineral oils, synthetic chemicals, and vegetable oils have been extensively
applied as lubricants in MQL machining. Many researchers have also explored adding nano-
particles to the lubricating oil. However, the above-mentioned categories of MWFs for MQL
machining have many limitations and a better alternative is needed which should exceed the
performance of all these systems and be environment friendly.
Ionic liquids are a relatively new family of eco-friendly chemicals being actively
researched upon by scientists for chemical, pharmaceutical and engineering applications including many challenging tribological areas involving relatively high contact stresses and
temperatures. The ionic liquids, therefore, can be suitable green and effective candidates as
lubricants in MQL machining and their potential needs to be explored critically.
In the present research work, conventional oils used in MQL machining have been
replaced with ionic liquids applied as additives to a vegetable (Canola) oil. This research
work aims to investigate the effectiveness and fundamental action mechanisms of ionic
liquids when employed as lubricants in interrupted orthogonal machining under MQL
conditions.
Machining experiments were carried out under dry, flood and different MQL
conditions in order to investigate the influence of machining parameters and cutting
conditions on the tribological performance of different types of lubricant systems prepared by
combining different ionic liquids with vegetable (canola) oil and poly ethylene glycol (PEG).
The ionic liquids selected
hexafluorophosphate
for the
(BMIMPF 6 ),
study were 1-methyl
1-methyl
3-butyl
3-butyl
imidazolium
imidazolium
tetrafluoroborate
(BMIMBF 4 ), 1-methyl 3-butylimidazolium bis(trifluoromethyl-sulfonyl)imide (BMIMTFSI),
and tributyl(nonyl)phosphonium bis(2-ethylhexyl) phosphate. These ionic liquids were used
as additives to the base vegetable oil. Canola oil was used as the base vegetable oil. Among
the ionic liquids, BMIMPF 6 , BMIMBF 4 and BMIMTFSI were hydrophilic in nature and non-
soluble in oil while ionic liquid tributyl(nonyl)phosphonium bis(2-ethylhexyl) phosphate was
oil miscible. Another lubricant used in study was Poly Ethylene Glycol (PEG) with average
molecular wt. of 400. PEG has hydrophilic nature and was able to dissolve BMIMPF 6 . The
three main categories of lubrication combinations investigated in this study included: (i)
vegetable oil with non-miscible hydrophilic ionic liquid added via sonication, (ii) vegetable
oil in solution with oil-soluble hydrophobic ionic liquid, and (iii) hydrophilic ionic liquid in
solution with another hydrophilic base lubricant (PEG).
The analysis of force signals recorded in machining revealed that in light machining,
the machining force values obtained during MQL machining using vegetable oil with ionic
liquids remained consistently lower in magnitude than the force values observed in case of
machining under dry, flood, air jet, or MQL with neat vegetable oil conditions. Additionally,
the workpiece surface roughness obtained in machining under MQL condition with vegetable
oil containing ionic liquids was significantly lower than the values observed under dry, compressed air jet, flood cooling, and MQL machining with neat vegetable oil without any
additives. This further confirmed the generally superior tribological conditions existing
during MQL machining with vegetable oil containing ionic liquids as additives.
The element dot maps of Iron (Fe) obtained with Energy Dispersive Spectroscopy
(EDS), for the area near the cutting edge of the tool used in MQL machining with oil and
ionic liquid BMIMBF 4 , and BMIMPF 6 , clearly demonstrated the presence of workpiece
material adhering to the tool rake face, since this element was not present in detectable
quantities either in the cutting tool material or in any of the applied MWFs, over most of the
tool-chip contact zone. The element map for Fluorine (F) showed much higher density in the
areas where significant Iron deposits were present. This suggests that at the temperatures and
pressures prevailing at the tool chip interface in cutting at higher speeds the fluorine
containing ionic liquids disintegrated and liberated fluorine, which, being more
electronegative than any oxygen present in the environment, readily combined with freshly
exposed surfaces of the workpiece material and formed fluorides of iron. This is
hypothesized to be the dominant mechanism through which ionic liquids used in this study
work as lubricants in metal cutting at high cutting speeds and loads. The other tribologically
active elements present in the selected ionic liquids included sulphur and phosphorous. The
element maps for these elements and the EDS spectra show sulphur and phosphorous in trace
quantities only, suggesting that they did not bind effectively with the tool or workpiece
material.
The thermal decomposition temperature showed a strong positive correlation with
cutting forces and workpiece surface roughness at higher cutting speeds and loads. The
specific heat capacity (Cp), product of density and specific heat capacity (ρ.Cp), and the heat
absorbed during decomposition (ΔH - decomposition), all of which influence the cooling
capacity of the lubricant, however, did not seem to have any consistently strong relation with
machining forces, workpiece surface roughness and tool-chip contact length. The heat
extraction by the lubricants appears to be a transient phenomenon at the beginning of the cut,
as the Cp, ρ.Cp and ΔH (decomposition) show significant correlations only with the peak
cutting forces observed during tool entry in finish machining condition.
While machining under light cutting conditions at higher cutting speeds, the fluorine
containing ionic liquids, when used as additives to vegetable oil in a small quantity, yielded lower cutting forces as compared to those observed with neat vegetable oil. Such ionic
liquids may be suitable for high speed machining applications where the cutting forces are
low, but the cutting speeds are high enough to raise the cutting temperatures well above the
decomposition temperatures of the ionic liquids. Under heavy cutting conditions, the stresses
and temperatures are high enough even at low cutting speed, hence showing beneficial
effects of these ionic liquids. At higher cutting speeds however, the effect of ionic liquids in
heavy machining seemed to diminish. Similarly, while evaluating the effect of addition of
ionic liquids on the workpiece surface roughness, the improvement was more significant at
lower cutting speed than at higher cutting speed where there was no significant difference.
When an oil miscible ionic liquid was added to the vegetable oil it showed lower
cutting forces as compared to those of machining with neat vegetable oil at lower cutting
speed under both light and heavy cutting conditions. Again, the benefit disappeared at higher
cutting speeds. The decomposition temperature of the oil soluble ionic liquid used in the
study was designed to be lower than those of oil non-soluble ionic liquids. That is why the
effect was visible even at lower cutting speed under light machining conditions. Additionally,
it was observed that the solution in which ionic liquid was added in 1% concentration
performed better than the solution with 0.5% concentration under heavy cutting conditions,
suggesting that a higher concentration may give better results in more severe machining
applications.
When a hydrophilic lubricant (Poly Ethylene Glycol – PEG) was used as the MQL
fluid, it showed a significant improvement in the cutting forces at lower cutting speed under
light machining conditions. At higher speeds and higher loads it was seen that the addition of
a hydrophilic ionic liquid, which was completely soluble in PEG, produced lower machining
forces as compared to machining with PEG alone. The workpiece surface roughness,
however, was better while machining with neat PEG under most of the cutting conditions.
A thermal model has been developed for estimation of cutting temperatures utilizing
two dimensional finite difference method for transient heat conduction with inverse heat
transfer procedure. The estimated tool-chip interface temperatures were used to gain insight
into whether ionic liquids and other lubricants used in the studies would reach their
decomposition temperature or not during different cutting and lubricating conditions and,
thus, explain the mechanism of working of the applied MWFs under different conditions. The results indicate that when the temperature remains below thermal degradation
temperature the MWF’s physical properties, such as viscosity and density may influence its
efficacy to a greater extent. When the temperature goes beyond the degradation temperature
the lubricant will decompose and the decomposition products define the mechanism of
action.
From the thermal model it was observed that in light machining at low cutting speed
the cutting temperatures were estimated to be below thermal decomposition temperatures of
the lubricants employed. In this condition the viscosity of the lubricant played a dominant
role and lubricants with higher viscosity performed better in terms of yielding lower
measured machining forces. At higher cutting speed the temperatures increased beyond
decomposition temperature. In this case fluorine containing ionic liquid lubricants
decomposed and released fluorine, which readily bonded with freshly machined surfaces and
reduced the intensity of adhesion between the tool and chip, and between the tool and the
new workpiece surface, resulting in lower cutting forces. Decomposition of other ionic
liquids, which did not contain fluorine as the tribo-active element released upon
decomposition, however, did not yield the same extent of improvement in measured
machining forces or workpiece surface roughness.
Several directions for future work involving application of next generation ionic
liquid-based MWFs for MQL machining are identified based on the insight gained from
experimental observations and numerical modelling of thermal conditions in machining. |
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