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Your search keyword '"Puthumana, Govindan"' showing total 25 results
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25 results on '"Puthumana, Govindan"'

1. Development of a low-cost volumetric additive manufacturing printer using less viscous commercial resins

Author

Pazhamannil, Ribin Varghese, Hadidi, Haitham M., and Puthumana, Govindan

Subjects
3D printing -- Methods, Polymerization -- Methods, Printers (Computers) -- Design and construction, Polymers -- Usage, Digital printing system, Monochrome printer, Printer accessory, Engineering and manufacturing industries, Science and technology
Abstract

The technological development of the 3D printing industry has been tremendous starting from stereolithography in the 1980 s. Low throughput and surface quality had been the major obstacles to this technology, which offers very limited constraints to the geometrical shapes. In this work, we designed a low-cost volumetric 3D printer that, unlike traditional 3D printers, polymerizes the whole geometry within the revolving resin container. Optimized projections needed for the polymerization of target objects were developed in MATLAB R2020b using the concepts of tomographic reconstruction. The rotation of the resin container and the projections rate were matched to develop the target geometries after the oxygen depletion. Commercially available low viscous Anycubic plant-based resins were used as the printing material. 3D objects of centimeter scale could be manufactured in 30 seconds with extremely low surface roughness in the sub-micron range. The dimensional deviation of final components from the CAD model was found to be within 5%. The overprinting on existing solid structures was successfully experimented with and thus opens the way for future developments. Commercialization of volumetric 3D printers would result in mass production of complex customer-specific functional components which in turn boosts the manufacturing sector significantly. KEYWORDS 3D printing, photopolymerization, tomography, volumetric additive manufacturing, 1 | INTRODUCTION The popularity of additive manufacturing technologies is attaining more reach due to their capability to fabricate complex customer-specific components. Ever since its inception in the 1980 s [...]

Published
2023
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2. Prediction of the mechanical properties of heat-treated fused filament fabrication thermoplastics using adaptive neuro-fuzzy inference system.

Author

Pazhamannil, Ribin Varghese, Hadidi, Haitham Mohammed, Edacherian, Abhilash, and Puthumana, Govindan

Subjects
POLYLACTIC acid, THERMOPLASTICS, POLYCARBONATES, STANDARD deviations, HEAT treatment, FIBERS, TENSILE strength
Abstract

The requirement for post-processing methods in 3D printing has increased due to its major limitations such as poor mechanical and surface properties. Thermal annealing, a heat-treatment procedure, has proven to be an excellent approach for increasing the mechanical strength of additive manufactured thermoplastics. The optimized thermal annealing parameters for maximum tensile strength are identified. The Adaptive Neuro-fuzzy Inference System (ANFIS) methodology is employed in this study to forecast the tensile strength of thermal annealed fused filament fabricated polylactic acid (PLA), carbon fiber filled polylactic acid (PLA-CF), and polycarbonate acrylonitrile butadiene styrene (PC-ABS). The root mean square error (RMSE) of the predicted tensile strength of PLA, PLA-CF, and PC-ABS are obtained as 1.012, 0.5, and 0.835 respectively. The coefficient of determination for the predicted model of thermoplastics PLA, PLA-CF, and PC-ABS is determined as 0.98, 0.99, and 0.89 respectively. The ANFIS model developed is successful in determining the tensile strength of annealed 3D printed thermoplastics at various annealing conditions of temperature and duration. Further, the study investigates the effect of heat treatment on the compressive, impact, and flexural properties of PLA prints. [ABSTRACT FROM AUTHOR]

Published
2024
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4. An Influence of Parameters of Micro-electrical Discharge Machining on Wear of Tool Electrode

Author

Puthumana Govindan

Subjects
micro-EDM, tool wear ratio, process inputs, statistical methods, main effects, interactions, regression analysis, Mechanics of engineering. Applied mechanics, TA349-359
Abstract

To achieve better precision of features generated using the micro-electrical discharge machining (micro-EDM), there is a necessity to minimize the wear of the tool electrode, because a change in the dimensions of the electrode is reflected directly or indirectly on the feature. This paper presents a novel modeling and analysis approach of the tool wear in micro-EDM using a systematic statistical method exemplifying the influences of capacitance, feed rate and voltage on the tool wear ratio. The association between tool wear ratio and the input factors is comprehended by using main effect plots, interaction effects and regression analysis. A maximum variation of four-fold in the tool wear ratio have been observed which indicated that the tool wear ratio varies significantly over the trials. As the capacitance increases from 1 to 10 nF, the increase in tool wear ratio is by 33%. An increase in voltage as well as capacitance would lead to an increase in the number of charged particles, the number of collisions among them, which further enhances the transfer of the proportion of heat energy to the tool surface. Furthermore, to model the tool wear phenomenon, a regression relationship between tool wear ratio and the process inputs has been developed.

Published
2017
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10. Micro-EDM process modeling and machining approaches for minimum tool electrode wear for fabrication of biocompatible micro-components

Author

Puthumana, Govindan

Subjects
Artificial neural networks, Electrical discharge machining, Modeling, Biocompatibility, Micro devices, Multiple linear regression
Abstract

Micro-electrical discharge machining (micro-EDM) is a potential non-contact method for fabrication of biocompatible micro devices. This paper presents an attempt to model the tool electrode wear in micro-EDM process using multiple linear regression analysis (MLRA) and artificial neural networks (ANN). The governing micro-EDM factors chosen for this investigation were: voltage (V), current (I), pulse on time (Ton) and pulse frequency (f). The proposed predictive models generate a functional correlation between the tool electrode wear rate (TWR) and the governing micro-EDM factors. A multiple linear regression model was developed for prediction of TWR in ten steps at a significance level of 90%. The optimum architecture of the ANN was obtained with 7 hidden layers at an R-sq value of 0.98. The predicted values of TWR using ANN matched well with the practically measured and calculated values of TWR. Based on the proposed soft computing-based approach towards biocompatible micro device fabrication, a condition for the minimum tool electrode wear rate (TWR) was achieved.

Published
2017

11. An Influence of Parameters of Micro-Electrical Discharge Machining On Wear of Tool Electrode

Author

Puthumana, Govindan and Puthumana, Govindan

Abstract

To achieve better precision of features generated using the micro-electrical dischargemachining (micro-EDM), there is a necessity to minimize the wear of the toolelectrode, because a change in the dimensions of the electrode is reflected directly orindirectly on the feature. This paper presents a novel modeling and analysis approachof the tool wear in micro-EDM using a systematic statistical method exemplifying theinfluences of capacitance, feed rate and voltage on the tool wear ratio. The associationbetween tool wear ratio and the input factors is comprehended by using main effectplots, interaction effects and regression analysis. A maximum variation of four-fold inthe tool wear ratio have been observed which indicated that the tool wear ratio variessignificantly over the trials. As the capacitance increases from 1 to 10 nF, the increasein tool wear ratio is by 33%. An increase in voltage as well as capacitance would leadto an increase in the number of charged particles, the number of collisions amongthem, which further enhances the transfer of the proportion of heat energy to the toolsurface. Furthermore, to model the tool wear phenomenon, a regression relationshipbetween tool wear ratio and the process inputs has been developed.

Published
2017

12. Effect of Micro Electrical Discharge Machining Process Conditions on Tool Wear Characteristics: Results of an Analytic Study

Author

Puthumana, Govindan and P., Rajeev

Subjects
Factor effect, Dielectric flushing factor, Tool wear rate, Micro-EDM, Discharge energy factor, Correlation
Abstract

Micro electrical discharge machining is one of the established techniques to manufacture high aspect ratio features on electrically conductive materials. This paper presents the results and inferences of an analytical study for estimating theeffect of process conditions on tool electrode wear characteristicsin micro-EDM process. A new approach with two novel factors anticipated to directly control the material removal mechanism from the tool electrode are proposed; using discharge energyfactor (DEf) and dielectric flushing factor (DFf). The results showed that the correlation between the tool wear rate (TWR) and the factors is poor. Thus, individual effects of each factor on TWR are analyzed. The factors selected for the study of individual effects are pulse on-time, discharge peak current, gap voltage and gap flushing pressure. The tool wear rate decreases linearly with an increase in the pulse on-time. A maximum increase of 28.57% has been observed between peak current of 1and 1.5 A. TWR decreases with an increase in pressure by 19.6%.

Published
2016

17. Modeling the effects of electrical and non-electrical parameters on the material removal and surface integrity in case of µEDM of a non-conductive ceramic material using a combined fuzzy-AOM approach

Author

Puthumana, Govindan and Puthumana, Govindan

Abstract

Micro-EDM is a non-contact process based on the thermoelectric energy between a tool electrode and a workpiece. In μEDM process, the mechanism of material removal is melting and evaporation. The thermal energy in the discharge plasma helps remove material from the workpiece, at the same time deteriorates the quality and integrity of the workpiece surface. The material removal phenomenon in μEDM of partially conductive and non-conductive materials is very complex. This paper presents a novel approach to model the effects of electrical and non-electrical parameters on the material removal phenomenon and surface integrity for a non-conductive ceramic material. The fuzzy logic modeling system is employed for predicting the μEDM process responses. The trends in the material removal rate and hardness values with the chosen electrical and non-electrical parameter for the model and obtained using AOM approach are compared. The average deviation between the model predictions and the results obtained using AOM plots is less than 10%. The material removal rate (MRR) decreases linearly with voltage, indicating a difference in material removal mechanism in the μEDM of non-conductive materials.

Published
2016

18. The effect of TWD estimation error on the geometry of machined surfaces in micro-EDM milling

Author

Puthumana, Govindan, Bissacco, Giuliano, Hansen, Hans Nørgaard, Puthumana, Govindan, Bissacco, Giuliano, and Hansen, Hans Nørgaard

Abstract

In micro EDM (electrical discharge machining) milling, tool electrode wear must be effectively compensated in order to achieve high accuracy of machined features [1]. Tool wear compensation in micro-EDM milling can be based on off-line techniques with limited accuracy such as estimation of the volumetric wear ratio and continuous compensation proportional to the in-plane displacements (anticipated wear compensation) or real time wear sensing [2]. Tool wear per discharge (TWD) is a parameter based on which a novel approach has been developed for tool wear compensation based on discharge counting and statistical characterization of the discharge population [3]. The TWD based approach permits the direct control of the position of the tool electrode front surface. However, TWD estimation errors will generate a self-amplifying error on the tool electrode axial depth during micro-EDM milling. Therefore, accuracy of the tool wear compensation method as well as the geometry of the machined feature depends on the variability of TWD during machining operation. This paper analyses the effect of errors on the estimation of TWD on geometry of the machined features, in the case of a typical slot machining process. The error propagation effect is demonstrated through a software simulation tool developed by the authors for determination of the correct TWD for subsequent use in compensation of electrode wear in EDM milling. The implemented model uses an initial arbitrary estimation of TWD and a single experiment with determination of number of discharges and removed electrode volume. The simulation tool developed is used to calculate the effects of errors in the initial estimation of TWD on the propagation effect of error on the depth of the cavity generated. Simulations were applied to EDM milling of a slot of 5000 μm length and 50 μm depth, with a segment length of 100 μm and layer thickness of 1 μm. Simulations have been performed for TWD estimation errors ranging from -15% to +1

Published
2016

19. Effect of Process Parameters on the Total Heat Damaged Zone (HDZ) during Micro-EDM of Plastic Mold Steel 1.2738

Author

Puthumana, Govindan and Puthumana, Govindan

Abstract

In micro electrical discharge machining, three subsurface layersare formed on the workpiece, they are;recast zone, heat affected zone and converted zone, primarily due to heating-quenching cycles. The HDZ inmicro-EDM is characterized by cracks and weakness in the grain boundary and thermal residual stresses.This paper presents the effect of process parameters on the HDZ in micro-EDM of plastic mold steel 1.2738.As the energy of the sparks increases, the thickness of the HDZ increases and the average coefficient ofcorrelation between energy and HDZ considering three different sections of the zone is 0.8099. Therefore,the effect of process parameters governing the discharge energy are analyzed; they are: average current(Ia), peak current (Ip) and pulse ‘on-time’ (Ton). An overall increase in heat-damaged zone thickness by105% is observed with an increase in pulse on time.

Published
2016

25. RESPONSE SURFACE MODELLING OF TOOL ELECTRODE WEAR RATE AND MATERIAL REMOVAL RATE IN MICRO ELECTRICAL DISCHARGE MACHINING OF INCONEL 718.

Author

PUTHUMANA, GOVINDAN

Subjects
INCONEL, MACHINING, MICROELECTRONICS, WEAR resistance, MECHANICAL engineering
Abstract

Inconel 718 is a corrosion-resistant and high strength nickel-based alloy with wide range of applications, including components for cryogenic tankage, liquid fueled rockets and casings for aircraft engines. The material is characterized by high hardness, high temperature strength, low thermal conductivity and high strength causing it extremely difficult to machine. Micro-Electrical Discharge Machining (Micro-EDM) is a non-conventional method that has a potential to overcome these restrictions for machining of Inconel 718. Response Surface Method (RSM) was used for modelling the tool Electrode Wear Rate (EWR) and Material Removal Rate (MRR) with the input factors, such as voltage (V), peak current (Ip) and pulse on-time (Ton). The RSM analysis of variance results show that the main input factors' pulse off-time and voltage are significant in controlling the tool electrode wear rate at 95% confidence level. An increase in voltage from 30 to 45 V and pulse on-time from 1 to 3 µs causes a linear decrease in EWR by 35%. Using response surface modeling, a minimum EWR of 12.3184 µm³ /min and a maximum MRR of 37.2151 µm³ /min is obtained at a current of 1.07 A, pulse ontime of 4.44 µs, pulse off-time of 4.06 µs and voltage of 60 V. [ABSTRACT FROM AUTHOR]

Published
2017
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