Browse Topic: Design Engineering and Styling

Items (43,613)

Structural Analysis of Two-Wheeler Handlebars under Varied Loads

2025-28-0053To be published on 02/07/2025

This study presents a comprehensive structural analysis of a two-wheeler handlebar subjected to various loading conditions, aiming to evaluate its strength, durability, and safety. During operation, two-wheelers encounter multiple forces, making the handlebar a critical component for rider control and safety. The analysis begins by investigating the different types of loads experienced during typical riding scenarios, including static loads when the bike is stationary, and dynamic loads arising from rider movements, braking, and handling. The primary objective is to understand how these loads impact the handlebar's structural integrity. To achieve this, critical load cases are identified and categorized. Braking loads, which apply force primarily in the forward direction due to deceleration, are examined. Manhandling loads are analyzed to understand the multidirectional forces acting on the handlebar during transportation and parking. Additionally, vertical loads are assessed

Prajapati, Akash, Rathore, Avijit Singh, Bhaskara Rao, Lokavarapu

Gear misalignment optimization for Electric Drive Unit using Machine learning based Prescriptive Analytics

2025-28-0166To be published on 02/07/2025

Gear mesh misalignment in electric drive unit may result in shifts in the load distribution of a gear pair that can increase contact and bending stresses. It may move the peak bending and contact stresses to the edge of the face width, and also increase gear noise. Lower misalignment value is often required to reduce the peak bending and contact stresses and have a balanced load distribution along the gear flank. This paper delineates a method which is also called prescriptive analytics that combines virtual simulations, Machine learning (ML) and optimization techniques to minimize different gear misalignments for electric vehicle drive unit. The gear misalignments are dependent on stiffness of different components in the drive unit. So, a comprehensive approach that incorporates effect of individual components and their interactions is needed. Generally, an assembly level virtual simulation is performed to evaluate gear misalignments. In order to minimize the misalignments, manual

Penumatsa, Venkata Ramana Raju, Thomas, Benson, Black, Derrick, Jain, Sachin

Forced Vibration Analysis of Cracked Functionally Graded Beams

2025-28-0169To be published on 02/07/2025

This study investigates the forced vibration characteristics of functionally graded material (FGM) beams with square cross-sections featuring V-shaped cracks. FGMs, characterized by a gradual transition in mechanical composition from a ceramic to a metallic surface, offer unique advantages in various engineering applications due to their non-uniform microstructure, which imparts varying material properties throughout the structure. This research employs ANSYS Workbench to conduct a comprehensive numerical analysis, focusing on evaluating the frequencies and mode shapes of cracked FGM beams under simply supported boundary conditions. The analysis delves into the impact of three critical crack parameters: crack opening width, crack depth, and crack location. The findings highlight that the crack opening width significantly influences the vibrational frequencies of the FGM beam. Specifically, as the crack opening width increases from 0.002 meters to 0.01 meters, the frequencies decrease

D, Manish, C V, Prasshanth, N, Suhas, Bhaskara Rao, Lokavarapu

Numerical Analysis of Capillary Performance of Various Lattice Structures for Vapor Chamber Application

2025-28-0062To be published on 02/07/2025

Additive manufacturing has made it possible for the design of increasingly complex structures that require precise manufacturing. This may be particularly beneficial for heat pipe and vapor chamber design – particularly for the wick structure, a very important component. This study uses numerical simulation to analyze three different types of lattice structures of increasing complexity, in terms of their capillary performance. This is one of the most important parameters which determine the wick efficacy. Simple cubic, Column and Octet lattice models are computationally designed and CFD is used to simulate capillary action in a pipe of 0.4 mm inner radius for 2 milliseconds, after validation of the numerical model with existing experimental results. It is found that the Octet lattice (with the most complex inner structure) has the greatest capillary rise in the same amount of time. The rate of rise is not uniform for any structure, but is highest for Octet. This study demonstrates the

Sundararaj, Senthilkumar, Hudge, Ajay, Basuroy, Suhashini, Kang, Shung-Wen

Thermal Buckling Analysis of Axially Layered Aluminium Zirconia Functionally Graded Beam

2025-28-0120To be published on 02/07/2025

This study investigates the thermal buckling behavior of functionally graded material (FGM) thin beams with potential applications in automotive structures. The FGM beam is comprised of four axially layered sections, where the volume fraction of metal and ceramic varies across the thickness. The buckling analysis is conducted under three different boundary conditions: clamped-clamped, simply-supported-simply-supported, and clamped-simply-supported. The primary objective is to identify the optimal thermal buckling temperature of the FGM thin beam using the Taguchi optimization method. The beam configurations are designed based on a Taguchi L9 orthogonal array and analyzed using finite element software (ANSYS). Layers 1-4 of the axially layered beam are considered process parameters, while the thermal buckling temperature is the response parameter. Minitab software performs an Analysis of Variance (ANOVA) at a 95% confidence level to determine the most significant layer and its relative

Pawale, Deepak, Bhaskara Rao, Lokavarapu

Optimizing Titanium Alloy Grade 7 Machining with Grey Relational Analysis

2025-28-0049To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in materials that conduct electricity, irrespective of their level of hardness. Due to the growing need for superior products and the requirement for quick design adjustments, decision-making in production has become more complex. This study focuses on Titanium Grade 5 and suggests creating predictive models utilizing a Taguchi-grey technique to achieve multi-objective optimization in ECM. The trials are structured based on Taguchi's principles, utilizing Taguchi-grey relational analysis (GRA) to simultaneously maximize several performance indicators. This entails optimizing the pace at which material is removed, decreasing the roughness of the surface, and attaining precise geometric tolerances. ANOVA is used to assess the relevance of process variables that affect these measures. The suggested predictive technique for Titanium Grade 5 outperforms current models in terms of flexibility

Pasupuleti, Thejasree, Natarajan, Manikandan, Kumar, V, Sagaya Raj, Gnana, Krishnamachary, PC, Silambarasan, R

A reduced-order beam modelling approach of BIW for torsional and bending stiffness optimization

2025-28-0187To be published on 02/07/2025

NVH (Noise, Vibration, and Harshness) simulations of vehicle bodies are crucial for assessing performance during the design phase. However, these simulations typically require detailed CAD models and are time-consuming. In the early stages of vehicle development, when only high-level vehicle sections are available, designing the body-in-white (BIW) structure to meet target values for bending and torsional stiffness is challenging and often requires multiple iterations. To address these challenges, this study deploys a reduced-order modelling approach. This method involves identifying the beam-like sections and major joints within the BIW and calculating their sectional properties (area, area moments of inertia along the plane’s independent axes, and torsion constant). These components form a simplified skeleton model of the BIW. Load and boundary conditions are applied to the suspension mount locations at the front and rear of the vehicle, and NVH parameters are calculated. The results

Khan, Mohd Zishan Ali, Thanapati, Alok, Deshmukh, Chandrakant

Thermal Buckling Analysis of Axially Layered Aluminium Silicon Nitride Functionally Graded Thin Beam using Taguchi Method

2025-28-0172To be published on 02/07/2025

This study investigates the thermal buckling behavior of functionally graded material (FGM) thin beams, specifically targeting their application in engine hood panels. The FGM material utilizes Aluminum and Silicon Nitride, offering a combination of metal's strength and ceramic's heat resistance. The analysis focuses on optimizing the critical buckling temperature under various boundary conditions, mimicking the real-world scenario of an engine hood experiencing uneven heating. The FGM structure is designed with four axially arranged layers, where the ceramic and metal content gradually changes throughout the thickness. Finite element analysis software (ANSYS) is employed to evaluate the buckling behavior under different temperature loads. To optimize the thermal performance of the engine hood panel, the Taguchi L9 orthogonal array technique is implemented using Minitab 19 software. Layers 1-4 of the FGM beam are considered process parameters, and the critical buckling temperature

Pawale, Deepak, Bhaskara Rao, Lokavarapu

Investigating the Influence of Fiber Orientation on Frequency Response of Laminated Composite Plates using Taguchi Method

2025-28-0183To be published on 02/07/2025

This study investigates the frequency response characteristics of laminated composite rectangular plates, focusing on the influence of fiber orientation. The composite plates, composed of 12 layers of glass fiber reinforced polymer composites (GFRP), were chosen for their superior mechanical properties and broad applicability in engineering fields, including the automotive sector. In automotive engineering, these composites are valued for their lightweight properties and high strength, contributing to enhanced performance and fuel efficiency. The analysis employed a combination of finite element methods and Taguchi experimental design techniques to understand how fiber orientation affects the dynamic behavior of these plates. Finite element analysis (FEA) was conducted using ANSYS Parametric Design Language (APDL), a computational tool known for handling complex geometries and material behaviors accurately. This software enabled precise simulations of the dynamic responses of the

N, Suhas, C V, Prasshanth, U, Anish Kumar, Bhaskara Rao, Lokavarapu

Fabrication And Analysis of Pneumatically Actuated Soft Robotic Gripper With Negative Pressure

2025-28-0145To be published on 02/07/2025

Soft-bending actuators are gaining considerable attention in robotics for handling delicate objects and adapting to complex shapes, making them ideal for biomimetic robots. Soft pneumatic actuators (SPAs) are favoured in soft robotics due to their compliance and safety features. Using negative pressure for actuation, it enhances stability by reducing the risk of sudden or unintended movements, crucial for delicate handling and consistent performance. Negative pressure actuation is more energy-efficient, safe and are less prone to leakage, increasing reliability and durability. This paper involves development of a new soft pneumatic actuator design by comparing various designs and to determine its performance parameters. This paper depicts on designing, and fabricating flexible soft pneumatic actuators working under negative pressure for soft robotic applications. Uniaxial tensile tests were conducted to characterise the properties of materials used to fabricate the soft actuator, and

Warriar J S, Sreejith, Sadique, Anwar, George, Boby

A Novel Approach to develop the Exhaust Backpressure Measurement System for Automotive Application

2025-28-0168To be published on 02/07/2025

Backpressure is one of key acoustic performance evaluation criteria of exhaust muffler (or Silencer) /EATS (Exhaust after treatment system) as well as for the exhaust system. Exhaust back pressure is an important parameter for fuel efficiency of a vehicle. Typically, the engine manufacturer specifies an upper limit for this. Usually, exhaust back pressure is measured during the driving condition of the vehicle at maximum power condition of the engine either on road or on chassis dynamometer. Both these methods, need a lot of preparatory works, test setup arrangement, 3 or more manpower and special skills. In this research, authors are tried to develop a new backpressure measurement set up for automotive vehicle application, which is simple and innovative, to fulfill the backpressure test requirement. In this design, mainly following devices are used namely Pitot tube, Compressed air, Manometer (or pressure gauge), Thermocouple, Fluke thermometer, along with standalone exhaust layout

Mandal, Goutam, Biswas, Sanjoy

Enhancing O-Ring Performance Prediction Using Machine Learning

2025-28-0161To be published on 02/07/2025

O-rings are essential sealants in engineering applications, ensuring leak-tight seals, and preventing fluid leakage. Specifically, in Fuel Cells, they play a crucial role in maintaining system integrity by preventing working fluid leakages. Finite Element Analysis (FEA) is commonly employed for virtual assessments of sealant assemblies. By simulating the behavior of O-rings under various conditions, engineers can evaluate their performance. However, the traditional approach of varying individual input parameters to understand their impact on performance is time-consuming and extensive. To address this challenge, machine learning (ML) algorithms offer an efficient alternative to repetitive traditional FEA. By leveraging ML models, engineers can predict output parameters more effectively, streamlining the analysis process and enhancing accuracy. Despite the benefits of ML, different predictive models exhibit varying prediction performance, leading to inconsistency. Therefore, it is

Mallu, Venkata Reddy, Penumatsa, Venkata Ramana Raju, Chirravuri, Bhaskara, Duddu, Varaprasad, Miller, Ronald, Sahu, Abhishek

Finite Element Fatigue Life Prediction and Test Correlation for Seam Welded Joints in Sheet-Metal Assemblies

2025-28-0054To be published on 02/07/2025

Tractors, agricultural machines comprising diverse interconnected assemblies, collaboratively perform specific functions to attain desired outputs. Among these assemblies, the footstep assembly—an affixed structure or platform facilitating convenient access for the operator to the tractor cabin or platform. The components of the footstep assembly are fabricated from sheet metal and are connected using various joining technologies, such as bolts, welds, and others. During field operations, several failures have been noted in the footstep component, specifically at the weld connections. This paper delineates a methodology for simulating and predicting the occurrences of weld joint failures in the sheet-metal components. The inherent characteristics of the welding process lead to welded joints generally exhibiting a fatigue strength lower than that of the individual parts being joined. Additionally, welds are frequently applied at geometric features or points of section changes within a

Kumar, Arun, Pandey, Manoj Kumar, Thirugnanam, Vivekanndan, Mani, Suresh, Redkar, Dinesh

Innovative Design and Comprehensive Aerodynamic Performance Investigations on Various Possible Propeller Positions of an Advanced Hexacopter for Easy Manoeuvring

2025-28-0182To be published on 02/07/2025

This work deals with the computational investigations of the component performances of advanced hexacopters under various manoeuvrings of the focused mission profiles. The Advanced Hexacopter is one kind of multirotor vehicle that contains more propellers and flexible arms, which makes this multirotor very manoeuvrable and aerodynamically efficient. This hexacopter was designed specifically to detect leakages and the presence of harmful gases in and around nuclear power plants, along with enhanced payload-carrying capability. This advanced hexacopter contains a frame composed of modified arms equipped with coaxial rotors, which servo motors control. By providing specific and simple inputs to the microcontroller, the hexacopter can autonomously undergo forward and backward manoeuvrings. The primary objective of this study is to analyse and compare different propeller configurations that improve the manoeuvring capability of this unmanned aerial vehicle (UAV), specifically emphasizing

Raja, Vijayanandh, Narayanan, Sidharth, Elangovan, Logesh, Arumugam, Lokesh, Sourirajan, Laxana, Raji, Arul Prakash, Kulandaiyappan, Naveen Kumar, Gnanasekaran, Raj Kumar, Madasamy, Senthil Kumar

Mechanical Design and Packaging Strategies of a Cell-To-Pack Battery for An Automotive Electric Vehicle Based on Economic & Sport Vehicle Requirements

2025-28-0078To be published on 02/07/2025

The world is moving towards a green transportation system. Governments are also pushing for green mobility, especially electric vehicles. Electric vehicles are becoming more popular in Europe, China, India, and developing countries. In EVs, the customer's range anxiety and the perceived real-world range are major challenges for the OEMs. The OEMs are moving towards a higher power-to-weight ratio. Energy density plays a crucial role in the battery pack architecture to increase the vehicle range. Higher capacity battery packs are needed to improve the vehicle's range. The battery pack architecture is vital in defining the gravimetric and volumetric energy densities. The cell-to-pack battery technique aims to achieve a higher power-to-weight ratio by eliminating unnecessary weight in the battery architecture. The design of battery architecture depends on the cell features such as the cell shape & size, cell terminal positions, vent valve position, battery housing strength requirements

K, Barathi Raja

Design and Comprehensive Computational Performance Investigations of Hybrid Vortex Bladeless Turbine with PVEH Patches for Unmanned Surface Vehicles

2025-28-0185To be published on 02/07/2025

This work addresses an innovative method for improving energy harvesting in bladeless wind turbines (BWT) by utilizing the energy of vorticity, an aerodynamic effect (vortex scattering), piezoelectric vibration energy harvesting (PVEH) patches, and profile modifications of a wind turbine. The streamlined flow undergoes a transformation and generates a vortex in the vicinity of the structure when the wind impacts the BWT. As the velocity increases, the wind strikes the structure with a greater force, resulting in an imbalance that causes the structure to vibrate. In order to convert the vibrational energy of the wind turbine into electrical energy, the research investigates the use of a variety of profile modifications to capitalize on the aerodynamic effect generated by the structure. The PVEH patches are applied to the structure's surface to extract energy from renewable sources. This provides additional energy in addition to the energy produced by the BWT, which is advantageous in

Veeraperumal Senthil Nathan, Janani Priyadharshini, Rajendran, Mahendran, Arumugam, Manikandan, Raji, Arul Prakash, Sakthivel, Pradesh, Stanislaus Arputharaj, Beena, L, Natrayan, Ganesan, Balaji, Raja, Vijayanandh

Design and Computational Investigations on the Performance attainment and Structural Integrity of Advanced Horizontal Axis Wind Turbines for Unmanned Marine Vehicles

2025-28-0188To be published on 02/07/2025

The integration of advanced Horizontal Axis Wind Turbines (HAWTs) into Unmanned Marine Vehicles (UMVs) significantly enhances their operational efficiency by providing power source. These vehicles, designed for diverse applications, require efficient power systems to operate autonomously over extended periods. The major disadvantages are limited battery life and energy storage capabilities restrict their operational range and endurance of the UMVs. Utilizing HAWTs in UMVs provide a renewable energy source, reducing operational costs. This continuous power supply enhances mission capabilities and promote energy independence, making them ideal for long-term missions. Ansys Composite PrepPost (ACP) is employed for the pre-processing of HAWT blades, enabling the layering of different composites. The layering of various materials can significantly increase the strength and durability of the HAWT blades. These composites provide superior resistance to fatigue and environmental degradation

Gunasekaran, Durga Devi, Kannan, Haridharan, Sourirajan, Laxana, Vinayagam, Gopinath, Gnanasekaran, Raj Kumar, Kulandaiyappan, Naveen Kumar, Stanislaus Arputharaj, Beena, L, Natrayan, Raja, Vijayanandh

Effect of Single Vacancy Defect on Fundamental Frequency of Single Walled Carbon Nanotube

2025-28-0111To be published on 02/07/2025

This paper studies the effect of single vacancy defect on the fundamental frequency of carbon nanotube using finite element method. Cantilevered and bridged boundary conditions have been used for carbon nanotube with and without attached mass. There is less effect on the frequency of cantilevered structure due to presence of defect at center rather than its presence at other positions. Presence of defect near to fixed end shows more effect on fundamental frequency of bridged structure as opposed to other positions. Cantilevered structure with mass attached shows increase in effect due to presence of defect when mass ranges from 10-3 to 10-6 femtogram, while it seems to remain constant with further decrease in mass. This paper is mainly concerned about the overall effect of single vacancy defect at the different positions and with different parameters of carbon nanotube with and without attached mass on the frequency and frequency shift. Nano materials are playing a vital role in all

Kharche, Gaurav, Bhaskara Rao, Lokavarapu, B, Srivatsan, Balakrishna Sriganth, Pranav, Biswas, Sayan

Enhancing Thermal Performance of Trapezoidal Porous Medium Solar Ponds: Experimental and Numerical Analysis

2025-28-0207To be published on 02/07/2025

This study investigates the thermal efficiency of trapezoidal porous medium solar ponds through a multifaceted approach encompassing laboratory experiments, outdoor contrasts, and numerical analysis. Laboratory experiments were conducted to evaluate the heat storage capabilities of various porous materials. Outdoor contrast experiments, involving two mini solar ponds with a surface area of 0.42m×0.42m and a bottom area of 0.09m×0.09m, examined the thermal performance enhancement offered by porous medium incorporation. Factors such as the presence of a cover and the type of porous medium were analyzed for their influence on temperature distribution. Results revealed a notable increase in the maximum temperature of the solar pond by approximately 10°C following the introduction of porous medium. Furthermore, numerical evaluation utilizing MATLAB provided deeper insights into the experimental data, enriching our understanding of the thermal dynamics specific to trapezoidal porous medium

J, Vinoth Kumar

Optimization and Regression Modeling of Additive Manufacturing (Fused Deposition Modeling) of PETG Material for Automobile applications

2025-28-0146To be published on 02/07/2025

Additive Manufacturing (AM) techniques, specifically Fused Deposition Modeling (FDM), have transformed the manufacturing industry by allowing the creation of intricate shapes using different materials. Polyethylene Terephthalate Glycol (PETG) is a thermoplastic that is commonly used in additive manufacturing (AM) because of its advantageous mechanical properties, resistance to chemicals, and ease of processing. PETG is used especially for producing automotive components that require impact resistance, dimensional stability, and good surface finish. It can be used for interior trim parts, protective covers, and exterior components The primary objective of this study is to enhance the FDM process parameters for PETG material and construct regression models that can accurately forecast important performance metrics. An investigation was carried out through experimental trials to examine the impact of FDM process parameters, such as layer thickness, infill density, printing speed, and

Natarajan, Manikandan, Pasupuleti, Thejasree, Shanmugam, Loganayagan, Katta, Lakshmi Narasimhamu, Silambarasan, R, Kiruthika, Jothi

Machine Learning Based Variation Studies for Electric Vehicle Drive Unit Virtual System Models

2025-28-0171To be published on 02/07/2025

In electric vehicles development, manufacturing variations pose big challenge in designing various mechanical components as these variations directly impact various customer perceivable performance outputs. If the manufacturing variations can be included in design phase itself, overall robustness of the design can be enhanced. This paper delineates machine learning based methods to include manufacturing variations in designing drive units for electric vehicles. In an electric vehicle, the drive unit transfers power or torque from a battery through an inverter to wheels. The drive units are subjected to different types of loads under various vehicle maneuvers. To evaluate the drive unit system virtually, system level simulations are performed. Traditionally, nominal values of the several inputs such as bearing parameters, gear parameters and clearances etc. are used. However, the drive unit must be designed in such a way that outputs meet target considering all the variations of inputs

Penumatsa, Venkata Ramana Raju, Katha, Venkateswar, Black, Derrick, Jain, Sachin, Maddipati, Seshagiri

A hybrid algorithm for optimizing machining and spraying parameters in MQL-turning of Inconel 800H

2025-28-0042To be published on 02/07/2025

Inconel 800H superalloy is a difficult-to-turn material. This study aims to achieve optimal machining results, including reduced cutting force, improved surface roughness, and minimized residual stress, by optimizing input machining parameters like cutting speed, feed rate, spraying angle, and nozzle distance on Inconel 800H. The Taguchi L27 method is utilized for experimentation, while the Harris hawks optimizer (HHO) is applied in a multi-objective optimization model. Additionally, the Technique for Order of Preference by Similarity to the Ideal Solution (TOPSIS) is used to identify the optimal input parameters. Five distinct weight schemes were employed, including the Analytic Hierarchy Process (AHP), the Entropy weight method, Criteria Importance through Inter-Criteria Correlation (CRITIC), Grey relational analysis (GRA), and Principal Component Analysis (PCA) to determine response weights. The analysis revealed that the primary factor affecting all measured weights is the feed

Kannan, Venkatesan, Mokshajna, Kotha

Development of AI Prediction Tool for Fused Deposition Modeling of ABS Material for automobile applications

2025-28-0127To be published on 02/07/2025

Additive Manufacturing (AM), notably Fusion Deposition Modeling (FDM), has grown in popularity owing to its ability to create complicated forms from a variety of materials. This research aims to increase the efficiency and accuracy of the FDM process for Acrylonitrile Butadiene Styrene (ABS) material. ABS plastic material is an important material in automotive manufacturing due to its strength, durability, and versatility. It is used extensively for a wide range of components, including dashboard components, bumpers, fenders, exterior trim, and interior trim. The objective will be accomplished by the development of a prediction model using an Adaptive Neuro-Fuzzy Inference System (ANFIS). The research investigates the influence of FDM parameters, including layer height, nozzle temperature, and printing speed, on significant printing characteristics such as dimensional accuracy, surface quality, printing speed, and dimensional deviation. The essential data is derived from empirical

Natarajan, Manikandan, Pasupuleti, Thejasree, Kumar, V, Kiruthika, Jothi, Katta, Lakshmi Narasimhamu, Silambarasan, R

AI-Driven Optimization of Advanced Machining for Haste alloy by ANFIS Method

2025-28-0141To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in materials that conduct electricity, independent of their level of hardness. Due to the increasing demand for superior products and the necessity for quick design modifications, decision-making in the manufacturing sector has become progressively more difficult. This study primarily examines the use of Inconel 625 in vehicle applications and suggests creating regression models to predict performance parameters in ECM. The experiments are formulated based on Taguchi's ideas, and mathematical equations are derived using multiple regression models. The Taguchi approach is employed for single-objective optimization to ascertain the ideal combination of process parameters for optimizing the material removal rate. ANOVA is employed to evaluate the statistical significance of process parameters that impact performance indicators. The proposed regression models for Inconel 625 are more versatile

Natarajan, Manikandan, Pasupuleti, Thejasree, D, Palanisamy, Silambarasan, R, Krishnamachary, PC

OPTIMIZED DESIGN AND ANALYSIS OF A HIGH-PERFORMANCE, TRACK-FOCUSED QUAD BIKE FOR THE INDIAN MARKET

2025-28-0061To be published on 02/07/2025

A comprehensive approach to the optimized design and analysis of a track-focused quad bike specifically tailored for the Indian market. The design process integrates multiple critical factors, including driver ergonomics, aesthetics, and strategic component placement, to establish the optimal vehicle dimensions. The primary objective is to ensure comfort, functionality, and visual appeal while addressing the unique demands of the Indian terrain and user preferences. A meticulous selection process for tires and suspension geometry is conducted using the advanced Optimum Kinematics software. This optimization ensures that the vehicle can adeptly handle a variety of road conditions, providing superior performance and stability. The vehicle’s core structure features a space frame chassis, engineered to minimize tubing and facilitate ease of fabrication, contributing to both weight reduction and structural integrity. A robust 600cc 4-cylinder engine is selected, emphasizing an optimal power

Thanikonda, Praveen Kumar, Shaik, Amjad, Tappa, Raju, Ratlavath, Ramu, Navar, Adarsh, Challa, Ajith Kumar

A Comparative Study on fault diagnosis of Electrical vehicle motor testing machine Gear Components Using machine Learning algorithms

2025-28-0177To be published on 02/07/2025

Electric vehicles (EVs) are the way of the future for the automobile industry. The drive motor is a vital part of modern EVs. A motor testing machine is used to verify the critical parameters of the electrical motor, which is seen to be of the utmost importance. Electric motor characteristic curve points and their electromagnetic behaviour under different conditions are regularly found using the motor testing machine. But it has been noted that a flaw in the testing machine's helical gear arrangement causes frequent malfunctions and less-than-ideal performance, which impacts the assembly line's effectiveness in producing electric cars. The research project is to enhance the motor test bench apparatus by modifying crucial design parameters using machine learning and vibration signal analysis methods. Vibration signals are recorded at various gear settings before statistical features are extracted. Following that, these signals are classified using classifiers such Quadratic SVM and

S, Ravikumar, Syed, Shaul, V, Muralidharan, D, Pradeep Kumar

Software Architecture for Autonomous Vehicles Using Matlab Simulink

2025-28-0190To be published on 02/07/2025

Autonomous vehicles utilise sensors, control systems and machine learning to independently navigate and operate through their surroundings, offering improved road safety, traffic management and enhanced mobility. This paper details the development, software architecture and simulation of control algorithms for key functionalities in a model that approaches Level 2 autonomy, utilising MATLAB Simulink and IPG CarMaker. The focus is on four critical areas: Autonomous Emergency Braking (AEB), Adaptive Cruise Control (ACC), Lane Detection (LD) and Traffic Object Detection. Also, the integration of low-level PID controllers for precise steering, braking and throttle actuation, ensures smooth and responsive vehicle behaviour. The hardware architecture is built around the Nvidia Jetson Nano and multiple Arduino Nano microcontrollers, each responsible for controlling specific actuators within the drive-by-wire system, which includes the steering, brake and throttle actuators. Communication

Ann Josy, Tessa, Sadique, Anwar, Thomas, Merlin, Manaf T M, Ashik, Vr, Sreeraj

Method Development for Virtual Validation of Tractor Three-Point Linkage for customer practices in Haulage application

2025-28-0069To be published on 02/07/2025

This paper discusses the design and analysis of the Three-point linkage of an agricultural tractor for uncommon abusive usage practices during haulage applications. Some operators use the Three-point linkage for additional traction to navigate gradient surfaces, which requires additional wheel torque to overcome road slope when the trailer is attached. These maneuvers induce higher loads on Three-point linkage components, such as the lower link, lift rod, and powertrain components, which may lead to structural failures. A virtual simulation and lab-level test methodology need to be established to simulate the usage pattern upfront and predict potential failures. Multi-body dynamics (MBD) simulation was deployed to simulate the physics and extract realistic loads for Computer Aided Engineering (CAE) analysis. Data acquisition was carried out to record the strain levels during the uncommon haulage usage practices, which will be used for further studies. CAE analysis has been carried out

Kumar, Yuvaraj, Perumal, Solairaj, V, Ashok Kumar, Savsani, Smitkumar, Subbaiyan, Prasanna Balaji, Bhandwalkar, Anand, V V H Krishna Prasad, Tadikamalla

Optimization of Fused Deposition Modeling Using Taguchi-Based Grey Relational Analysis for TPU used in Auto parts

2025-28-0158To be published on 02/07/2025

Fused Deposition Modeling (FDM) is a highly adaptable additive manufacturing method that is extensively employed for creating intricate structures using a range of materials. Thermoplastic Polyurethane (TPU) is a highly versatile material known for its flexibility and durability, making it well-suited for use in industries such as footwear, automotive, and consumer goods. Hoses, gaskets, seals, external trim, and interior components are just a few of the many uses for thermoplastic polyurethanes (TPU) in the automobile industry. The objective of this study is to enhance the performance of Fused Deposition Modeling (FDM) by optimizing the parameters specifically for Thermoplastic Polyurethane (TPU) material. This will be achieved by employing a Taguchi-based Grey Relational Analysis (GRA) method. The researchers conducted experimental trials to examine the impact of key FDM parameters, such as layer thickness, infill density, printing speed, and nozzle temperature, on critical responses

Pasupuleti, Thejasree, Natarajan, Manikandan, Ramesh Naik, Mude, Silambarasan, R, D, Palanisamy

Data-Driven Optimization of Titanium Grade 7 Machining for Automotive Applications

2025-28-0143To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in materials that conduct electricity, irrespective of their level of hardness. With the rising demand for superior products and the necessity for quick design modifications, decision-making in the industrial sector becomes increasingly complex. This study specifically examines Titanium Grade 5 and suggests creating prediction models through regression analysis to estimate performance measurements in ECM. The experiments are formulated based on Taguchi's ideas, utilizing a multiple regression approach to deduce mathematical equations. The Taguchi method is utilized for single-objective optimization in order to determine the ideal combination of process parameters that will maximize the material removal rate. ANOVA is a statistical method used to determine the relevance of process factors that affect performance measures. The suggested prediction technique for Titanium Grade 5 exhibits

Natarajan, Manikandan, Pasupuleti, Thejasree, Kumar, V, Krishnamachary, PC, Somsole, Lakshmi Narayana, Silambarasan, R

Optimization of Fusion Deposition Modeling Parameters for PLA Material for Automobile Interior Using Taguchi based TOPSIS Approach

2025-28-0131To be published on 02/07/2025

Additive Manufacturing (AM) techniques, particularly Fusion Deposition Modeling (FDM), have revolutionized manufacturing by enabling the fabrication of complex geometries with various materials. PLA is mostly used for both under-the-hood components and aumobile interior items including carpets, upholstery and protective wrappings used in vehicle manufacture and transportation. This study focuses on enhancing the efficiency and quality of FDM for PolyLactic Acid (PLA) material through the application of Taguchi-Grey Relational Analysis (GRA) optimization. The research investigates the influence of FDM parameters, including layer height, nozzle temperature, and printing speed, on critical printing characteristics such as dimensional accuracy, surface finish, and mechanical strength. Experimental trials are conducted based on a Taguchi orthogonal array design to systematically explore the parameter space. Grey relational grades are calculated to quantify the relationships between input

Natarajan, Manikandan, Pasupuleti, Thejasree, D, Palanisamy, Katta, Lakshmi Narasimhamu, Silambarasan, R

Exploring Trapezoidal Salt Gradient Solar Pond Performance A Combined Numerical and Experimental Analysis with and without Reflective Covered Surface

2025-28-0201To be published on 02/07/2025

This study investigates the thermal performance of trapezoidal salt gradient solar ponds through a combined approach of experimental analyses and MATLAB numerical simulations. Salt gradient solar ponds offer a promising solution for sustainable energy generation by harnessing solar radiation and storing it as thermal energy for various applications. However, optimizing their performance is essential to maximize energy efficiency and economic viability. Laboratory experiments were conducted to evaluate the thermal dynamics of trapezoidal salt gradient solar ponds under different conditions, including the presence or absence of a reflective covered surface. These experiments provided valuable empirical data on temperature distribution and heat storage capacity. Additionally, numerical simulations were performed using MATLAB to model the thermal behavior of the ponds and validate the experimental findings. The simulations allowed for a deeper understanding of the underlying mechanisms

J, Vinoth Kumar

Designing Next-Generation Piston Geometry for LPG Powered Spark Ignition Engines: An Integrated CFD and Experimental Approach

2025-28-0123To be published on 02/07/2025

The efficiency of combustion has a major impact on the performance and emission characteristics of a spark-ignited LPG (Liquified Petroleum Gas) engine. The shape of the combustion chamber determines the homogeneous charge intake velocity, which is crucial for the turbulent motion that encourages flame propagation and quickens combustion. It need the right amount of compression ratio, charge squish velocity and turbulent kinetic energy to sustain combustion and propel laminar flames. There are a number of names for the motion of the charge within the cylinder: swirl, squish, tumble and turbulence. All of these terms affect how air and fuel are mixed and burned. Piston shape affects in-cylinder motion, which in turn reduces fuel consumption and improves combustion characteristics. The shape of the piston quench zone has a substantial impact on the charge velocity inside the combustion chamber. The impact on charge motion was analyzed using computer modeling using STAR-CD on pentroof

Sagaya Raj, Gnana, R L, Krupakaran, Pasupuleti, Thejasree, Natarajan, Manikandan

Development of ANFIS Predictive Model for Additive Manufacturing (Fusion Deposition Modeling) of PETG Material for automotive components

2025-28-0124To be published on 02/07/2025

Additive Manufacturing (AM), specifically Fusion Deposition Modeling (FDM), has become widely popular due to its capacity to produce intricate shapes using different materials. The objective of this study is to improve the efficiency and accuracy of the FDM process for Polyethylene Terephthalate Glycol (PETG) material, which is used for producing automotive components that require impact resistance, dimensional stability, and good surface finish. This will be achieved by creating a predictive model using an Adaptive Neuro-Fuzzy Inference System (ANFIS). The study examines the impact of FDM parameters, such as layer height, nozzle temperature, and printing speed, on important printing attributes like dimensional accuracy, surface quality, printing speed and dimensional deviation. The necessary information is obtained from experimental trials of FDM printing, which were conducted using various combinations of parameters. The experimental trials have been planned by Taguchi’s approach

Pasupuleti, Thejasree, Natarajan, Manikandan, Kumar, V, Kiruthika, Jothi, Katta, Lakshmi Narasimhamu, Silambarasan, R

Design and Test methodology development of Retainer plate in Forward and Reverse mechanism of Tractor Transmission

2025-28-0079To be published on 02/07/2025

ABSTRACT: In the Automobile tractor- transmission system plays major role to transfer power from Engine to final drive through gear box enabling Forward/reverse(F/R) movements during field operations and transportation conditions. The F/R retainer plate with idler gear, shaft is located between clutch housing and transmission gear box housing. If the retainer housing plate gets failure, then power will not be able to transfer from engine to transmission gear box main drive. In one of the tractor model Retainer plate failures was observed during field testing. To simulate the failure mode from field to lab condition, the resultant forces and angle were calculated based on the gear torque and gear ratio of the drive line assembly. The resultant loads were applied on Idle gear shaft assembly through servo actuator in cyclic mode at FTL lab. The failure was observed in the Retainer plate and location of failure was matching with Field failure. CAE Virtual simulation was carried out for

V, Saravanan, Mani, Suresh, Kumar, Sasi, More, Amit, Dumpa, Mahendra Reddy

A Simulation Methodology for Rainwater Ingress into Vehicle HVAC Cowl Box With Design Improvement

2025-28-0163To be published on 02/07/2025

Cowl Box is the first element of HVAC air passage and responsible for keeping rainwater away from blower unit without much impacting the HVAC air flow rate. Rainwater ingress to HVAC system affects passenger comfort. The main design objectives to be achieved in the design of HVAC cowl box includes minimizing the pressure drop and eliminating the chances of water ingress in cowl box. There are CFD tools available to study the cowl box pressure drop. However, methods available to study rain water ingress in cowl box are expensive in both mesh preparation and computational time. Using SPH (Smooth Particle based Hydrodynamics) based Preonlab tool, an attempt has been made in this work to study the design improvements of HVAC cowl box to eliminate the chances of flooding during raining. ANSYS FLUENT tool used to study the pressure drop of each design. The objectives of the simulation are to examine the cowl box pressure drop and water ingress quantity into the HVAC module. Designs with

Baskar, Subramaniyan, A, Boopalshanmugam, Raju, Kumar

Multi-Objective Optimization for Contemporary Drilling of Nimonic Alloy Using Taguchi-Grey Relational Analysis

2025-28-0050To be published on 02/07/2025

The objective of this research is to develop an optimization strategy for the Electrochemical Drilling process on Inconel 800HT material, taking into account various performance factors. The optimization strategy relies on the integration of the Taguchi method with Grey Relational Analysis (GRA). Inconel 800HT is extensively utilized in aerospace, nuclear, and marine industries, specifically in situations that are prone to corrosion. The experimental trials are structured based on Taguchi's principle and encompass three machining variables: feed rate, electrolyte flow rate, and electrolyte concentration. This inquiry examines performance indicators like the rate of material removal, surface roughness, as well as geometric parameters such as overcut, shape, and orientation tolerance. Based on the investigation, it is determined that the feed rate is the primary factor that directly affects the intended performance criteria. In order to enhance the accuracy of predictions, multiple

Pasupuleti, Thejasree, Natarajan, Manikandan, D, Palanisamy, Silambarasan, R, Krishnamachary, PC

Smart Machining of Titanium Grade 7: ANFIS Application for Process Parameter Prediction

2025-28-0160To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in materials that conduct electricity, regardless of their level of hardness. Due to the growing demand for superior products and the necessity for quick design adjustments, decision-making in the manufacturing industry has grown increasingly intricate. This study specifically examines Titanium Grade 5 and suggests the creation of an Adaptive Neuro-Fuzzy Inference System (ANFIS) model for predictive modelling in ECM. The study employs a Taguchi-grey relational analysis (GRA) methodology to attain multi-objective optimization, with the goal of concurrently maximizing material removal rate, minimizing surface roughness, and achieving precise geometric tolerances. Analysis of variance (ANOVA) is used to assess the relevance of process characteristics that impact these performance measures. The ANFIS model presented for Titanium Grade 5 provides more flexibility, efficiency, and accuracy in

Natarajan, Manikandan, Pasupuleti, Thejasree, D, Palanisamy, Kiruthika, Jothi, Silambarasan, R

Design and Finite Element Analysis of Pneumatically Actuated Soft Gripper under Combined Positive and Negative Pressure

2025-28-0044To be published on 02/07/2025

Soft-bending actuators have garnered significant interest in the field of robotics and biomedical engineering due to their ability to mimic the bending motions of natural organisms. In this study, we propose a novel soft bending actuator that utilizes combined positive and negative pressures to achieve enhanced performance and control. The actuator consists of a flexible elastomeric chamber divided into two compartments: a positive pressure chamber and a negative pressure chamber. By selectively applying positive and negative pressures to the respective chambers, controlled bending motion can be achieved. The combined positive and negative pressure approach allowed for faster response times and increased flexibility compared to traditional soft actuators. Additionally, the actuator exhibited a high level of controllability, enabling precise manipulation of the bending motion. Its flexibility, controllability, and enhanced performance make it suitable for a wide range of tasks requiring

Lalson, Abirami, Sadique, Anwar

Advanced Parameter Forecasting for Titanium Grade 19 Machining in Automotive Applications

2025-28-0045To be published on 02/07/2025

Electrochemical machining (ECM) is a remarkably effective technique for producing detailed designs in materials that can conduct electricity, regardless of their level of hardness. As the desire for high-quality products and the necessity for rapid design changes grow, decision-making in the industrial sector becomes increasingly intricate. This work focuses on Titanium Grade 9 and proposes the development of prediction models using regression analysis to estimate performance measurements in ECM. The experiments are designed using Taguchi's methodology, employing a multiple regression approach to produce mathematical equations. The Taguchi technique is utilized for the purpose of single-objective optimization in order to determine the optimal combination of process parameters that will optimize the rate at which material is removed. ANOVA is a statistical method used to assess the relevance of process factors that impact performance indicators. The suggested prediction technique for

Pasupuleti, Thejasree, Natarajan, Manikandan, Ramesh Naik, Mude, Silambarasan, R, D, Palanisamy

Innovative Design and Validation of Tandem Quadrant Assembly in Tractors

2025-28-0009To be published on 02/07/2025

The Tractor is essential in both agriculture and construction, equipped with a variety of implements for different operational conditions. Its hydraulic system is crucial for controlling these implements during fieldwork and transport. The quadrant assembly is a key part of the tractor's hydraulic control system, allowing the operator to manage important functions. This includes hydraulic control and draft control, enabling the farmer or operator to use the PC and DC levers to adjust the movement of implements during various tasks. Tractors are commonly used in fields and farms where the soil can be loose and muddy, particularly during wet puddling operations. In these muddy conditions, tractors can accumulate mud in critical components, such as the quadrant assembly. This can lead to functional issues, increased friction, and problems within the hydraulic system, especially affecting the controls for hydraulics and lever shifting for implement handling. As a result, operators may need

K, Bheshma, Phadtare, Yogesh, Gomes, Maxson, V, Ashok Kumar, Perumal, Solairaj, Magendran, G

Optimization and Regression Modeling of Fused Deposition Modeling for TPU Material used in automotive instrument panels

2025-28-0142To be published on 02/07/2025

Fused Deposition Modeling (FDM) is a widely recognized additive manufacturing method that is highly regarded for its ability to create complex structures using thermoplastic materials. Thermoplastic Polyurethane (TPU) is a highly versatile material known for its flexibility and durability. TPU has several applications, including automobile instrument panels, caster wheels, power tools, sports goods, medical equipment, drive belts, footwear, inflatable rafts, fire hoses, buffer weight tips, and a wide range of extruded film, sheet, and profile applications.. The primary objective of this study is to enhance the FDM parameters for TPU material and construct regression models that can accurately forecast printing performance. The study involved conducting experimental trials to examine the impact of key FDM parameters, such as layer thickness, infill density, printing speed, and nozzle temperature, on critical responses, including dimensional accuracy, surface quality, and mechanical

Pasupuleti, Thejasree, Natarajan, Manikandan, Sagaya Raj, Gnana, Silambarasan, R, Kiruthika, Jothi

Taguchi Based Grey Approach for Optimizing the Advanced Machining of Nickel Alloys in Manufacturing of Automotive Parts

2025-28-0147To be published on 02/07/2025

The objective of this research is to develop an optimization technique for the Electrochemical Drilling process on Inconel 625 material, considering various performance factors. The Taguchi approach, along with Grey Relational Analysis (GRA), forms the basis for optimization. Inconel 625 has a wide range of uses in industries such as aerospace, nuclear, and marine, especially in harsh environments. The experimental trials conducted in accordance with Taguchi's approach have utilized three machining variables: feed rate, electrolyte flow rate, and electrolyte concentration. When doing this examination, we analyze not only the rate at which material is removed and the roughness of the surface, but also other characteristics that indicate performance, such as overcut, shape, and orientation tolerance. The analytical findings indicate that the feed rate is the primary factor that directly impacts the required performance standards. Regression models are constructed to make predictions, and

Natarajan, Manikandan, Pasupuleti, Thejasree, Sagaya Raj, Gnana, Silambarasan, R, Somsole, Lakshmi Narayana

Performance Forecasting in Nickel Alloy Machining: A Study for Aerospace Engineering Applications

2025-28-0154To be published on 02/07/2025

The process of electrochemical machining, often known as ECM, is capable of effectively shaping complicated structures in materials that conduct electricity, independent of the materials' level of hardness hence especially used for automobile and aerospace applications. As a result of the demand for high-quality products and the desire for rapid design changes, the manner in which decisions are made in the manufacturing industry has become increasingly contentious. With the assistance of regression analysis, this study proposes the development of predictive models for the purpose of forecasting the performance measures in electrochemical machining of Inconel 800HT. The trials are designed in accordance with Taguchi's principles, and a multiple regression model is utilized in order to derive the mathematical equations. Taguchi's method can be applied as a methodology for single objective optimization in order to attain the most optimal combination of process parameters for the purpose

Natarajan, Manikandan, Pasupuleti, Thejasree, Sagaya Raj, Gnana, Silambarasan, R, Kiruthika, Jothi

CFD Analysis On the Effect Of Circular Cavity at Different Location of Airfoil Surface

2025-28-0074To be published on 02/07/2025

The paper presents the effect of cavity at different position of the airfoil on lift coefficient, drag coefficient and lift to drag ratio respectively. Here the analysis performed on SC (2) 0414 3D airfoil by using commercial CFD ANSYS FLUENT. The passive control method is applied by modifying the baseline airfoil surface coordinates to ascertain the aerodynamic behavior of the cavity at 40 %, 50% and 60 % of the chord length successfully where spalart turbulence model technique is chosen to solve boundary layer problems on adverse pressure gradient and tested at extended range of angle of attack -150 to 180. A structured meshing method was used. RANS, Reynolds averaged Navier-Stokes, was the solver used for the unsteady simulations. At Reynolds numbers (Re) of 10× 104 , the coefficients of lift, drag, pressure were observed. The study highlights the aerodynamic characteristics and stall effects at desired angle of attack. It is observed that the cavity at 40 % of the chord length

Pushparaj, Catherine Victoria, P, Booma Devi, D, Piriadarshani, Ganesan, Balaji, Ganesan, Santhosh Kumar, Raja, Vijayanandh

Process Parameter Prediction for Advanced Machining of Copper-Nickel Alloy Turbine Components

2025-28-0155To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in materials that conduct electricity, irrespective of their hardness. Due to the increasing demand for superior products and the necessity for quick design modifications, decision-making in the manufacturing sector has become progressively more difficult. This study focuses on Inconel 718 and suggests creating predictive models to anticipate performance metrics in ECM through regression analysis. The experiments are formulated based on Taguchi's principles, and a multiple regression model is utilized to deduce the mathematical equations. The Taguchi approach is employed for single-objective optimization to ascertain the ideal combination of process parameters for optimizing the material removal rate. ANOVA is employed to evaluate the relevance of process parameters that impact performance indicators. The proposed prediction technique for Inconel 718 is more adaptable, efficient, and accurate

Pasupuleti, Thejasree, Natarajan, Manikandan, Sagaya Raj, Gnana, Silambarasan, R, Somsole, Lakshmi Narayana

Grey Relational Analysis for Multi-Objective Optimization in Aerospace Machining of Titanium Grade 19

2025-28-0047To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in electrically conductive materials, irrespective of their hardness. Due to the growing need for superior products and quick design adjustments, decision-making in production has become increasingly complex. This study focuses on Titanium Grade 9 and proposes creating predictive models using a Taguchi-grey technique to achieve multi-objective optimization in ECM. The experiments are structured based on Taguchi's principles, utilizing Taguchi-grey relational analysis (GRA) to simultaneously optimize several performance indicators, including the material removal rate, surface roughness, and geometric tolerances. ANOVA is employed to assess the significance of process variables affecting these measures. The proposed predictive technique for Titanium Grade 9 outperforms current models in terms of flexibility, efficiency, and accuracy, providing enhanced capabilities for monitoring and control

Pasupuleti, Thejasree, Natarajan, Manikandan, Krishnamachary, PC, Katta, Lakshmi Narasimhamu, Silambarasan, R

Optimization of Biodiesel Production from Tannery Industry Fleshing Wastes Using Response Surface Methodology

2025-28-0115To be published on 02/07/2025

In response to rising emissions and pollutants, an alternative and environmentally friendly synthesis is gaining prominence on the energy sources. The leather industries generate substantial amount of waste and fleshing oil extracted from fleshing which is rich in lipids and presents a viable feedstock for biodiesel production. In this research work, Response Surface Methodology (RSM) is used to optimize the conversion of leather fleshing oil into biodiesel using three parameters such as operating temperature, reaction time, and molar ratio. Experiments were carried out to determine the most optimal conditions and the response on yield (%) and viscosity (mm2/s) based on a 17-run Box–Behnken Design matrix. Stochastic model parameters such as R2 (0.9715 and 0.9793), adjusted R2 (0.9349 and 0.9527), predicted R2 (0.8327 and 0.7656), and high F-values (26.52 and 36.78) of both responses (yield and viscosity) were found to be statistically significant and warranted model adequacy. ANOVA and

P, Kanthasamy, Selvan, Arul Mozhi, P, Shanmugam

Enhanced Aero Engine Components Manufacturing Through Predictive Models for Cupronickel Machining

2025-28-0137To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in materials that conduct electricity, regardless of their level of hardness. Due to the growing demand for superior products and the necessity for quick design changes, decision-making in the manufacturing industry has become increasingly intricate. The primary objective of this work is to concentrate on Inconel 718 and suggest the creation of an Adaptive Neuro-Fuzzy Inference System (ANFIS) model for the purpose of predictive modeling in ECM. The study employs a Taguchi-grey relational analysis (GRA) methodology to attain multi-objective optimization, with the target of maximizing material removal rate, minimizing surface roughness, and simultaneously achieving precise geometric tolerances. The relevance of process parameters affecting these performance metrics is assessed using analysis of variance (ANOVA). The ANFIS model suggested for Inconel 718 provides more flexibility, efficiency

Pasupuleti, Thejasree, Natarajan, Manikandan, Ramesh Naik, Mude, Kiruthika, Jothi, Silambarasan, R

Optimization of Wire Electrical Discharge Machining Parameters for Invar 36 Material Using Regression Modeling

2025-28-0122To be published on 02/07/2025

Wire Electrical Discharge Machining (WEDM) is a commonly employed technique for shaping conductive materials such as SAE 1010 steel, providing highly accurate machining capabilities. This low-carbon steel has excellent formability, weldability, and machinability, making it useful in many contexts including bolts, nuts, valves and cold headed fasteners. The objective of this study is to improve the efficiency and precision of the Wire Electrical Discharge Machining (WEDM) process for SAE 1010 material. This will be achieved by creating a predictive model using an Adaptive Neuro-Fuzzy Inference System (ANFIS). The study investigates the influence of WEDM parameters, specifically pulse-on time, pulse-off time, and discharge current, on important machining outcomes such as surface roughness (Ra), material removal rate (MRR). The experimentation has been planned and conduced as per Taguchi L9 orthogonal array design. The ANFIS predictive model is constructed by utilizing the obtained

Pasupuleti, Thejasree, Natarajan, Manikandan, Raju, Dhanasekar, Krishnamachary, PC, Silambarasan, R

Items per page:

1 – 50 of 43613