*Corr. Author’s Address: University of Ljubljana, Faculty of Mechanical Engineering, Aškerčeva 6, 1000 Ljubljana, Slovenia, deepa.kareepadathsanthos@fs.uni-lj.si 435
Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443 Received for review: 2023-05-27
© 2023 The Authors. CC BY 4.0 Int. Licensee: SV-JME Received revised form: 2023-09-12
DOI:10.5545/sv-jme.2023.658 Original Scientific Paper Accepted for publication: 2023-10-04
Grinding of Cemented Carbide Using a Vitrified Diamond Pin  
and Lubricated Liquid Carbon Dioxide
Kareepadath Santhosh, D. – Pušavec, F. – Krajnik, P.
Deepa Kareepadath Santhosh
1,*
 – Franci Pušavec
1
 – Peter Krajnik
1,2
1 
University of Ljubljana, Faculty of Mechanical Engineering, Slovenia 
2 
Chalmers University of Technology, Department of Industrial and Materials Science, Sweden
Despite extensive research on grinding of cemented carbide, few studies have examined abrasive machining of this material using small-
diameter super abrasive tools (also known as grinding pins/points), especially with respect to varying cooling-lubrication methods. This study 
therefore focuses on a comparative experimental investigation of three such methods - dry, emulsion, and lubricated liquid carbon dioxide 
(LCO
2
-MQL). The performance of these methods and the resulting grindability are examined in terms of grinding forces, force ratios, specific 
energy, and through the analysis of wheel loading. The results show that LCO
2
-MQL grinding has lower grinding forces (normal forces – 8 % 
to 145 % lower than dry grinding, and 18 % to 33 % lower than emulsion grinding and tangential forces – 4 % to 66 % lower than dry grinding 
and 28 % to 78 % lower than emulsion grinding) and specific energy 24 % to 51 % lower compared to dry grinding and 64 % to 69 % lower 
than emulsion grinding, indicating its potential for efficient material removal. However, a challenge with high wheel loading was observed 
with LCO
2
-MQL, likely due to the lack of oxygen in the CO
2
 grinding atmosphere. Despite this issue, the LCO
2
-MQL method shows potential for 
efficient operations, especially at higher aggressiveness values where the lowest specific energies were achieved. These results provide new 
insights into various aspects of cooling-lubrication methods in the pin grinding of cemented carbides.
Keywords: diamond, grinding, cemented carbides, cooling-lubrication, carbon dioxide
Highlights
• 	 Analysis of different cooling-lubrication conditions reveals LCO
2
-MQL as a potentially superior method.
• 	 LCO
2
-MQL reduces grinding forces and specific energy in pin grinding.
• 	 LCO
2
-MQL achieves the lowest force ratio, indicating superior lubrication capability.
• 	 Wheel loading is present in all cooling-lubrication methods but is most severe in LCO
2
-MQL.
0  INTRODUCTION
Cemented carbides, known for their excellent 
combination of hardness, wear resistance, and 
toughness, have become the most common cutting 
tool materials for machining applications. The 
combination of the high hardness of tungsten-
carbide (WC) grains cemented into a composite by 
a ductile Co binder yields outstanding mechanical 
properties [1]. Cemented carbides are considered 
hard-to-machine materials due to their high strength 
at elevated temperatures and low modulus of elasticity 
[2]. This work focuses on the GC1130 grade developed 
by Sandvik Coromant, which features a high hardness 
and wear-resistant substrate due to its high chromium 
content and fine-grained microstructure. The WC 
grain boundaries are structured to enhance edge 
toughness, and the grade is designed to resolve tool 
life and issues associated with chipping, flaking, and 
thermal cracking in milling operations.
Due to its inherent hardness, the production of 
cemented carbides almost always includes grinding 
using diamond grinding wheels at the end of the 
manufacturing value chain. Diamond wheels typically 
feature a metal bond, or a hybrid, resinoid-metal, bond. 
The grinding of cemented carbides is in high demand 
in the industry, and these processes are accompanied 
by high grinding forces, specific energy, wheel wear, 
and low material removal rates [3]. Another concern, 
common on the shop floor but not extensively 
researched, is wheel loading, which is especially 
challenging when grinding with low aggressiveness. 
In a loaded wheel, the workpiece material becomes 
embedded within the pores of the diamond wheel, 
which prevents normal grinding action, i.e., material-
removal by chip formation. Badger reported that 
loading of cemented carbide workpiece material does 
not appear to be caused by the high ductility of the 
workpiece material or a chemical reaction, but rather 
by the short, WC-Co chips [4]. The author proposed 
the loading be removed via stick-conditioning. In 
production, grinding machines have conditioning 
(sticking) done by truing using aluminum oxide 
wheels, often used in-process while grinding. In some 
cases, an external truing wheel can be used [5]. In 
the most challenging applications, diamond-wheel 
conditioning is done on metal-bonded wheels by spark 
electric-discharge dressing, which requires a special 
wheel design and grinding fluid to facilitate electrical 
conductivity [6]. 
Grinding fluids reduce the friction in the contact 
between the tool and the workpiece. This is achieved 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443
436 Kareepadath Santhosh, D. – Pušavec, F. – Krajnik, P.
through lubrication. Grinding fluids also dissipate 
heat from the grinding zone, i.e., they provide cooling. 
While most industrial grinding of cemented carbides 
is done using (petroleum-based) straight oils, it is 
also possible to use a solution synthetic fluid, which 
is considered more environmentally friendly due 
to the large proportion of water (e.g., 95 %) in the 
grinding fluid. Both types of grinding fluids typically 
contain additives, such as chemical substances to 
inhibit cobalt leaching, i.e., removal of the cobalt 
binder. To further improve sustainability, it is viable 
to drastically reduce the amount of grinding fluids 
used [7]. For example, minimum quantity lubrication 
(MQL) technology can be used in the grinding of 
cemented carbides, which employs an oil-mist to 
lubricate the grinding process at a consumption rate 
that is on a mL/hour scale [8]. Nevertheless, while 
MQL can lubricate the process, it has limited cooling 
capability [9]. Therefore, recent innovative solutions 
include using subcooled MQL, for example, by using 
liquid nitrogen to reduce the temperature of the MQL 
oil mist [10], or by dissolving the oil in liquid carbon 
dioxide (LCO
2
), which upon exiting a nozzle drops to 
a temperature of −78.5  °C and freezes the oil droplets, 
which measure only 2 micrometers in diameter [11]. 
Such advanced solutions to cooling and lubrication 
have not yet been explored in the grinding of cemented 
carbides. This work focuses on investigating the LCO
2
 
solution, as this technology has proven superior in 
other machining applications, such as in drilling [12] 
and milling [13]. Even though the pressure in LCO
2
 
cylinder is nearly 6 MPa (60 bar), it is likely that the 
air barrier formed around a grinding wheel rotating 
at high speed would prevent the LCO
2
 from entering 
the grinding zone and causing it to be diverted 
elsewhere. Therefore, the first grinding investigation 
using LCO
2
 intentionally involved using a tool with a 
much smaller diameter that does not create a distinct 
air barrier and is hence a lower obstacle to gas/oil-
mist penetration. In conventional grinding, wheel 
diameters typically measure 400 mm to 600 mm, 
whereas the diameter of the grinding pins in focus 
here was only 6 mm. Grinding with small (generally 
≤15 mm) fixed-abrasive tools, such as diamond pins 
mounted on a high-speed machining center is often 
referred to as pin or point grinding [14], which has 
proven to be a capable process for machining of hard 
and brittle materials with high dimensional accuracy 
and fine surface finish demands [15], due to a small 
grit-penetration depth. The available research on pin 
grinding of cemented carbides is limited. Kadivar et 
al. [16] studied the process mechanics and surface 
integrity of micro-grinding of titanium alloys and 
ceramics. Arrabiyeh et al. [17] studied the importance 
of process parameters in the micro-grinding of 
hardened steel. Morgan et al.'s [18] study, specifically 
focused on cemented carbides, revealed that the 
specific energy was initially high at the onset of 
tool-workpiece contact, but rapidly decreased to an 
almost constant value of 500 J/mm
3
 after a stable tool 
engagement. Huang and Kuriyagawa [19] performed 
grinding of cemented carbide used for mold inserts, 
achieving better form accuracy and surface roughness 
even though they found small chipping of the material.
Based on the previous research, it has been 
observed that critical issues such as high rotational 
speeds, significant tool deflection, uneven grit 
protrusion, varying bond layer thickness, rapid tool 
wear, sensitivity to runout resulting in vibrations, 
and excessive tool loading are encountered [20]. 
While challenges such as wear and deflection can be 
addressed by optimizing grinding parameters, it was 
recognized that more research is needed, particularly 
in the areas of cooling and lubrication, and the 
investigation of vitrified pins, as most studies have 
focused primarily on electroplated (single layer) tools. 
In summary, research on pin grinding, particularly 
for cemented carbide materials, remains limited. 
Given this knowledge gap, the objective of the 
present study is to investigate the effects of various 
cooling-lubrication methods, including dry machining 
conditions as an extreme reference, on the grinding of 
cemented carbide using a vitrified diamond grinding 
pin. A secondary objective is to investigate the wheel-
loading phenomena associated with different cooling-
lubrication methods. The insights gained from this 
research could provide valuable information for future 
efforts to extend these experiments to conventional 
grinding applications using LCO
2
.
1  EXPERIMENTAL
Pin grinding experiments were conducted using 
the Sodick MC 430L high-speed milling machine, 
The employed grinding tool was a vitrified-bonded 
diamond pin (D32-46-150-V-3195) mounted on 
a tungsten-carbide shaft, produced by Meister 
Abrasives. The pin had a diameter of 6 mm. 
The workpiece material chosen was an uncoated 
cemented carbide blank (GC1130 grade), designed 
for a gear-cutting insert and fabricated from the fine-
grained, high-chromium by Sandvik Coromant. This 
workpiece, with dimensions of 85 mm × 15 mm × 13 
mm, was subject to hardness testing with a Vickers 
microhardness tester, yielding a hardness value of 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443
437 Grinding of Cemented Carbide Using a Vitrified Diamond Pin and Lubricated Liquid Carbon Dioxide 
79 HV . Fig. 1 shows images of both the tool and the 
workpiece utilized in the grinding experiments.
a) 
b) 
Fig. 1.  a) Diamond grinding tool, and  
b) cemented carbide workpiece
After each test, the grinding wheel underwent 
a conditioning and cleaning process using a hand-
sticking method with a fine-grit mesh silicon-carbide 
stone. The grinding experiments consisted of five 
varying grinding wheel speeds, ranging from 4 m/s to 
12 m/s, while maintaining a constant workpiece speed 
(100 mm/min) and depth of cut (10 µm). This range in 
grinding wheel speeds provided six distinct grinding 
aggressiveness conditions. Table 1 lists the utilized 
grinding parameters and the corresponding calculated 
aggressiveness numbers, Aggr.
Table 1.  Grinding parameters used in the experiments
Experiment 
no.
Wheel 
speed 
[m/s]
Workpiece 
speed  
[mm/min]
Depth of cut 
[µm]
Aggr
[-]
1 12 100 10 5.68
2 10 100 10 6.82
3 8 100 10 8.52
4 6 100 10 11.36
5 4 100 10 17.04
Fig. 2 illustrates the experimental setup used 
for this study. A Kistler Type 9129AA dynamometer 
was employed to measure the normal and tangential 
grinding forces. During the LCO
2
-MQL trials, the 
dynamometer was insulated to minimize potential drift 
and bias in force readings stemming from the low-
temperature effects on the piezoelectric dynamometer. 
To assure the reliability and reproducibility of the 
results, each experimental test was replicated four 
times.
Fig. 2. Experimental setup
The tool's topography following each experiment 
was initially assessed utilizing a Keyence VHX 6000 
digital microscope. Furthermore, an FEI/Philips 
XL30 ESEM (Environmental Scanning Electron 
Microscope) was employed to examine wheel surface 
and ascertain potential wheel loading or clogging 
issues.
Three different cooling-lubrication conditions 
were utilized in the grinding experiments: dry, 
emulsion, and LCO
2
-MQL grinding. For "emulsion 
grinding" a conventional water-based cutting 
fluid in the form of a soluble oil emulsion with a 
concentration of 6 % was employed. The LCO
2
-MQL 
system deployed, ArcLub One, was developed at the 
University of Ljubljana, Slovenia. This novel cooling-
lubrication approach involves a single-channel supply 
of a pre-mixed blend of LCO
2
 and oil, conveyed 
as MQL. As nonpolar oils, which are completely 
soluble in LCO
2
, lead to smaller oil droplet sizes and 
more uniform distribution in MQL, a low-viscosity, 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443
438 Kareepadath Santhosh, D. – Pušavec, F. – Krajnik, P.
nonpolar oil was selected as the lubricant [11] and [21]. 
The chosen lubricant was HAROLBIO 0, a petroleum-
free, saturated synthetic ester with a viscosity index of 
152 (ASTM D 2270). An external nozzle was used to 
deliver the cooling lubricant to the grinding zone.
Fig. 3.  LCO
2
-MQL grinding set up
2  RESULTS AND DISCUSSION
In this section, an analysis of the results is presented, 
focusing on the evaluation of the grinding process 
through grindability aspects such as grinding forces, 
grinding force ratios, grinding specific energy, wheel 
loading, and wheel topography. The significance 
and novelty of the results are discussed. Limitations 
associated with the techniques used and the results 
presented are also highlighted.
2.1  Grinding Forces
The normal and tangential grinding forces were 
measured across four repetitions. Since the measured 
grinding forces remained relatively constant across 
these repetitions, average grinding force values were 
used in Figs. 4 and 5 to show their variation with Aggr 
and cooling-lubrication conditions. Both tangential 
and normal grinding forces were found to decrease 
with an increase in cutting speed – an expected result 
given that higher cutting speeds yield smaller Aggr 
values. In all cases, normal forces exceeded tangential 
grinding forces, an observation commonly noted in 
conventional grinding operations as well.
Fig. 4.  Normal grinding forces vs. Aggr
Fig. 5.  Tangential grinding forces vs. Aggr
The normal grinding forces are lower in LCO
2
-
MQL grinding for the first five experiments and range 
from 1.2 N to 4.09 N, followed by emulsion and dry 
grinding. The tangential grinding forces are also lower 
for LCO
2
-MQL grinding and range from 0.25 N to 
1.5 N, followed by dry and emulsion grinding. The 
grinding force values were found to be exceptionally 
high in the last experiments of emulsion and LCO
2
-
MQL grinding due to excessive wheel wear and wheel 
loading. The sixth experiment at the highest Aggr 
is clearly an outlier, and hence not a representative 
case of normal grinding conditions. The normal 
and tangential grinding forces are comprised of two 
components, one due to cutting and one due to sliding 
on the wear flats [22]. The low tangential grinding 
forces observed in LCO
2
-MQL grinding indicate 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443
439 Grinding of Cemented Carbide Using a Vitrified Diamond Pin and Lubricated Liquid Carbon Dioxide 
efficient shear in the grinding zone and lubrication. A 
boundary-lubricating film was likely formed through 
polar group adsorption [11]. The lubricating film 
allows the oil to penetrate the grinding zone, which 
helps to prevent issues such as evaporation, and 
adhesion that can occur due to high temperatures, 
when the lubricant layer is sufficiently thick, it 
provides an effective lubrication effect, further 
reducing grinding forces [23]. Hence, the combined 
effect of LCO
2 
and MQL can enhance the formation 
of the lubricating film. This combination facilitates 
a continuous lubrication effect, which contributes to 
the reduction of grinding forces and friction [24]. The 
grinding forces are higher under dry grinding because 
of the excessive sliding and plowing action [25]. 
One can also observe very steady levels of normal 
and tangential forces in LCO
2
-MQL, which indicate 
minimal tool wear, until its collapse [26] at excessive 
(Experiment 6) grinding condition at the highest 
tested Aggr.
The grinding force ratio is further analyzed as it 
provides indirect information regarding the efficiency 
of the grinding process. It can characterize the 
lubrication effect at the wheel/workpiece interface. 
A high grinding force ratio suggests poor lubrication 
in the grinding zone, whereas improved lubrication 
corresponds to a lower force ratio. The force ratio 
in grinding is synonymous with the coefficient of 
friction between sliding surfaces. For hard materials, 
the coefficient of friction is high, indicating worse 
grindability [27]. The following expression is used to 
calculate the grinding force ratio:
 μ = F
T
 / F
N 
, (1)
where F
T
 is the tangential grinding force, and F
N
 is the 
normal grinding force.
Fig. 6 shows the grinding force ratios under 
varying cooling-lubrication conditions. The grinding 
force ratios for dry grinding range from 0.32 to 0.38. 
In comparison, grinding with emulsion gives ratios 
between 0.50 and 0.82, representing an increase of 
56 % to 116 % compared to dry grinding. On the 
other hand, LCO
2
 shows the lowest force ratios, 
ranging from 0.21 to 0.37, representing a 3 % to 34 
% decrease compared to dry grinding and a 55 % to 
58 % decrease compared to emulsion grinding. The 
grinding force ratio is maximum under emulsion 
grinding followed by dry grinding. The grinding force 
ratio in LCO
2
-MQL grinding is lower compared to 
that in dry and emulsion grinding, indicating that the 
grindability, with respect to friction in the grinding 
zone, is enhanced with LCO
2
-MQL grinding. The 
penetration of LCO
2
-MQL into the grinding zone 
creating a boundary lubrication layer provides better 
lubrication, hence reducing friction [23].
2.2.  Specific Grinding Energy
Specific grinding energy, u, is a fundamental parameter 
for gauging the efficiency of the grinding process. 
This quantity is defined as the energy expended 
per unit volume of material removed [28]. Specific 
energy is dependent on the tangential grinding force, 
the employed grinding parameters, the workpiece 
material's grindability, the tool's topography, and the 
tribological conditions in the grinding zone, which are 
largely determined by the cooling-lubrication method 
Fig. 6.  Grinding force ratios vs. Aggr

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443
440 Kareepadath Santhosh, D. – Pušavec, F. – Krajnik, P.
used. The following equation can be used to calculate 
the specific energy [28]:
 u = F
T
 V
s
 / (V
w
 a b) (2)
where F
T
 is the tangential grinding force, V
s 
is the 
wheel speed, V
w 
is the workpiece speed, a is the depth 
of cut, and b is the grinding width of cut.
Badger et al. [29] introduced the dimensionless 
aggressiveness number, Aggr, a fundamental 
parameter encapsulating the geometry and kinematics 
of a grinding process. In this study, Aggr was therefore 
used to quantify the intensity of abrasive interaction 
during the experiments as it is fundamentally linked 
to the specific grinding energy. As such, the outcomes 
of the pin-grinding experiments were analyzed and 
charted across various aggressiveness numbers. The 
aggressiveness number can be calculated as follows:
 Aggr = 10
6
 (V
w
 / V
s
) (a / d
s
)
1/2
,
 
(3)
where d
s
 is the diameter of the wheel.
The obtained specific grinding energy values for 
the different cooling-lubrication methods are given in 
Table 2. The specific energies here were calculated 
using the measured tangential grinding forces at 
different Aggr values. The specific grinding energy 
was lower at higher Aggr, indicating that increasing 
the wheel speed improves the efficiency of material 
removal, since the lower specific energy indicates 
lower proportions of sliding/friction in the chip 
formation process [3]. This phenomenon is especially 
noticeable in pin-grinding or when the depth of cut is 
very small.
Table 2.  Specific grinding energy values for different cooling-
lubrication conditions
Experiment 
No.
Aggr 
[-]
Specific energy [J/mm³]
Dry Emulsion
LCO
2
-MQL
1 5.68 55 82 18
2 6.82 47 137 42
3 8.52 45 96 38
4 11.36 50 71 38
5 17.04 37 50 36
In LCO
2
-MQL grinding, the obtained specific 
energy values range from 18 J/mm³ to 42 J/mm³, 
the lowest among the tested cooling-lubrication 
conditions. By comparison, the values for dry grinding 
are between 37 J/mm³ and 55 J/mm³, and for emulsion 
grinding, they span from 50 J/mm³ to 137 J/mm³. 
These results suggest that LCO
2
-MQL cooling 
lubrication enables the most efficient cutting. 
Fig. 7.  Specific grinding energy vs. Aggr
The specific energy curve depicted in Fig. 7 
exhibits a typical size effect, indicating that specific 
energy declines as the aggressiveness number (or 
undeformed chip thickness) increases. This effect can 
be attributed to the transitional nature of the grinding 
process among the sliding, ploughing, and cutting 
regimes. With larger Aggr values, the grinding process 
is dominated by the cutting regime, where material 
removal occurs predominantly through shearing. 
Conversely, at lower Aggr values, the grits of the 
grinding wheel largely slide across the workpiece 
surface, resulting in limited material removal. 
The latter behavior necessitates a greater energy 
expenditure to remove a unit volume of material, 
thereby contributing to the observed size effect.
2.3  Wheel Topography
After each experiment, regardless of the cooling-
lubrication method utilized, wheel loading was noted; 
a phenomenon expected due to the low grinding 
aggressiveness. The tested Aggr values in pin-
grinding with a diamond pin are significantly smaller 
compared to values observed in larger-scale grinding 
operations. This is mentioned, as the problem of wheel 
loading is also common in conventional grinding of 
cemented carbides, particularly when using straight 
oil as a grinding fluid. This issue was mitigated during 
the sequence of experiments and their repetitions by 
conducting a thorough conditioning and cleaning 
of the grinding wheel surface after each trial using 
an abrasive stone/stick, as described in Section 1. 
Figs. 8 to 10 depict images of the wheel topography 
following grinding under different cooling-lubrication 
conditions. With dry grinding (Fig 8), the wheel 
loading is clearly visible after each experiment. This 
is due to the lack of grinding fluid to flush away the 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)11-12, 435-443
441 Grinding of Cemented Carbide Using a Vitrified Diamond Pin and Lubricated Liquid Carbon Dioxide 
chips during grinding and to reduce temperatures. 
In emulsion grinding, the wheel loading is less than 
in other methods due to the effectiveness of the 
emulsion in preventing clogging and removing chips. 
However, LCO
2
-MQL grinding (Fig. 10) presents a 
stark contrast. Although LCO
2
-MQL
 
has the lowest 
values of grinding forces and specific energy, it has a 
substantial wheel loading, which is noteworthy. This is 
likely due to the lack of oxygen in a CO
2
 atmosphere, 
which may enhance the adhesion of metal particles 
(chips) to the grinding wheel.
Fig. 8.  Wheel loading after dry grinding
Fig. 9.  Wheel loading after grinding with emulsion
Fig. 10.  Wheel loading after LCO
2
-MQL grinding
To investigate the loading for the LCO
2
-MQL 
case more thoroughly, the pins were gold sputtered 
before electron back-scatter diffraction pattern 
analysis was conducted. Fig. 11 displays scanning 
electron micrographs (Fig. 11a) magnification 350 
x, Fig. 11b) magnification 95 x), which reveal the 
particles loaded onto the wheel. The bright white, 
shiny areas represent the cemented carbide materials 
loaded into the wheel, a conclusion further supported 
by a chemical analysis of the wheel surface. This result 
could be due to inefficient chip evacuation when using 
LCO
2
-MQL, which contradicts previous findings 
of reduced loading during LCO
2
-MQL grinding of a 
titanium alloy with a conventional wheel [30]. 
a) 
b) 
Fig. 11.  ESEM images of the wheel surface after  
LCO
2
-MQL grinding; a) ESEM (magnification 350×), and  
b) ESEM (magnification 95×)
While the presence of oxygen in a typical 
grinding atmosphere minimizes the sticking, or 
“adhesion,” of metal particles to each other and to the 
workpiece, enhancing the overall grinding process, 
its absence in environments like a vacuum or an inert 
(non-reactive) atmosphere can significantly alter the 
process. Specifically, the lack of oxygen may increase 
the likelihood of metal particles sticking to each 
other and adhering to the workpiece and the grinding 
wheel [31] and [32]. When oxygen is absent, freshly 
created metal workpiece particles, or chips, with 
pristine, uncontaminated surfaces, have a propensity 
to physically stick to one another and to the wheel 

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point grinding. CIRP Annals, vol. 72, no. 1, p. 267-272, 
DOI:10.1016/j.cirp.2023.04.078.
surface. This behavior subsequently leads to the 
loading and clogging of the wheel [28].
3  CONCLUSIONS
In conclusion, this study was conducted to advance 
the understanding of the effects of varying cooling-
lubrication conditions on pin grinding of cemented 
carbides. Through the detailed investigation of three 
different conditions: LCO
2
-MQL, dry, and emulsion 
grinding – the following results were obtained.
The grinding forces and specific grinding 
energies were found to be lowest in LCO
2
-MQL 
grinding. It was found that grinding under emulsion 
(flood) conditions resulted in a poorer performance 
compared to dry grinding.
In addition, the lack of oxygen in a CO
2
 
atmosphere can potentially increase the adhesion of 
metal particles (chips) to the grinding wheel, leading 
to challenges in the grinding process, especially 
severe wheel loading in the case of LCO
2
-MQL 
grinding. However, the novel method of cooling-
lubrication, using lubricated liquid carbon dioxide, 
while demonstrating a wheel loading problem, showed 
potential for improved grinding efficiency. 
These findings pave the way for further 
investigation into optimizing the material removal 
processes in the pin-grinding of cemented carbides, 
with a particular focus on addressing wheel loading 
issues and understanding the role of the grinding 
atmosphere.
4  ACKNOWLEDGEMENTS
The authors would like to express their gratitude to 
Meister Abrasives and Sandvik Coromant for their 
invaluable support in this research endeavor. Special 
appreciation is extended to Mr. Elias Navarro and Mr. 
Per Norlin for providing the vitrified diamond pins 
and cemented carbide blanks, respectively. Further, 
we acknowledge the financial support received from 
the Slovenian Research Agency (No. 54942. Lastly, 
partial support from the EIT Manufacturing program, 
through the project (21193: Transitioning to a Waste-
free Production – International Cryogenic + MQL 
Machining Activity), is gratefully recognized.
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