Non Traditional Machining Research Papers (original) (raw)

The present study focuses on optimizing the process parameters during machining of NiTi (Nickel-Titanium) shape memory alloy by wire electric discharge machining (Wire EDM) for simultaneously maximizing material removal rate and minimizing tool wear rate u sing brass wire as electrode. Taguchi's design with utility and modified utility optimization techniques have been used for simultaneous multi-response optimization. Different analyses were performed to determine the optimal settings in both utility and mo dified utility concepts. The optimal results of both methods disclose that the pulse on time of 115µsec and pulse off time of 40µsec with spark gap set voltage of 20V are useful for maximizing material removal rate and minimizing tool wear rate. The optimization results indicate that the spark gap set voltage is the majority significant parameter that affects the tool wear rate and material removal rate.

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- Non Traditional Machining, Machining, Optimization, Ni-Ti Shape Memory Alloys

Non Traditional Machining notes

- by Shashidhar G S
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- Engineering, Mechanical Engineering, Laser, Non Traditional Machining

- by Vasant Aiholi
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- Non Traditional Machining, Machining, Multidisciplinary, Optimization

Newly developed metals and non-metals with extraordinary properties make traditional machining difficult or impossible leading to the development of non-traditional machining (NTM) processes. Large number of available alternatives, conflicting process criteria, limitations for processing different materials and shape applications and insufficiency of expert decision makers make NTM process selection problems complex. In this paper, the weighted utility additive (WUTA) method is proposed for solving the NTM selection problems. In order to validate the method one problem with previously published data is solved and obtained results are compared to the previous results. It is observed that the proposed WUTA method is quite proficient to solve such type of complex multi-criteria decision making (MCDM) problems with conflicting criteria. Furthermore, the proposed method is applied to find out the best suitable NTM process to generate a through cavity on ceramics with (t/w) <10. 1. Introduction Non-traditional machining (NTM) processes also known as non-conventional processes is a group of processes which uses mechanical, electrical, chemical or thermal energy or combination of these energies, but do not use sharp cutting tools in the conventional sense for removal of superfluous materials from the work piece. Requirement of advanced geometric designs on newly developed exotic work materials create intricate challenges on conventional manufacturing processes to attain the expected quality of work. This led to the development and establishment of NTM processes in the industry as efficient alternatives to conventional ones. Processing capabilities of NTM processes for required work material and shape feature combination is a key decision factor in NTM process selection [1]. Nowadays, different NTM processes with numerous highly developed capabilities are available and modernized recurrently [2, 3]. The selection of a non-traditional machining (NTM) process is often observed to be a multi-criteria decision-making problem with conflicting and diverse objectives. The past researchers using different MCDM methods in last few years have already successfully solved the NTM selection problems for different applications. Yurdakul and Çoğun [4] developed combined technique for order preference by similarity to ideal solution (TOPSIS) and an analytical hierarchy process (AHP) methods for NTM processes selection and proved the effectiveness of process through numerous examples. Chakraborty and Dey [5,6] have presented an AHP-based method for NTM process selection and also developed a QFD-based expert system for NTM processes selection, where a score value developed through prioritized comparison matrix is used to sequence the processes. Das Chakladar and Chakraborty [7] developed an automated expert system based on combined TOPSIS and AHP methods for automated NTM processes selection. In this paper, a modified UTA method considering the criteria weight values is proposed for NTM process selection and this novel approach is called as weighted UTA (WUTA) method.

- by Dr. Prasad Karande
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- Non Traditional Machining

Intricate metallurgical properties of newly developed materials and alloys as well as requirement of machining complex shape geometries for modern industrial applications boost demand for use of non-traditional machining (NTM) processes. Scarcity of expert manpower, conflicting multiple criteria as well as large number of alternatives with vastly different specifications and capabilities, make the NTM process selection a complex task. Therefore, selection of the most appropriate NTM process for a particular application needs the use of a systematic methodology. Even though, few multi-criteria decision-making methods have already been employed by the past researchers to select NTM processes, the need for a simple and sound mathematical approach still exists. In this paper, a simple mathematical model, i.e. reference point approach is applied to select the most suitable NTM processes for generating through cavities on ceramics and cylindrical through holes on titanium.

- by Dr. Prasad Karande
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- Non Traditional Machining

Electric discharge machining (EDM), sometimes colloquially also
referred to as spark machining, spark eroding, burning, die sinking or
wire erosion, is a manufacturing process whereby a desired shape is
obtained using electrical discharges (sparks). Material is removed
from the workpiece by a series of rapidly recurring current discharges
between two electrodes, separated by a dielectric liquid and subject
to an electric voltage. One of the electrodes is called the toolelectrode, or simply the ‘tool’ or ‘electrode’, while the other is called
the workpiece-electrode, or ‘workpiece’. EDM will help and support
the drive to quality cost and delivery. Knowledge of EDM will provide
the ability to design parts that are not possible or cost effective to
produce by any other method. The prospect of machining complex
shapes in hardened or exotic materials will continue to attract
engineers and designers to produce more challenging parts and
profile.

- by DEBKUMAR RUIDAS
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- Non Traditional Machining

This paper reports the effects of machining parameters on surface roughness in cylindrical wire electrical discharge grinding (WEDG) process. In this research tungsten carbide is used as workpiece. A rotary axis spindle is set up in the electric discharge machine in a submerged dielectric environment so as to machine cylindrical parts. The speed of the spindle is maintained constant at 200 rpm. Experiments have been under different process conditions like peak current, voltage, pulse off time and number of passes. Number of passes in the wire electric discharge grinding decreases the surface roughness.

- by Parthi PSG
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- Non Traditional Machining, Micromachining

This article highlights and focuses on laser beam machining (LBM) of aluminum and its alloys. It begins by providing a brief overview of various conventional (chip forming) and nonconventional machining techniques employed for aluminum-based materials. Later, it explicitly provides features of LBM techniques employed for aluminum and its alloys for different types of machining.

Abrasive waterjet machining (AWJM) is a new machining process, the advantages of which include low cutting temperatures, no heat damage to the material being cut, minimal dust, and low cutting forces. This paper presents a state of the art review of research in this new process. The main topics discussed are mechanics of material removal, productivity, cutting forces, surface quality and nozzle wear.

Conventional machining of polymeric composite materials is often both technically and economically less effective because the structural characteristics inherent in fibre reinforcement promote excessive tool wear. In recent years, abrasive waterjet machining (AWJM) has been proving to be successful in the machining of such materials. This paper presents a state of the art review of research in AWJM of polymeric composite materials. Among the main topics discussed are mechanisms of material removal, productivity and surface quality

- by PRABHJYOT SINGH
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- Non Traditional Machining

Despite the large number of abrasive waterjet machining (AWJM) models developed so far, there still has been confusion about the nature by which workpiece surfaces are eroded. The finite element method (FEM) could provide both qualitative and quantitative means in order to explain the AWJ erosion process. This paper presents an attempt to model the AWJM process using the powerful tool of the finite element method. The main objective is to develop an FE model which would enable to predict the depth of cut without any cutting experiments. The new model takes into account the precise representation of the constitutive behaviour of the workpiece material under AWJ dynamic loading conditions. Interaction of the abrasive particle with the workpiece material is traced at small time increments. The model accurately predicts the depth of cut as a result of AWJ impact and the results are in good agreement with experimental results.

In order to realize the manufacturing/machining demands thrived by newer, hard and difficult-to-machine materials being utilized in the present day industries, an assortment of non-traditional machining (NTM) processes has been developed over the past few decades. These processes are capable of generating intricate and complex shapes with high degree of accuracy, close dimensional tolerance and better surface finish. In this paper, a decision guidance framework is developed in Visual BASIC 6.0 to help the process engineers in selecting the most appropriate NTM process for a specific work material and shape feature combination. It also assists in identifying the ideal process parameter combinations for the most suitable NTM process. The derived results highly corroborate with the opinions of the experts in the related field, demonstrating the acceptability of the developed system.

- by KANIKA PRASAD
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- Decision Making, Non Traditional Machining, Machining Parameters

Understanding the exact nature of erosion of workpiece materials by abrasive waterjet machining (AWJM) is still confused, although it is important for successful modeling of this promising process. This paper presents a first attempt to model the AWJM process using the powerful tool of the finite element method (FEM) in order to explain the abrasive particle-workpiece interaction. Also the model predicts the behaviour of the process. The main objective is to develop an FE model which would enable to predict the depth of cut without any cutting experiments. The new model takes into account the precise representation of the constitutive behaviour of the workpiece material under AWJ dynamic loading conditions which was ignored in previous AWJM models in which the flow stress was represented by a constant value. Additionally, deformations, stresses and strains occurring in the workpiece material in the vicinity of the cutting interface as a result of the erosion impact by AWJ, could be obtained. In the present model, forces acting on the abrasive particle need not be initially determined, as in previous AWJM studies, as they are automatically calculated at each time step. The results show that the finite element method is a useful tool in predicting abrasive-material interaction and AWJ depth of cut.

Despite the large number of abrasive waterjet machining (AWJM) models developed so far, there still has been confusion about the nature by which workpiece surfaces are eroded. It is believed that analysis of stresses generated at the AWJ cutting interafce could provide deeper insight to explain such an erosion behavior. This paper presents a stress analysis of AWJM using a nonlinear dynamic finite element (FE) code in order to explain the behaviour of the process. The main objective is to develop an erosion mechanism which would correctly describe the abrasive-material interaction. The new model considers both AWJ dynamic loading conditions and nonlinear material behavior. The results show that the workpiece material fails due to highly localized plastic deformation caused by compressive stresses, specially at the AWJ cutting interface. Also AWJM causes residual stresses to remain in the workpiece material after machining.

The main functions which feature the developed wire vibration detection and analysis system are: To be able to measure the wire position and displacement during machine idling as well as during EDM cutting. To perform a vibration analysis, based on the gathered data during the wire vibration measurements. This also in both modes, machining and idling. The vibration analysis includes, graphical output of the wire displacement data in a 2-D plane, Past Fourier Transform calculation (PFT), calculation of wire damping ratios, and frequency spectrum analysis.

- by DEBKUMAR RUIDAS
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- Non Traditional Machining

Erosion of ductile materials by abrasive waterjet machining (AWJM) is still a complex phenomenon. This paper presents a first attempt to simulate the abrasive waterjet machining (AWJM) process using the finite element method (FEM) in order to determine the workpiece response in this erosive wear process. Additionally, deformations occurring in the workpiece material in the vicinity of the cutting interface as a result of the high speed AWJ impact could be obtained. The results indicate that the finite element method is a useful tool in the prediction of the AWJ deformations.

Abrasive waterjet cutting is one of the unconventional cutting processes capable of cutting extensive range of difficult-to-cut materials. This paper assesses the impact of process parameters on surface roughness which is a significant machining performance measure in abrasive waterjet cutting of hastelloy. The experimental parameters were selected based on Taguch's design of experiments. Experiments were conducted in varying nozzle traverse speed, abrasive mass flow rate and standoff distance for cutting hastelloy using abrasive waterjet cutting process. The effects of these parameters on surface roughness have been discussed.

Monitoring of the abrasive waterjet (AWJ) cutting process has become increasingly important. The present paper proposes a
model for on-line depth of cut monitoring based on the acoustic emission (AE) response to the variation in AWJ depth of cut,
instead of the expensive and impractical vertical cutting force monitoring. The main objective is to use the AE technique in order
to predict the actual depth of cut in AWJ cutting under normal cutting conditions. It was found that the root mean square of the
acoustic emission energy (AErms) increases linearly with an increase in the depth of cut and could be used for its on-line monitor-
ing. The results show that the AE is the most suitable technique for AWJ monitoring, as the AE signal has high sensitivity to the
variation in the depth of cut.

- by ASHRAF HASSAN and +1
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- Non Traditional Machining, Electrical Discharge Machining, Applied Waterjet Technology, Machining

Aim of the experimental investigation was to determine the
effect of electric discharge machining parameters on surface
roughness of oil hardened non shrinkable (O6) steel. Though
vast research has been done to improve the surface finish of hard
metal machined by EDM, optimal choice of parameters for best
performance measures is still challenge. The experiments were
carried out on adequate range of machining parameters. Selected
input parameters for this study were peak current, pulse-on-time,
and pulse-off-time. Pure copper electrode with positive polarity
in dielectric medium was used to perform the investigation. The
optimal machining parameters peak current (8 Amp), pulse on (45
μs) and pulse off (9 μs) were originated by using Taguchi method
and ANOVA analysis. Design of experiment approach was used to
model the experimental data. It is found that interactions between
Peak current, pulse on, Voltage Gap and Flushing Pressure have
significant effect on the surface roughness.

- by Kamal Mahal
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- Manufacturing, Non Traditional Machining, Electric Discharge Machining

Modeling of abrasive waterjet machining (AWJM) has been finding widespread interest for the past twenty years. Due to the complex interaction of several AWJM parameters, combined with the nonlinear dynamic high speed impact of several thousands of small abrasive particles on the workpiece surface, the mechanism of material removal has not yet been fully understood. The current paper presents an attempt to explain the mechanism of material removal in AWJ, as a result of abrasive particle impact through step by step tracing of the abrasive particle as it is interacting with the workpiece material. The new model considers the elastic-plastic behavior of the workpiece material. Also the non linear dynamic loading conditions which are characteristic feautres of AWJM are accounted for in the pesent study. The failure of the workpiece material is examined analytically, by means of a virtual finite element (FE) AWJ experiment, and experimentally, by means of scanning electron microscopy (SEM) and surface topographies. Stress results indicate that the workpiece material is subject to severe highly localized plastic deformation and as a result, small overlapping craters are generated. These craters are formed by high compressive stresses at the cutting interface. The finite element results indicate a good agreement with experimental results.

Although several theoretical and experimental models have been developed for abrasive waterjet machining #AWJM), the exact nature of
erosion is not yet understood. This paper presents an attempt to model AWJM using the ®nite element method #FEM) in order to explain the
abrasive particle±workpiece interaction process. Also, the model predicts the depth of deformation as a result of abrasive particle impact.
The main objective is to develop an FE model which would enable the prediction of the depth of cut without any cutting experiments. The
new model takes into account the precise representation of the constitutive behavior of the workpiece material under AWJ dynamic loading
conditions which was ignored in the previous AWJM models. In the present model, forces acting on the abrasive particle need not be
initially determined, as in previous AWJM studies, as they are automatically calculated at each time step. The results show that plastic
deformation is very localized. Finally, the present FE results are consistent with experimental results.

This paper aims to develop a finite element (FE) model precisely simulating the multi-particle impact in the radial mode abrasive waterjet turning (AWJT). An explicit dynamic analysis was carried out to predict the crater profile resulting from the impact of the abrasive particles along a limited segment of the jet pass over the workpiece surface. The effect of both momentum transfer loss and abrasive load ratio was taken into consideration while calculating the impact velocity of the abrasive particles. To build a user-friendly model, the scripting feature of ABAQUS was involved to automatically perform all the repetitive modeling procedures. The presented FE model considers four variable turning parameters tested at five levels each, including impact velocity, abrasive mass flow rate, traverse rate, and workpiece speed. The obtained crater profile from the simulation process was utilized to calculate the depth of cut (DOC) at different parameter combinations. A comparison between ...

Electric discharge machining (EDM) process generally used for burrs free, less metallurgical damage, stress free and very precise machining and produces mould cavity, deep holes, complex shapes & size by arc erosion in all types of electro-conductive materials. In this process, the metal is removed from the work piece due to erosion caused by rapidly recurring spark discharge taking place between the tool electrode and work-piece. Tool electrode and wok-piece both submersed into the dielectric fluid. The main aims of this review paper work is to present the consolidated information about the contribution of various researchers on the machining applications of electric discharge machining process on Nickel-Base Super alloys materials, utilization of various tool and techniques for correlating experiment results and applications of product through the EDM. Nickel-Base Super alloys materials is widely used for fuel tanks,

- by Dr. Sushil K U M A R Choudhary and +1
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- Non Traditional Machining, Advanced Machining Processes, Micro-machining

Nickel-based superalloy Inconel 718 is one of the hardest materials owing to its high hardness and additional physical properties. It is the most commonly used superalloy in gas turbine, aerospace, and automobile sectors. Micro-milling is generally employed for precision manufacturing of tiny structures, but it is difficult to obtain good surface quality with micro-milling Inconel 718 because of its excellent mechanical properties like high strength and hardness. Atmospheric pressure cold plasma jet can effectively improve surface wettability without changing surface micromorphology, which is expected to have positive lubricating effects in micro-machining of difficult-to-cut materials. In addition, minimum quantity lubrication can induce coolants into the machining area more efficiently, and is especially appropriate for micro-machining. In this paper, we propose a composite micro-milling method combining plasma jet and minimum quantity lubrication to machine Inconel 718. The effect of plasma jet on machinability is investigated by performing micro-milling experiments under different atmospheres (dry, nitrogen jet, plasma jet, minimum quantity lubrication, and plasma + minimum quantity lubrication). Surface roughness, cutting forces, and residual stress are the measures using corresponding techniques. The results indicate that the atmospheric pressure cold plasma jet can efficiently improve surface quality and reduce cutting forces of Inconel 718.

- by Ghulam Mustafa
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- Non Traditional Machining, Surface integrity

ABSTRACT Nickel alloys possess the excellent potential at high temperature and resistance to oxidation/corrosion owing to its high nickel content. These materials necessitate non-traditional machining methods. The rotary ultrasonic machining (RUM) process comes into existence as a superior alternative to the conventional machining of nickel alloys. The processing of these alloys using RUM needs attention. This article details the multi-response optimization in RUM of nickel alloy using the desirability concept. The present work is carried out with two shapes of the tool: (i) Plain tool and (ii) lateral slotted tool. During RUM, the process parameters—power rating tool rotation, abrasive diamond grit size and feed rate are varied. Compared with the plain tool, the lateral slotted tool shows the more efficient machining rate (MR) with less tool wear (TW). The micro-graphs disclose the mechanism of MR and TW during RUM.

- by Dipesh Popli
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- Materials Science, Non Traditional Machining, Design of Experiments, ANOVA

Nickel alloys possess the excellent potential at high temperature and resistance to oxidation/corrosion owing to its high nickel content. These materials necessitate non-traditional machining methods. The rotary ultrasonic machining (RUM) process comes into existence as a superior alternative to the conventional machining of nickel alloys. The processing of these alloys using RUM needs attention. This article details the multi-response optimization in RUM of nickel alloy using the desirability concept. The present work is carried out with two shapes of the tool: (i) Plain tool and (ii) lateral slotted tool. During RUM, the process parameters-power rating tool rotation, abrasive diamond grit size and feed rate are varied. Compared with the plain tool, the lateral slotted tool shows the more efficient machining rate (MR) with less tool wear (TW). The micro-graphs disclose the mechanism of MR and TW during RUM.

- by Dipesh Popli
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- Non Traditional Machining, Rotary ultrasonic machining

In this paper, the effect of chromium powder mixed dielectric fluid on machining characteristics of AISI D2 die steel has been studied. Peak current, pulse on time, pulse off time, concentration of powder are the process parameters. The process performance is measured in terms of material removal rate (MRR), tool wear rate (TWR) and surface roughness (SR). The research outcome will identify the important process parameters that maximize MRR, minimize TWR and SR. The design of experiment has been undertaken using Taguchi method. ANOVA analysis has been used to investigate the percentage contribution of each process parameter for optimizing the performance. The study indicates that all the selected parameters except pulse off time have a significant effect on MRR. Current is found to be the most significant factor for MRR and TWR. With increase in current, TWR increases. Also, surface roughness increases with increase in pulse off time.

- by Sunil Sharma
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- Manufacturing, Non Traditional Machining

The abrasive waterjet machining (AWJM) process is so complex, due to the interaction of several working parameters, that its micro erosion mechanisms have not yet been completely understood. Understanding the interaction of a single abrasive particle with the workpiece material constitutes the basic step in understanding the occuring complex erosion phenomena. This paper presents the results of an extensive program of AWJ experimentation, which was recently carried out at the department of Machine Technology.

Erosion of ductile materials by waterjet machining is still a complex phenomenon. This paper presents a finite element model of the waterjet machining (WJM) process. Cutting forces, deformations and stresses occurring in the workpiece material in the vicinity of the cutting interface as a result of erosion impact by the waterjet could be obtained. The results indicate that the finite element method is a useful tool in the analysis of this process. Further research work is currently being conducted by the authors.

The energy demands of world are increasing rapidly due to continuous economic development and population growth in developed as well as developing countries. Coal makes up around 27% of global primary energy and 37% of global electricity. Like other developing countries, India’s energy demands are also increasing. In India, Coal is the bulk primary energy contributor and demand of more than 70% of electricity is fulfilled by coal. Due to increasing energy demands, limited coal reserves and rapid increase in economic development, lots of question arises regarding life and qualities of the coal reserves. The aim of this research is to focus on availability of proved coal reserves, production and consumption of coal by different countries and regions of the world. The proved, indicated and inferred coal reserves available in different states of India have been discussed with production and consumption of coal by different states of India. Also, an attempt has been made to know the qualities of coal available in coal reserves of India. At last, life of coal of world as well as India has been estimated. The management policies that may be adopted to use coal in better ways considering environment pollutions have been discussed.

Optimization of wire tool vibration in WEDM

- by DEBKUMAR RUIDAS
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- Non Traditional Machining

The experimental investigation of material removal rate, and micro hardness during machining of OHNS steel using
EDM machine was study in this paper. The input parameters include peak current, pulse on time; voltage gap and
flushing pressure were used for experimental work. Mean effect plot and S/N ratio graphs have been used to
optimize the machining parameters of EDM on OHNS steel using the Taguchi method and ANOVA methods. It can
be observed that Current has the largest effect on the material removal rate of OHNS steel by machining. It can be
observed that flushing pressure has the largest effect on the hardness of OHNS steel by machining. The optimum
machining condition for material removal rate (MRR) with positive polarity are Current (30 A), Pulse-on (100 µs)
Voltage Gap (10 v) and flushing pressure (20 lb/in2). The optimum machining condition for with positive polarity
for hardness are, Current (10 amp.), Pulse-on (100 µs), voltage gap (20 volt) and flushing pressure (10 lb/in2).

- by Kamal Mahal
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- Manufacturing, Non Traditional Machining, Electric Discharge Machining

- by abhishek abrol
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- Engineering, Technology, Manufacturing, Non Traditional Machining

Deviation in machining process due to the temperature influence, cutting force, tool wear leads to highly inferior quality of finished product, especially in high speed machining operations where product quality and physical dimensions seems to be meticulous. Moreover, temperature is a significant noise parameter which directly affects the cutting tool and work piece. Hence the aim of this project work is to study the machining effect on 6063 Aluminium alloy at varies combinations of process parameters such as speed, feed rate and depth of cut; and also to determine the effect of those parameters over the quality of finished product. A L 27 Orthogonal Array (OA) based Design of Experiments (DOE) approach and Response Surface Methodology (RSM) was used to analyse the machining effect on work material in this study. Using the practical data obtained, a mathematical model was developed to predict the temperature influence and surface quality of finished product. The ultimate goal of the study is to optimize the machining parameters for temperature minimization in machining zone and improvement in surface finish.

- by KANNAN A
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- Non Traditional Machining, Machining, Micro machining