International Journal of Engineering Materials and Manufacture (2021) 6(1) 50-59 

https://doi.org/10.26776/ijemm.06.01.2021.05 

 

Shazzad Hossain
 
and Mohammad Zoynal Abedin  

Department of Mechanical Engineering 

Dhaka University of Engineering and Technology 

Gazipur 1707, Bangladesh 

E-mail: abedin.mzoynal@duet.ac.bd 

 

Reference: Hossain S and Abedin, M. Z. (2021). Effect of Minimum Quantity Lubrication System for Improving Surface Roughness 

in Turning Operation. International Journal of Engineering Materials and Manufacture, 6(1), 50-59. 

 

 

Effect of Minimum Quantity Lubrication System for Improving Surface 

Roughness in Turning Operation 

 

 

Shazzad Hossain and Mohammad Zoynal Abedin 

 

 

Received: 21 October 2020 

Accepted: 29 December 2020 

Published: 30 January 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT  

Due to increase in temperature at the cutting zone, the tool wear and surface roughness along with the non-uniform 

chip formation and the dimensional deviation of the job by using the conventional cutting fluid, the machining 

operation experts have directed their concentrations in order to achieve a smooth machining operation by using 

minimum quantity lubrication (MQL). As a consequence, numerous efforts can be seen for not only having the 

optimum cutting parameters but also other parameters that enhance the product quality and the surface roughness. 

In this regard, relevant experimental and numerical data outcomes not only MQL but also conventional cutting fluid 

(CCF) in the turning operation of 50HRC steel has been investigated experimentally. It is revealed that the surface 

roughness becomes optimal and significantly reduced for the condition of MQL with that of dry and conventional 

flood. 

Keywords: Turning operation, CCF, MQL, Surface roughness, Lathe machine. 

 

1 INTRODUCTION 

Minimum quantity lubrication or MQL, also known as "Micro lubrication", is the new method of delivering metal 

cutting fluid to the chip-tool interface. Using this method, a little fluid, when properly selected and applied, can make 

a substantial difference in how effectively a tool performs in the operation. The goal of any machining operation 

such as turning, milling, grinding, drilling, etc. is to reduce the machining costs by improving its quality and 

productivity. The machining operation is performed by using an extensive lubrication that helps not only to reduce 

the friction, heat and wear of cutting tools but also helps to ensure a smooth operation between the cutting tools 

and work pieces. In ancient time, the conventional cutting fluid (CCF) was seen to be highly used in various machining 

processes that would cause the tremendous health problems of employees as well as environmental pollutions. In 

addition, by using CCF, it may not be possible to achieve more working satisfactions due to its various reasons such 

as the recycling of its chips, degrading the quality of fluid and less heat absorbing capacity of the fluid and so on. 

Also, the CCF is considered to be more effective at a lower cutting speed and it becomes ineffective at a higher cutting 

speed because the amount of generated heat is more and the coolant cannot reach the critical areas, hence the 

interface cannot be cooled easily. Thus, the minimum quantity lubrication system comes out as another method that 

can be studied in details so as to reach the desired objectives and that may be considered to be an economical and 

environmentally compatible lubrication system in the machining operation.  

The MQL system provides spray painting at high speed and high pressure to the cutting zone by the gun. It is supplied 

at a constant pressure around 2 to 6 bars. Basically, a mixture of air and cutting fluid (soluble oils, semi synthetics, 

and synthetics) is applied onto the cutting zone. Different papers published on MQL in different types of machining 

process. MQL is an advanced method which can perform the superior cutting operation where the temperature at 

the cutting zone promotes a favorable chip formation and tool wear that leads to have an enhanced tool life and 

surface finish. The quality of surface is most significant foe any product. The surface roughness is main affecting thing 

such as for contact causing surface friction, wearing, in production time it is generating high cutting zone temperature. 

Such high temperature list to have a dimensional deviation and enhance premature failure of cutting tools. In high 

cutting speed machining, it is clear that conventional cutting fluid application fails to penetrate the chip-tool interface 

and thus cannot remove heat effectively. Lubrication and heat removal are the basic ways to keep the tool wear 

under control. But the conventional cutting fluid effective at lower cutting speed and gets ineffective at higher cutting 

mailto:abedin.mzoynal@duet.ac.bd


Effect of Minimum Quantity Lubrication System for Improving Surface Roughness in Turning Operation  

51 

speeds and feed, because the amount of heat generation in cutting zone is high. It is also shown rough results in high 

depth of cut in machining. The coolant cannot reach the critical areas and the tool work piece area or cutting zone 

area cannot be cooled. Solving this problem, it is widely used in various machining operation minimum quantity 

lubrication (MQL) method due to its huge advantages. This is possible if machining is carried out at maximum cutting 

parameters and at the same time able to achieve enhanced tool life (TL).When the high pressure soluble oil is used 

on the chip tool interface, it can reduce the cutting temperature and improve the tool life and surface finish to a 

certain extent. The prospect of using overflow coolant in high speed machining (HSM) is not very optimistic. Most 

coolants, especially water-based coolants, have a negative impact on tool life. MQL is one of the new system in 

which a very small amount of oil is pulverized into a compressed air steam. MQL helps to reduce the cutting 

temperature and avoids the thermal shock of flooded coolant. Given the high costs associated with the use of cutting 

fluids, and when it comes to enforcing stricter environmental regulations, the choice of MQL seems obvious. 

Furthermore, MQL also reduces the cutting force, power consumption, tool wear, nodal temperature and friction 

coefficient. Authors have also identified the research gaps for further research. 

Although there have been many review articles on this topic. Here in this study tries to find out major advantages 

using MQL on machining process from various established journal. So that in future it will help going on further 

research on MQL. The present work reviewed some papers on MQL and experimentally investigates the role of MQL 

on surface roughness in turning operation of CNC lathe machine. The wealth of nations can be judged by their 

investment in machining. Modern manufacturing trends require parts to be produced quickly and smoothly. Although 

there have been many review articles on this topic, this attempt has its own merits. It highlights the operational 

parameters that have been left untouched and can be proved very useful for any future studies in this field.as a 

significant enhancer. For convenient usage, passive techniques are important topics for scientists and researchers 

during recent decades. Innumerable experimental studies have been conducted to improve the heat transfer rates by 

these techniques. Scientists preferred passive heat transfer enhancement techniques due to their simplicity and 

applicability in many applications [1]. In recent years, heat transfer technology has been widely applied to 

refrigeration and air conditioning, automobile, process industries, etc. The main purpose of heat transfer 

enhancement techniques is to reduce the thermal resistance either by achieving the effective heat transfer surface area 

or by creating turbulence in the fluid flowing inside the tube. There are various arrangements are used and 

experimented to get better heat transfer rate such as insertion in tubes, the tube with fins, different tube shapes, 

corrugated tubes, baffle arrangements as well as different mediums like water, air, and nanofluids. The 

rearrangements of these different components are used for obtaining various purposes like increases the surface 

contact area of the fluid, create a swirl in the flow, and decrease the pressure drop to get enhancement heat transfer 

rates [2]. 

Overall, rough surfaces or extended surfaces are used to increasing the effective surface area whereas inserts, 

winglets, turbulators, etc. are used for generating the turbulence [3]. Based on scientific experiences, various types of 

inserts such as modified twisted tapes, wire coil, baffles, wire mesh, longitudinal swirl generators, and other types of 

tube inserts have been designed and studied numerically or experimentally. Some researchers summarized the 

functions of different types of the insert which mainly enhanced single-phase convective heat transfer in heat 

exchangers by mixing main flow and the turbulence in the boundary layer region [4]. 

In recent years, heat transfer technology has been widely applied to devise applications in refrigeration, 

automotive, method industries as heat exchanger system. Heat exchanger systems are used in different processes like 

conversion, utilization and recovery of thermal energy in various industrial, domestic applications and commercial 

processes. The most common examples include steam generation and condensation in power cogeneration plants 

widely used the heat exchanger to get better performance. The heating and cooling in thermal processing of 

pharmaceutical products manufacturing, chemicals industries and waste heat recovery plants are also utilizing the 

heat enhancement process by various enhancer to increase the heat exchanger efficiency. The increase in heat transfer 

performance can lead to a more economical design of heat exchanger which can help to make savings of energy, 

materials and cost which is related to a heat exchange process. This design also obeys many techniques termed as 

heat transfer augmentation which has an indicative impact on the enhancement of thermal performance. The present 

study investigated the heat transfer enhancement in various arrangements with insert devices as an important passive 

technique and their impacts on different mediums and configurations. 

 

2 RECENT LITERATURE SURVEY ON MQL 

In the pursuit toward achieving dry cutting, air machining, minimum quantity lubrication system in machining are 

the stepping stones. Nevertheless, machining is always accompanied by certain difficulties, and hence none of these 

methods has provided a complete solution. Dhar et al. [1] investigated the role of minimum quantity lubrication on 

cutting temperature, tool wear, surface roughness, and dimensional deviation in turning of AISI-4340 steel at cutting 

speed and feed rate combinations by uncoated carbide insert and found a significant result on tool wear rate, 

dimensional inaccuracy and surface roughness by using MQ. MQL helps to reduce the cutting temperature and avoids 

the thermal shock [2]. Lugscheider et al. [3] used this technique in remaining process of gray cast iron and aluminum 

alloy with coated carbide tools and concluded that it caused a reduction of tool wear when compared with the 

completely dry process and as a result an improvement in the surface quality of the holes. Dhar et al. [4] also used 

this method in turning process of medium carbine steel and found that, in some cases, a mixture of air and soluble 



Hossain and Abedin (2021): International Journal of Engineering Materials and Manufacture, 6(1), 50-59  

52 

oil has been shown to be better than overhead flooding application of soluble oil. The drilling of aluminum silicon 

alloys is one of those processes where dry cutting is impossible due to the high ductility of the work piece material 

[5].Without cooling and lubrication, the chip sticks to the tool and breaks it in a very short cutting time. Therefore, 

in this process a good alternative is the use of the MQL method [6, 7]. Khan et al. [8] described that, MQL provides 

environment friendliness with machining (maintaining neat, clean and dry working area, avoiding inconvenience and 

health hazards due to heat, smoke, fumes, gases, etc. and preventing pollution of the surroundings) and improves 

the machinability characteristics. 

Dhar et al. [9] compared the mechanical performance of MQL to completely dry lubrication for the turning of AISI-

1040 steel based on experimental measurement of cutting temperature, chip reduction coefficient, cutting forces, tool 

wears, surface finish, and dimensional deviation. Results found that the use of near dry lubrication leads to lower 

cutting temperature and cutting force, favorable chip–tool interaction, reduced tool wears, surface roughness, and 

dimensional deviation. The increasing demand for high machine productivity requires the use of high cutting speeds 

and feed speeds. This processing inherently produces high cutting temperatures, which not only shortens tool life, 

but also impairs product quality. Metal cutting fluids have changed the performance of machining operations due to 

their lubrication, cooling and chip removal functions, but in terms of employee health and environmental pollution, 

the use of cutting fluids has become a problem [10, 11]. They suggested MQL mainly by which reduction the cutting 

zone temperature and favorable change in the chip-tool and work-tool interaction. Productivity of any machine tool 

and any tool Processing parts depends on the quality of the parts the surface produced by the machine. So for the 

good functional behavior of any mechanical parts good surface quality is essential [12].  

Lohar and Nanavaty [13] describes that the surface in hard turning of hardened AISI 4340 is better as compare to dry 

and wet turning. There is 30% improvement in surface finish using MQL of turning operation and use the Analysis 

of variance (ANOVA) is carried out using MINITAB software to investigate difference in average performance of 

factors using test. As usual hard turning process requires large quantities of coolants and lubricants for machining. The 

cost of associated with lubricants increases the total cost of production and conventional cutting fluid application fails 

to penetrate the chip-tool interface. Thus conventional cutting fluid cannot remove heat effectively. Considering cost 

and the environmental laws are enforced, alternatives has been sought to minimize the use of cutting fluid in 

machining operations. Some of these are dry machining and machining with Minimum Quantity Lubrication (MQL). 

Kedare et al. [14] found that the surface finish improved by 27% using MQL system during end milling operation. 

The results of this study show that MQL can be considered an economical and environmentally friendly lubrication 

technology.  

Y S Laio et al. [15] described that the tool life significantly improved by MQL in HSM of NAK80 hardened steels 

when cutting parameters are selected properly. MQL is the name given to the process in which very small amount 

of oil is pulverized into the flow of compressed air. MQL helps in reducing cutting temperature and also averts 

thermal shocks, experienced by flood coolant. Zhou et al. [16] has investigated of surface damage produced by 

whisker-reinforced ceramic cutting tools in the finish turning of Inconel 718 (nickel-based super alloy). The aim of this 

study is the effects of the cutting parameters (cutting speed, depth of cut and feed), tool wear and Coolant conditions 

on the surface damage to it occurring during dry and wet turning. MQL shows better result at slow cutting speed and 

low depth of cut. As per as MQL is concerned surface roughness value is almost constant with little variations. Surface 

finish of MQL is better with medium cutting speed. The main objective of this paper is MQL provides the benefits 

mainly by reducing the cutting temperature, which improves cooling effect and results in better surface finish. Cakir 

et al. [17] has investigated the AISI 1040 steel by turning process, the effects of cutting fluid, application of some gases 

and dry cutting on cutting force, thrust force, surface roughness, friction coefficient and shear angle were studied. Dry 

machining, wet machining and machining with oxygen, nitrogen and carbon dioxide gases were carried out under 

constant cutting speed, three level of feed and depth of cut. Chrong-Jyh et al. [18] has investigated the optimization 

of CNC turning operation parameters like speed, feed and depth of cut for SKD11 (JIS) using the Taguchi and Grey 

relational analysis method. The cutting tool is made of carbide and coated with titanium nitride (TiN) and Water-

soluble cutting fluids are mixed with water at different ratios depending on the machining operation. 

Rajan and Philip by using AISI 4340 steel and the combination has been studied and compared with dry and wet 

turning under the parameters of speed nation of SNMG 120408 and P30 tool material, hard turning with minimal 

cutting fluid (HTMF, feed, depth of cut [19]. So the surface roughness is used as an indicator of the quality of any 

product. It Influences such as wear resistance, fatigue strength, Coefficient of friction, corrosion resistance, and 

lubricity, wear the speed of processing the part. In today's manufacturing Industry quality is one of the important 

factors, the only Components that affect customer satisfaction. In every industrial field, the surface quality is 

determined by the surface roughness of the component [20, 21].  

Tsai et al. [22] found that the cooling ability of water in terms of temperature drop decreases with an increase in 

both temperature and depth of cuts. So, this might be the reason for flood cooling having no effect at higher depth 

of cuts, while the effect for MQL might be due to inadequate lubrication. Lajis  et al. [23] described that the machining 

temperature at the cutting zone is an important index of machinability and needs to be controlled as far as possible. 

MQL is expected to provide some favourable effects mainly through reduction in cutting temperature. When the 

chip-tool contact is partially elastic, where the chip leaves the tool, MQL is dragged in that elastic contact zone in 

small quantity by capillary effect and is likely to enable more effective cooling [23]. Brain Boswell, Mohammad 

Nazrul Islam, state that, the experimentation involved in determining a suitable environment alternative to using 



Effect of Minimum Quantity Lubrication System for Improving Surface Roughness in Turning Operation  

53 

little amount of cutting fluid in high speed velocity at cutting zone. As a result they observed and found that reduce 

thermal shock and stresses generating during machining [24].  

The MQL systems enabled reduction in average chip tool interface temperature up to 10% as compared to using 

conventional cutting fluid. Most of the authors have indicated adequate betterment in performance with MQL 

machining compared to dry machining, and more meaningful results could have been obtained if it was also 

compared with flood machining. Surface quality of the machined parts is one of the most important product quality 

indicators and most frequent customer requirements which can be obtained by MQL processing and get accurate 

finishing than conventional fluid.  

Cha et al. [25] found that Inconel 718 alloy is widely used as material of aircraft engine, has a good mechanical 

property in high temperature, strong anti-oxidation characteristics in oxidized current over 900∘C900∘C, and also is 
not easily digested in the air containing sulfur, therefore, its usage as mechanical component is expanding rapidly. 

Even though Inconel alloy 718 is difficult to machine, it requires highly precise processing/machining to sustain its 

component quality of high accuracy. In this paper, general turning operation conditions arc tested to select the best 

cutting process condition by measuring surface roughness through implementing experiments with orthogonal array 

of cutting speed, feeding speed and cutting depth as processing parameters based on the Taguchi method. Optimal 

turning operation conditions are extracted from the proposed experimental models.  

Lee et al. [26] suggested in their research how to derive optimum cutting conditions for the milling process in MQL 

machining. To reach these goals, a bunch of finish milling experiments was carried out while varying cutting speed, 

feed rate, oil quantity, depth of cut and so on with MQL. Patil et al. [27] characterized airborne micro droplet 

diameters and size distribution from two commercially available lubricants A and B for internal minimum quantity 

lubrication (MQL). 

 

3 MQL SYSTEM SET UP AND ITS APPLICATIONS 

In general, there are two methods are widely used in machining process one is external spray and another is through-

tool. The external spray system made by a coolant tank or reservoir which is connected with tubes fitted with one 

or more nozzles. It is easy method than others, inexpensive, portable, and suited for almost all machining operations. 

Through-tool MQL systems are available in two configurations: based on the method of creating the air-oil mist. The 

first is the external mixing others name is one channel system. Here, the oil and air are mixed externally, and piped 

through the spindle and tool to the cutting zone. Minimum quantity lubrication and dry metalworking system is the 

most recent and quickly modern technology. This technology was mainly developed in the aerospace industry 

because the scale of the work amplified the negative attributes of the conventional flood type coolant and it was not 

possible surface quality requirements by using dry machining. This type of lubrication system can apply anywhere 

would like to maximize tool life without the conventional coolant mess. Such as- Aluminum, steels, HSLA, super 

alloys, tool steel, copper and brass. Various process like as-Lathe operation, grinding, CNC profiling, turning, and 

drilling, milling, etc. To extend the life time of cutting tools and reduces friction between work piece and cutting 

edges MQL contributes a lot. Its assists in smoothing and quick operation. Obviously the health and safety aspects of 

using cutting fluids add to the cost of metal cutting as suitable disposal of the cutting fluid is needed. Most of the 

researcher have showed a noticeable improvement in performance with MQL machining and more meaningful results 

could have been obtained. MQL very useful on hard machining process because of its high pressure jet flow, good 

mixture of coolant and applied at the chip-tool interfaces and could reduce cutting temperature. 

 

 

Figure 1: High speed cutting fluid with compressor: (1a) Nozzle (1b) Compressor (1c) cutting fluid reservoir 

1c 

1a 

1c 



Hossain and Abedin (2021): International Journal of Engineering Materials and Manufacture, 6(1), 50-59  

54 

 

Figure 2: Conventional cutting set up: (2a) Nozzle (2b) Work piece material (2c) Tool post 

 

In figure 1 represents the set up for high speed cutting fluid with compressor where lubricant (grade 60) and air is 

mixed by MQL set up based on spray gun of CNC lathe (Model: CK6136A-2, made in China). The two separate 

hollow pipes carry lubricant and air which mixed in mixing chamber (white colour) and just before the tip of the 

nozzle. The lubricant flow is controlled by flow control valve. In order to have contentious mist, constant pressure 

is assured by the pressure gauge reading because change in pressure may vary quantity of the lubricant coming out 

of the nozzle and outer diameter of nozzle is 2.5mm. Experiments are carried with the following parameter viz. 

Coolant pressure, spot distance, coolant flow rate are 5bar, 20mm, 850ml/hr. From Figure 2 it is shown that the 

photographic view of conventional cutting fluid on machining process. In Figure 3, it has shown that the schematic 

view of MQL set up and all accessories which are to be needed for this system.  

 

Figure 3: Schematic view of MQL set up 

 

The schematic view of minimum quantity lubrication system set up shows by figure 3 [1]. The conventional cutting 

fluids are not effective in such high production machining, particularly in continuous cutting of materials like steel 

and alloy. Minimum quantity lubrication presents itself as a viable alternative for turning with respect to tool wear, 

heat dissipation, and machined surface quality.  

 

4 EXPERIMENTAL METHOD AND SAMPLE PREPARATION 

The experimental set-up consists of a CNC lathe (Model: CK6136A-2) machine. The experiment done using two types 

of cutting fluids. One is conventional cutting fluid and another is minimum quantity lubrication which is extremely 

small amount of cutting fluids. The requirements of Minimum Quantity Lubrication is supplied by the MQL system 

during the experiment at 5 bars pressure. The MQL system is a superfine particle oil mist generator capable of 

supplying superfine particles of oil–air mixture from an ejecting nozzle, while discharging cutting oil at a level of 850-

1000ml/hr. The work piece (Ø81mm×L457.2mm) material is shown in Figure 4 is a cylindrical round bar of Mild 

Steel and consists of hardness is (48-50) HRC. A tungsten carbide tool is shown Figure 5 which is used for this 

experiment which contain (L = 8.7mm, I.C = 12.7mm, r = 0.8mm, d = 5.16mm) specification with WNMG tool 

holder. The MQL system generates the oil mist based on the principle of Minimum Quantity Lubrication, oil mist 

generator. The experiment is carried out at three cutting speeds are 600, 700 and 800 rev/min at 60, 70 and 80 

mm/min feed rate with 015, 020 and 0.30 mm depth of cut. 

2b 

2a 

2c 



Effect of Minimum Quantity Lubrication System for Improving Surface Roughness in Turning Operation  

55 

 

    

 

 

 Figure 4: Work piece raw material (Mild steel 50HRC)  

 

 

 

Figure 5: WNMG tool holder with insert 

 

 

Table 1: Experimental Data 

 

 

SL. No. Cutting speed 

(rev/min) 

Feed rate 

(mm/min) 

Depth of cut 

(mm) 

Response parameters 

Surface roughness(µm) 

Dry Flooded MQL 

1 600 60 0.15 2.31 2.25 1.85 

2 600 60 0.20 2.12 2.38 1.67 

3 600 60 0.25 2.40 2.11 1.56 

4 600 60 0.15 1.95 1.89 1.48 

5 600 60 0.20 2.10 1.97 1.69 

6 600 60 0.25 1.96 1.84 1.35 

7 600 60 0.15 1.88 1.76 1.23 

8 600 60 0.20 2.22 1.72 0.98 

9 600 60 0.25 1.91 1.68 0.90 

10 600 60 0.15 1.75 1.66 1.20 

11 600 60 0.20 2.40 1.78 1.11 

12 600 60 0.25 2.10 1.63 0.87 

13 600 60 0.15 1.89 1.53 0.79 

14 600 60 0.20 1.77 1.66 0.84 

15 600 60 0.25 1.82 1.75 0.68 

16 600 60 0.15 1.93 1.52 0.72 

17 600 60 0.20 1.78 1.60 0.80 

18 600 60 0.25 2.12 1.58 0.78 



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56 

5 RESULT AND DISCUSSION 

The experiments were designed by using various methods with Minitab 19 software. The surface roughness are 

determined by three cutting condition such as dry, conventional flood and MQL systems. From these, the best and 

optimal results are found by using Minitab software. At first specimen is prepared and experiments are carried out in 

CNC Lathe machine. To visualize the effect of cutting speed (Cs) depth of cut (DOC) over surface roughness 

parameters (Ra) of dry, flooded and MQL condition are shown in following Figures 6-8. 

 

 

Figure 6: Analysis of line plot of mean surface roughness for cutting speed (Cs). 

 

The concept of minimum quantity lubrication (MQL) has been suggested since a decade ago as a means of addressing 

the issues of environmental intrusiveness and occupational hazards associated with the airborne cutting fluid particles 

on factory shop floors. In figure 6 represents the analysis of line plot of mean surface roughness for cutting speed (Cs) 

of 600 rpm. As shown in Figure 6, the mean is the average of the number (response data) and it is used to analyse 

the way in which the mean varies across different groups of data. As  the experiment are done with constant cutting 

speed, constant feed rate with varies of depth of cut, so it is drawn two line plot figure for dry, flooded and MQL 

over two cutting condition. In the Figure 6, it is clear that when cutting speed is constant and applying MQL system 

the surface roughness value is significant over dry and flooded condition.  

 

 

Figure 7: Analysis of line plot of mean over depth of cut (DOC) 

 

Figure 7 shows the analysis of line plot of mean over depth of cut (DOC). As can be seen in the Figure 7, with small 

change of depth of cut, the surface roughness in the machining becomes optimum for MQL system comparing with 

those for dry and flooded situation. When depth of cut is 0.25mm (green colour), MQL system show the excellent 

result of surface roughness than others two depth of cut. In conclusion, it can be said that the cutting performance of 

MQL system of machining is better than that of dry and conventional machining. As per as MQL is concerned surface 

roughness value is almost constant with little variations. Minimum quantity lubrication (MQL) and cryogenic cooling 

system has been developed now a days for better surface roughness, temperature and tool life. Also, MQL reduced 



Effect of Minimum Quantity Lubrication System for Improving Surface Roughness in Turning Operation  

57 

average auxiliary flank wear and notch wear on auxiliary cutting edge, surface roughness also grew very slowly under 

MQL condition.  

Surface roughness is also an important index of machinability or grind ability because performance and service life of 

the machined component are often affected by its surface finish. MQL cooling effect also improved to some extent 

with the decrease in feed particularly at lower cutting velocity. 

 

 

Figure 8: Time series plot of surface roughness for dry, flooded and MQL 

 

In figure 8 shows the time series plot of surface roughness for dry, flooded and MQL. As can be seen in the Figure 8, 

it is clearly shows that the surface roughness value is optimal than dry and flooded condition. With increasing 

machining time MQL show better surface roughness with gradually. The machining temperature at the cutting zone 

is an important index of machinability and needs to be controlled as far as possible. MQL is expected to provide 

some favourable effects mainly through reduction in cutting temperature. With the increases of machining time the 

surface roughness value of MQL machining is excellent than dry and flooded machining. 

 

6 CONCLUSION 

In the cutting performance of machining, MQL provides the better surface roughness result than dry and flooded 

condition which are shown from the experiment. Not only surface roughness, but MQL also provided reducing tool 

wear, improved tool life and better surface finish as compared to dry and flooded machining of steel. In this study, 

MQL provides several benefits in the machining of 50HRC steel. The main objective of the present work was to 

experimentally investigate the role of minimum quantity lubrication (MQL) on surface roughness in turning operation 

50HRC steel and compared the effectiveness of MQL with that of dry and conventional flood. The findings of the 

present experimental investigation can be written in the following way. 

1. MQL machining of surface roughness is seen to be significant and optimal when compared with the dry and 

flooded.  

2. It is evident that MQL improves surface roughness finish depending upon the work–tool materials and 

mainly through controlling the deterioration of the auxiliary cutting edge.  

3. It is appeared that MQL system grows quite fast under dry and conventional machining due to more 

intensive temperature. 

 

7 FUTURE SCOPES OF MQL  

The future direction of MQL can be illustrated in the following way. 

• Metal cutting is one of the most extensively used manufacturing processes, and its technology continues to 

advance in parallel with the developments in material from surface of a work-piece to achieve the desired 

product and researcher always tried to fulfilled the requirement.  

• The new method of minimum quantity lubrication (MQL) system is the delivering metal cutting fluid to the 

chip-tool interface and by this method, a little fluid, when properly selected and applied, can make a 

substantial difference in how effectively a tool performs and is to reduce the machining costs by improving 

its quality and productivity. 

• MQL is a most environment friendly method and used to minimize the negative aspects of cutting fluid 

which will be most helpful for researcher in their further research work. 



Hossain and Abedin (2021): International Journal of Engineering Materials and Manufacture, 6(1), 50-59  

58 

• IV. By using MQL system it is possible to reduce friction, cooling and flushing away chips. The cutting 

performance of MQL machining is better than that of conventional machining. Researchers will be more 

benefits for future research work in this field.  

• MQL provides the benefits mainly by reducing the cutting temperature, which improves cooling effect and 

results in better surface finish. 

 

ACKNOWLEDGEMENTS 

The authors would like to acknowledge the Teachers and staffs in the Industrial and Production Engineering 

Department, DUET, Gazipur, Bangladesh for the entire supports and valuable suggestions and helps during the entire 

experimental work. 

 

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