International Journal of Engineering Materials and Manufacture (2021) 6(3) 195-201 

https://doi.org/10.26776/ijemm.06.03.2021.11 

 

De Oliveira, D. , Gomes, M.G., Dos Santos, A. G. and Da Silva, M.B. 

Department of Mechanical Engineering,  

Faculty of Technology,  

University of Brasilia, Brazil. 

E-mail: oliveira.deborah@unb.br 

 

Reference: De Oliveira et al. (2021) Influence of Cutting Fluid Application Frequency in Micromilling Cutting Forces. International 

Journal of Engineering Materials and Manufacture, 6(3), 195-201. 

 

 

Influence of Cutting Fluid Application Frequency in Micromilling Cutting 

Forces 

 

 

De Oliveira, D., Gomes, M. G., Dos Santos, A. G. and Da Silva, M. B. 

 

 

Received: 15 April 2021 

Accepted: 29 April 2021 

Published: 15 July 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

Micromachining allows the production of parts and components on a micro scale with high precision and has become 

a key process to meet the growing demand for micro parts and micro components. To meet the quality requirements 

of the generated surfaces and reduce the cutting forces, strategies have been analysed, such as the use of the cutting 

fluid. Therefore, this research aimed to verify the effect of the frequency of the use of cutting fluid during the micro-

milling of the Inconel 718 alloy. For this purpose, an ultra-refined cemented carbide micro end mill coated with (Al, 

Ti) N and 400 µm in diameter was used. A spindle speed of 20,000 rpm, a cutting speed of 13.8 m/min, a feed per 

tooth of 5 µm/tooth and an axial depth of cut of 40 µm were used as cutting parameters. Two frequencies of 

application of the cutting fluid were evaluated, corresponding to the flow rate of 40.7 and 270.0 ml/ h, in addition 

to the dry test. To measure the cutting forces, a Kistler dynamometer with operating range of -5 kN to +10 kN was 

used. In addition, the process simulation was performed using the AdvantEdge software by ThirdWave Systems. The 

results showed that the higher flow of the cutting fluid provided lower cutting forces and that, in dry machining, the 

cutting force increased significantly during the machining of a slot. 

Keywords: Micromilling, Inconel 718, Cutting fluid, Cutting forces. 

 

1 INTRODUCTION 

Researches in microfabrication processes are experiencing a rapid evolution due to the growing demand for 

microproducts with possible applications in optical, mechanical, electrical, medical and biochemical devices [1]. In 

this scenario, the micro machining process is an important technology to provide micro parts with the required 

precision [2]. According to Saha et al. [3], micromachining allows the production of micro components with complex 
geometries, by removing material in the form of micro-chips and using a micro-tool with sharp edges. It is noteworthy 

that one of the characteristics that defines this process is related to the size of the tool.  As an example, in micro 

milling, as exposed by Saha et al. [4], the diameter of the micro-cutter usually ranges from 0.01 to 1.0 mm. 

Micromachining has particularities that differentiate it from the conventional machining process due to the size 

effect. An important difference between the two processes is that, in micro machining, the undeformed chip thickness 

has a size comparable to the cutting-edge radius, exerting a strong influence on the chip formation mechanism [5]. 

Thus, there is a minimum uncut chip thickness for chip formation and this varies between 0.25 and 0.33 of the tool 

edge radii [6]. In addition, considering that the reductions that occur in the micro-machining process, such as in the 

tool size and cutting parameters, do not occur with the workpiece grains, the chip formation can therefore occur 

through the shearing of a single or a few grains [7,8]. 

Due to the presence of the size effect in the micromachining processes, the reduction of the undeformed chip 

thickness does not have the same effect on the cutting forces when compared with conventional processes. In this 

case, the influence of the thickness on the forces is uncertain, while the force is high due to the increase in the chip 

cross-section, it is reduced since in this condition the effective exit angle of the tool becomes more positive, which 

decreases the occurrence of ploughing, and consequently, decreases the value of ploughing force [8]. 

The machining force, as well as its components, are important output variables to be studied both in machining 

processes on a macro scale, as well as in micromachining, as it estimates the power required for cutting, as well as 



Influence of Cutting Fluid Application Frequency in Micromilling Cutting Forces 

196 

the forces that will act on the elements of the machine-tool. Besides, they directly affect the ability to obtain tight 

tolerances, cutting temperature, and tool wear [9]. 

The machining force has three basic components that act on the cutting edge: cutting force, feed force, and passive 

force [10]. In addition to these components, in the micromilling process, there is the presence of the ploughing force. 

This force will be very present in this process due to the size effect. This is a deformation force that acts at the tip of 

the cutting tool and at the interface of the chip tool, being responsible for the significant increase in the specific cutting 

energy [11]. 

One way to reduce the forces present in the cut is to use cutting fluids, thus guaranteeing less tool wear and higher 

quality of machined surfaces [12]. According to De Oliveira et. al [13] the cutting fluid must be applied at an 

appropriate rate, to ensure the homogeneous quality of the machined surface. In this work, the variation of the fluid 

application rate in the Inconel 718 micromilling was investigated, and it was observed that by using the highest fluid 

application rate (200 pulses per minute) it was possible to guarantee its presence on the entire surface of the slot, 

thus improving its surface finish. 

Ziberov et al. [14] when performing the micromilling of the Ti-6Al-4V alloy, observed that the application of 

cutting fluid improves the quality of the machined surfaces, by reducing the wear of the cutting tool. In addition, 

they noted that the presence of the fluid influenced the size of the burrs formed. Demonstrating the great importance 

of using the cutting fluid in micromachining operations. 

  In view of this, the present work was developed with the aim of evaluating the influence of the frequency of 
application of the cutting fluid in the micromilling process of the nickel alloy Inconel 718. 

 

2 MATERIALS AND METHODS 

2.1 Workpiece Material 

The workpiece material was the refractory nickel alloy Inconel 718, its austenitic microstructure can be observed in 

Figure 1. This alloy has high tensile strength, good chemical resistance, and the ability to operate continuously at high 

temperatures [15], Table 1 contain some of the material properties and Table 2 its chemical composition. The 

workpieces were machined to blocks of 15 mm X 20 mm X 15 mm. 

 

 

 

Figure 1: Inconel 718 microstructure [16] 

 

 

Table 1: Mechanical properties of Inconel 718 [17] 

 

Tensile 

strength 

Yield 

strength 

Young’s 

Modulus 

Hardness 

(HRc) 

Room Temp 

Density 

Melting 

Range (º C) 

Thermal 

Conductivity 

(MPa) (MPa) (GPa)  (g/cm
3
)  (W/mk) 

1275 1034 200 40 8.22 1260 - 1336 11.4 

 

 

Table 2: Chemical composition of Inconel 718 [17] 

 

Element C Al Ti Cr Fe Ni Nb Mo 

Percentage 0.04 0.50 0.90 19.00 18.50 50.66 5.10 5.30 



De Oliveira et al. (2021): International Journal of Engineering Materials and Manufacture, 6(3), 195-201. 

197 

2.2 Micro Cutting Tools and Machine Tool 

The tool used in this work is a ultra-refined cemented carbide micro end mill (MS2MSD0040) coated with (Al, Ti)N, 

400 µm diameter, 2 flutes, manufactured by Mitsubishi. The geometry of the tool is shown in Figure 2, with some 

dimensions in millimetres. 

The machine-tool was the Mini-mill / GX CNC, manufactured by Minitech Machinery Corporation®. It has a 

maximum spindle speed of 60000 rpm, 4 axes with position resolution of 0.1 μm. This machine is equipped whit an 
MQL system. The system was set to deliver the fluid at an air pressure of 33 psi (0.23MPa), and the cutting fluid 

selected was the Coolube 2210EP, manufactured by UNIST. 

 

 

 

Figure 2: Micromill [18] 

 

 

2.3 Cutting Parameters 

The experiment consisted in machining micro slots of 15 mm in the Inconel 718. In order to continue the investigation 

proposed by De Oliveira et al. [13], the same cutting parameters and lubrication conditions were selected, except the 

cutting speed. The cutting conditions are shown in Table 3. The only different parameter from [13] is the cutting 

speed. This is because limitations of the dynamometer. It is important to mention that the different cutting fluid 

application frequency will result in different flow rates, with the first being 40.7 ml/h, and the second being 270.0 

ml/h, which results in 30 and 200 pulses per minute, respectively.  

 

Table 3: Cutting Parameters 

 

Parameter Value 

Spindle speed n (rpm) 20 000 

Cutting speed vc (m/min) 13.8 

Feed per tooth fz (µm/tooth) 5 

Axial depth of cut ap (µm) 40 

Cutting fluid flow rate (ml/h) 

00.0 (dry) 

40.7 

270.0 

 

 

2.4 Outputs 

To obtain the force results, a Kistler dynamometer, model 9257b was used. This dynamometer has an operating 

range of -5 kN to +10 kN and can operate dynamically or almost statically [19]. Its sensitivity is adjustable, being 

recommended to 0.02 N. This equipment has a low natural frequency of 3.5 kHz [19], which limited its use for 

experiments with lower cutting speed since the frequency of the phenomenon of cutting is related to the number of 

teeth of the tool and the spindle rotation. Therefore, the cutting speed used in this work was 13.8 m/min. 

After the signals were generated in the dynamometer, they passed through a Kistler 5405A distribution box, later 

through a Kistler conditioner / amplifier, model 504E and finally converted (analogue / digital) by a National 

Instruments board, NI USB-66221, with 16 bits. The signals were acquired using a LabVIEW software with a frequency 

of 100 kHz, to achieve an adequate trade-off between the quality of the signal and its intensity [20] Subsequently 

the signals were treated and analysed using the MATLAB software. 

In order to verify the force measurements a computational simulation was performed using the AdvantEdge by 

ThirdWave Systems. This is a software dedicated to machining operations and uses an explicit dynamic, thermo-

mechanically coupled finite element model specialized. The material properties were obtained by the software library 

and the tool was modelled based in SEM images and the manufacturer specifications. The tool was determined as a 

rigid body, with elements varying from 10.0 μm to 1.0 μm, the workpiece material was plastically and elastically 



Influence of Cutting Fluid Application Frequency in Micromilling Cutting Forces 

198 

deformable, having initial mesh parameters as 500 – 10 μm, and as the deformations occur the adaptative mesh could 
generate new smaller elements, reaching 0.4 μm. It is important to comment that the simulation was performed 
considering the same cutting parameters and for dry cutting. 

 

3 RESULTS AND DISCUSSION 

To verify the theory presented by De Oliveira et al. [13], the cutting forces were obtained in similar conditions. This 

was selected once the cutting fluid is directly related to the excitations and forces of the system [21, 22]. In figure 3 

is possible to observe one of the machined slots in two different regions. The left one in the red square presented 

worsened surface finish and adhered material in the slot surface, attributed to the lack of cutting fluid in this region 

during the cut. 

Figure 4 contains the force signals during the cutting, for dry machining, the two different lubrication conditions 

and a comparison of the three lubricating atmospheres. The force was measured in the cutting direction and the 

negative values are the forces during cutting and the positive values are due to ploughing. 

Figure 4a shows the rough signal for dry micromachining. The cutting forces increase from about 4.6 N to about 

8.7 N during the micromachining, indicating that there was a significant tool wear in the machined length 15 mm. 

When comparing the force result, Figure 4a with Figure 4c, dry condition with the test with cutting fluid applied 

at high frequency, it is possible to observe that the initial force is similar. However, when fluid is applied at 270.0 

ml/h flow rate, there is no significant increase in the cutting force with the machined length, and the maximum force 

was about 6.7 N. This different behaviour indicates that the fluid has reduced the cutting forces and, consequently, 

the wear rates of the micromill. Focusing on the low frequency of cutting fluid application, it is possible to notice in 

Figure 4b that the initial value of the force is high and has peaks of force, which may be related to the lack of cutting 

fluid at the chip tool interface. 

The results obtained are in accordance with the literature, which points out that the application of cutting fluid 

when machining Inconel 718 favours the process since the lubrication prevents the material from adhering to the 

microtool, which also results in less friction which means lower cutting forces [23, 24]. These effects reduce the 

diffusion of the workpiece material to the microtool material, a common effect when machining Inconel 718. The 

combined reduction of these factors helps not only in the quality of the slot, as presented in Figure 3, but in increasing 

the life of the micromill [25, 26]. 

As mentioned, computational simulation was performed with the intention to verify the quality of the force 

signals obtained experimentally. The computational results proved to be robust and the obtained results were similar 

to the experimental ones. In Figure 5 it is possible to observe the results of force for one single revolution of the tool, 

in which the micromill had not yet fully entered the part, representing the beginning of the slot. However, it is 

important to remark that this signal is not equivalent to the first contact because a pre-Boolean cut was used, so that 

the simulation started with both edges inside the part. 

When considering the beginning of the micromilling, it is possible to notice that the cutting forces when the 

micromill is starting the slot are quite reduced. According to Wang et al. [27], for a 100 µm micro-cutter, with a 

depth of cut of 50 µm, the initial forces vary from 0.2 N for a chip load of 0.5 µm to approximately 0.8 N for chip 

load 4.0 µm. These results are in accordance with the ones presented here. 

Regarding the application of cutting fluid, it was possible to prove quantitatively the benefits of its use for Inconel 

718 micromilling operations. 

 

 

 

Figure 3: Micromilled slot with different surface finish due to the lack of cutting fluid [13] 



De Oliveira et al. (2021): International Journal of Engineering Materials and Manufacture, 6(3), 195-201. 

199 

  

a) Force signal for dry machining b) Force signal for machining with 40.7 ml/h 

 
 

c) Force signal for machining with 270.0 ml/h d) Comparison of forces for different atmospheres in 

micromilling 

 

Figure 4: Force signals for different cooling-lubrication conditions 

 

 

 

 

 

 

Figure 5: Computational results for cutting force. 

 

 

 

 

 



Influence of Cutting Fluid Application Frequency in Micromilling Cutting Forces 

200 

4 CONCLUSIONS 

After the experimental and computational trials about micromilling Inconel 718 with a 400 μm diameter cemented 
carbide micromill, the following conclusions can be draw:  

 

1. The computational results presented similar results to the experimental, indicating that the cutting forces 

were correctly obtained. 

2. The cutting force increase within one slot when dry machining, from 4.6 N to 8.7 N, indicating high wear 

in the microtool. 

3. Low frequency presented intermediate results and the presence of force pikes can be related to the absence 

of cutting fluid in some regions of the slot. 

4. The higher flow rate resulted in the lower cutting forces with the force in the end of the slot being 6.7 N, 

which near 25% of reduction when comparing to the dry cut. 

 

ACKNOWLEDGEMENT  

The authors are thankful to CAPES, CNPQ, FAPEMIG, to Faculty of Mechanical Engineering of Federal University 

of Uberlandia and to the Department of Mechanical Engineering, Faculty of Technology, University of Brasilia. 

 

 

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