Browse Topic: Electrical, Electronics, and Avionics

Items (54,163)

Experimental Characterization of Fabricated (310) and (210) Symmetrical Tilt High-Angle Grain Boundaries in Bicrystalline Copper Thin Films Using NaCl Substrates

2025-28-0034To be published on 02/07/2025

A novel sintering method of bridging the two mechanically polished and oriented single-crystals together face-to-face in a non-environmental controlled atmosphere to fabricate the bicrystal substrate of NaCl of macroscopic thickness, with a common zone axis and having planarity over large areas, has been developed. Epitaxial [001] bicrystalline thin face-centered cubic (fcc) metal film of surface-reactive metal-containing tilt grain boundary across the interface is first grown in high vacuum directly by flash deposition on initially fabricated [001] oriented bicrystalline substrate of NaCl. The [001] tilt boundary, thus produced, is examined by electron microscopy to characterize grain boundary morphology and structure. The findings of some preliminary investigations are then presented. A distinct atomic structure is observed for {310} and {210} inclination. Both HAADF-STEM and Diffraction images reveal that such fabricated high-angle grain boundary accommodates minor deviations from

DISH, NILABH, Gautam, Abhay, Behera, Rakesh, Banka, Hemasunder, CHAVAN, PRADEEP

DEVELOPMENT OF COMPOSITE PCM TO ENHANCE HEAT TRANSFER RATE WITH THE ADDITION OF NANOPARTICLES IN THERMAL ENERGY STORAGE

2025-28-0023To be published on 02/07/2025

This paper explores the augmentation of thermal conductivity in paraffin wax through the incorporation of aluminum oxide (Al2O3) and copper oxide (CuO) nanoparticles, leading to the development of composite phase change materials (PCMs). The objective is to enhance heat transfer rates, crucial for various energy storage applications including industrial waste heat recovery and solar thermal energy storage. Differential Scanning Calorimetry (DSC) testing was employed to experimentally investigate the thermal properties of the resulting nanocomposite PCM.The experimental results reveal that the nanocomposite PCM, composed of 96.14% paraffin wax, 2% aluminum oxide, and 1.6% copper oxide, exhibits 1.35 times increase in heat transfer rate compared to conventional paraffin wax. The integration of nanoparticles into the PCM matrix, facilitated by a magnetic stirrer at 50°C for 4 hours, results in uniform distribution and improved grain morphology, as evidenced by SEM images. Moreover, the

Tarigonda, Hariprasad, Kumar, YB Kishore, Kala, Lakshmi K, R L, Krupakaran

Cloud-Based Monitoring of Lithium-Ion Battery Management Systems for Health Estimation in Manufacturing Industries

2025-28-0200To be published on 02/07/2025

The increasing reliance on lithium-ion batteries in manufacturing necessitates advanced monitoring techniques to ensure their longevity and reliability. Cloud technology offers a solution by enabling real-time data collection, analysis, and accessibility, facilitating thorough monitoring and predictive maintenance. Digital twin technology, creating a virtual replica of the physical battery system, provides a platform for simulating real-world conditions and predicting potential issues before they arise. By integrating sensor data and historical usage patterns, the digital twin model can accurately predict battery degradation, aiding in the implementation of timely maintenance strategies. This proactive approach not only enhances battery operational efficiency but also extends their lifespan, leading to cost savings and improved safety. The paper explores the use of cloud-based monitoring systems to enhance the health estimation and management of lithium-ion batteries. A comprehensive

ZEESHAN, MOHAMMAD, AKRE, VINEET

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

Flow and Heat Transfer Characteristics of microchannel through various nanofluids

2025-28-0024To be published on 02/07/2025

The significant development of power convertors in electrical vehicles demand higher energy consumptions and in turn larger heat generations. To prevent overheating of power convertors a newly designed curved micro channel was designed diamond shaped and triangular cross-sections. The working fluids used are Gc3N4/Water (0.3%), Al2O3/Water (0.3%) nanofluids, and Al2O3-Gc3N4/Water (0.3%) hybrid nanofluid and evaluated the flow and heat transfer characteristics. The heat sink has a cross-sectional area of 80 × 48 mm², and the experimental study was conducted by varying the mass flow rate from 0.1 to 0.5 LPM under a constant heat flux of 50 kW/m². The experimental results revealed that the heat transfer rate and pressure drop for the pentagonal channel increased by 14.2% and 18.9%, respectively, compared to the triangular channel heat sink using hybrid nanofluids. This improvement can be attributed to the secondary flow generated in the oblique finned pentagonal microchannel heat sink

R L, Krupakaran, PETLA, RATNA KAMALA, Anchupogu, Praveen, Kala, Lakshmi K, Gangula, Vidyasagar reddy, Tarigonda, Hariprasad

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

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

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

Development of Grey Based ANFIS Model for Electrochemical Machining of Incoloy 800HT for Automobile Applications

2025-28-0043To be published on 02/07/2025

The aim of this study is to create an Adaptive Neuro-Fuzzy Inference System (ANFIS) model for the Electrochemical Machining (ECM) process using Incoloy 800HT material, with a specific focus on several performance aspects. The optimization strategy utilizes the combination of the Taguchi method and ANFIS integration. Incoloy 800HT is widely employed in the aerospace, nuclear, marine, and car sectors, especially in situations that are susceptible to corrosion. The experimental trials are designed according to Taguchi's principle and involve three machining variables: feed rate, electrolyte flow rate, and electrolyte concentration. This study investigates performance indicators, such as the rate at which material is removed, the roughness of the surface, and geometric characteristics, including overcut, shape, and tolerance for orientation. Based on the analysis, it has been determined that the feed rate is the main component that affects the intended performance criteria. In order to

C, Navya

Application of ANFIS Approach for Prediction of Process Parameters for Electrochemical Machining of Titanium Grade 9 Alloys for Auto parts

2025-28-0046To be published on 02/07/2025

Electrochemical machining (ECM) is a highly efficient method for creating intricate structures in electrically conductive materials, regardless of their hardness. Due to the growing demand for superior products and the necessity for quick design adjustments, decision-making in the manufacturing industry has become increasingly complex. This study specifically examines Titanium Grade 9 and suggests the creation of an Adaptive Neuro-Fuzzy Inference System (ANFIS) model for predictive modeling 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 9 provides more flexibility, efficiency, and accuracy in comparison to

Kiruthika, Jothi

Multiple Objective Optimization on Electrochemical Drilling of Nickel Alloy (Inconel 625) using Taguchi Grey Relational Approach for Automobile Applications

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

Silambarasan, R.

Design of Smart Assistive Headgear For The Blind

2025-28-0096To be published on 02/07/2025

This paper presents the development of a cost-effective assistive headgear designed to address the navigation challenges faced by millions of visually impaired individuals. Existing solutions are often prohibitively expensive, leaving a significant portion of this population underserved. To address this gap, we propose a novel human-machine interface that utilizes a synergistic combination of computer vision, stereo imaging, and haptic feedback technologies. The focus of this project lies in the creation of a practical and affordable headgear that empowers visually impaired users with real-time obstacle detection and navigation capabilities. The solution leverages computer vision for environmental analysis and integrates haptic feedback for intuitive user guidance. This paper details the design intricacies of the headgear, along with the implementation methodologies employed. We present comprehensive testing results and discuss the project's potential to significantly enhance

Manu, Rohith, S Nair, Sreeram, biju, Mariya, KM, Devika, Sadique, Anwar

Investigation on the Effectiveness of Phase Change Materials in Battery Thermal Management System of Electric Vehicles

2025-28-0178To be published on 02/07/2025

Electric vehicles (EVs) are a clean, sustainable alternative to conventional internal combustion engines representing a paradigm shift in the transportation sector. Electric vehicles (EVs) have significantly improved in performance in battery technology. With the rapid proliferation of Electric Vehicles (EVs), effective Battery Thermal Management Systems (BTMS) are essential to ensure optimal performance and longevity of the battery packs. This study aims to investigating the effect of Phase Change Materials (PCM) in a hybrid cooling of liquid cold plate with battery pack. With the rapid proliferation of Electric Vehicles (EVs), effective Battery Thermal Management Systems (BTMS) are essential to ensure optimal performance and longevity of the battery packs. This study aims to investigating the effect of Phase Change Materials (PCM) in a hybrid cooling of a liquid cold plate with the battery pack. In models of battery cell arrangement of 5x13 arrays of aligned modules with the PCM and

S, Palanisamy, Selvan, Arul Mozhi

Analysis and optimization of Drilling parameters using Hybrid based Taguchi-GRA analysis on Al7075

2025-28-0184To be published on 02/07/2025

This project aims to investigate the effect of carbide drill bits with different geometries on drilling 7075 Aluminum alloy (Al7075). The drilling on Al7075 will be performed by using CNC machine. The primary objective is to optimize drilling parameters to achieve better quality holes in Al7075, ensuring optimal assembly and product performance. The chosen input parameters for experimentation are spindle peed, feed rate, and tool geometry, while the selected output parameters are surface roughness, circularity error, and material removal rate. Three types of carbide drill bits twist, step, and Brad point are utilized for drilling Al7075. Machining trials involved drilling of holes on Al7075 according to L27 Taguchi’s orthogonal array (OA) approach using the solid carbide drill tools. Grey Relational analysis has been used to find the effect, percentage contribution, and significance of the process parameters, namely, cutting speed, feed rate, drill bit type. The focus of this article

Kala, Lakshmi K, Reddy, A. Damodara, Tarigonda, Hariprasad, R L, Krupakaran

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 PhD, Ravikumar, V, Muralidharan, D, Pradeep Kumar

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

Crash performance study on high-speed electric two wheeler battery enclosure

2025-28-0203To be published on 02/07/2025

The growth rate of Electric Vehicles (EVs) industry and the annual production rate have increased significantly over the years. This is due to the development of rechargeable electrical energy storage system (battery pack), which is the main power source for EVs. Lithium-ion batteries (LIBs) pack is predominantly used across all major vehicle category such as 2 wheelers, 3 wheelers and light commercial vehicle. LIB is one of the high energy-dense sources of volume. However, LIBs have a challenge to poses a risk of short circuits and battery pack explosions, when expose to an external damage. Controlled crash analysis is performed for various velocities ranging from 40 kmph to 70 kmph against an obstruction directly and at an offset from the wheel, so as to mimic the real-world crash of high-speed two-wheelers. The behaviour of the battery enclosure is examined through evaluating the structural integrity of the battery enclosure used in a realistic two-wheeler after crash at various

Venkatesan Sr, Aiyappan, Nelson, N Rino, HARIHARAN NAIR, ADARSH

FRONT AND REAR COLLISION AVOIDANCE SYSTEM WITH EMERGENCY BRAKING BY SHIFTING POLARITY FOR ELECTRIC TWO WHEELER

2025-28-0193To be published on 02/07/2025

The new vehicle performance has been continuously improved and the study results relating to the safety of driving have also been continuously reported and demonstrated, it is trying to find a balance point between the development of vehicle speed limit and the protection of drivers safety. This project looks into recent developments and research trends in collision avoidance and warning systems. It is an attempt to provide a bigger picture of the very diverse, detailed and highly multidisciplinary research in this area. Based on diversely selected research, our project explains the initiatives on the vehicle-level automation. In this project we try to develop a system to provide the prior to accident information so that it enables the vehicle to prevent the happening of accident. This project describes automobile collision avoidance system by using of an ultrasonic sensor for a vehicle. We utilize the electronic systems application embedded in a two wheeler that is anticipated to

Deepan Kumar, Sadhasivam

Development of Artificial Intelligence Tools for Electrochemical Machining of Inconel 625 by ANFIS approach

2025-28-0156To be published on 02/07/2025

The objective of this research is to develop an optimization method for the Electrochemical Machining (ECM) process on Inconel 625 material, taking into account various performance characteristics. The optimization relies on the amalgamation of the Taguchi method with an Adaptive Neuro-Fuzzy Inference System (ANFIS). Inconel 625 is extensively utilized in the aerospace, nuclear, marine, and car sectors, specifically in situations that are prone to corrosion. The experimental trials are organized based on Taguchi's principles and involve three machining variables: feed rate, electrolyte flow rate, and electrolyte concentration. This examination examines performance indicators, including the pace at which material is removed and the roughness of the surface. It also includes geometric factors such as overcut, shape, and tolerance for orientation. The results suggest that the rate at which the feed is supplied is the most influential element affecting the necessary performance standards

Ramesh Naik, Mude

Improvement in Shift Quality in an Automated Multi-Speed Transmission of a Battery Electric Vehicle through Optimization of Required Shift Force

2025-28-0105To be published on 02/07/2025

In the context of heavy-duty applications for Battery Electric Commercial Vehicles, the development of multi-speed transmissions paired with smaller traction motors is increasingly pertinent. This combination is essential for achieving the necessary gradeability while enhancing operational efficiency. However, the primary challenge lies in comprehending the shifting methodology in electric vehicles, which do not employ physical clutches to disengage the transmission from the traction motor during gear shifts. This unique characteristic of electric vehicles renders traditional methods for estimating shift force inapplicable, presenting a novel challenge for the industry. The advent of electric vehicles has presented opportunities for optimizing various attributes of mechanical powertrains. A particularly promising approach involves the design of a compact shift system that employs smaller actuators for automated gear shifting. During gear shifts, the unlocking of the dog clutch

Sharma, Saurabhkumar

Enhancing Solar Still Productivity with Aluminium Oxide Nanoparticles and Phase Change Materials

2025-28-0026To be published on 02/07/2025

The present study is focused on the integration of phase change materials (PCMs) and Al2O3 nanoparticles into solar stills presents a promising approach to enhance their efficiency. This paper explores the design and performance analysis of a solar still system incorporating PCMs and Al2O3 nanoparticles with different concentration like 200ppm and 400ppm. The primary goal is to investigate the impact of these enhancements on the solar still's productivity and thermal efficiency.The Aluminium Oxide Nanoparticle were synthesized by Sol-Gel method. The Aluminium Oxide particles were characterized by XRD, SEM, EDS, and FTIR etc. In this experiment TN+30 was used as phase change materials and Aluminium Oxide Nanoparticles used for energy storage materials. The water is taken about 15(ltrs) and the optimal depth of water found to be 1cm. The energy materials TN+30 along with Al2O3 shown improvement in collection efficiency with 200ppm and 400ppm was 21.65% and 32.97% when compared with PCM

R L, Krupakaran, PETLA, RATNA KAMALA, Anchupogu, Praveen, Tharehallimata, Gurubasavaraju, Kala, Lakshmi K

Efficient Heuristic for Solving Extremely Large-Scale Open Vehicle Routing Problems with Stringent Delivery Times

2025-28-0085To be published on 02/07/2025

This paper introduces a deterministic heuristic method for solving large-scale open vehicle routing problems (OVRPs) with stringent delivery times. The proposed method is based on the sweep algorithm and aims to obtain approximate solutions for large-scale OVRPs. Initial testing on smaller OVRP instances, with up to 500 customers, demonstrated that the method produces quick approximate solutions, with deviations not exceeding 5% from the best-known solutions (BKS). Further testing on 10 sets of standard benchmark instances, each involving thousands of customers, confirmed that the heuristic provides efficient approximate solutions with minimal CPU time consumption and uses a minimal number of vehicles. This demonstrates the method's effectiveness in handling complex open vehicle routing problems efficiently

Vangipurapu, Bapi Raju, Prasad, Malladi Jogendra

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, BASUROY, Suhashini, HUDGE, Ajay, Kang, Shung-Wen

Experimental investigation of chip morphology and machining parameters during nano-MQL assisted machining of Nimonic 80A

2025-28-0051To be published on 02/07/2025

This study focuses on the machining of Nimonic80A, a difficult-to-cut super alloy. Friction during the turning process can lead to affect surface quality and chip shearing, which results in different chip shapes. Turning experiments were carried out under the three machining conditions of cutting velocity (70, 140, and 210 m/min), feed rate (0.1, 0.15, and 0.2 mm/rev), and depth of cut (0.5, 0.75, and 1 mm). The experimental design was established using a Taguchi L27 orthogonal array for both dry and nano-MQL lubricant conditions. Surface roughness, chip reduction coefficient, tooth height, and tooltip temperature were among the response characteristics of interest. Suspension of graphene oxide in rice bran oil was used in the study to produce and used as nanofluids for minimum quantity lubrication (nano-MQL). Furthermore, the addition of GO nanoparticles introduces a tribo-film effect that reduces friction tracks in the chips and enhances surface smoothness. Ribbon chips, short, long

Kannan, Venkatesan

An Evaluation of Automotive Electric Vehicle Cell-to-Pack Battery Technology for Higher Power-to-Weight Ratio

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

The world is moving towards a green transportation system. The governments also push for green mobility. Electric vehicles are becoming more popular in Europe, China, India, and developing countries. The energy density plays a crucial role in the battery pack architecture. The OEMs are moving towards a higher power-to-weight ratio. Higher capacity battery packs are needed to increase the range of the vehicle. The battery pack architecture is vital in defining the gravimetric and volumetric energy densities. The battery architecture depends on the battery cell, battery cell chemistry, and Government regulations. The cell-to-pack battery technique aims to achieve a higher power-to-weight ratio by eliminating unnecessary weight in the battery architecture. In this work, different battery pack architectures were analyzed to enhance the higher power-to-weight ratio and volumetric ratio. The different architectures were evaluated using statistical techniques to meet an optimum design

K, Barathi Raja

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

Synthesis and characterisation of poly (aniline –co-chloroaniline) polymers and applications in automotive industries as paint coatings

2025-28-0037To be published on 02/07/2025

Polyaniline (PANI)-polymer based paints have emerged as a promising solution for enhancing the durability and performance of automobile surface coatings. These paint coatings offer superior corrosion resistance, conductivity, and environmental stability, making it an ideal. Here novel copolymers of dodecylbenzenesulfonic acid aided poly (aniline-co-m-chloroaniline) nanocomposites of various compositions were prepared by oxidative method in micellar solution. The nanocomposites were analyzed by using UV-Vis and FT-IR spectroscopic methods. The crystalline nature of the polymer was evidenced through XRD patterns. SEM revealed the presence of particles with spherical morphology 100 nm in diameter. The electrical activity of the doped polymer was found to be content increasing from 3:1 to 3:3 x 10-2 S/cm to 5.64 x 10-7 S/cm with chloroaniline. These copolymers are added as additives in manufacturing of paint. These novel paints offer multiple protective mechanisms, including barrier

Pachanoor, Vijayanand, MOORTHI, BHARATHIRAJA

Application of Grey Method for Multi Objective Optimization of Electro Chemical Machining of Titanium Alloy – Grade 9 for Aerospace Components

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

Krishnamachary, PC

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

Analysis of Mechanical Properties of Jute Woven Fiber Composites with Al₂O₃, B₄C, and SiC Particles Using ANFIS for Aerospace Applications

2025-28-0186To be published on 02/07/2025

The study comprehensively examines the mechanical properties of jute fiber polymer composites that are filled with various ceramic particles, including aluminum oxide (Al₂O₃), boron carbide (B₄C), and silicon carbide (SiC). Natural fiber composites are increasingly recognized as promising materials for a diverse range of engineering applications due to their exceptional properties, such as reduced weight, enhanced strength, and cost-effectiveness. Additionally, these materials offer the benefits of being biodegradable and renewable, which aligns with sustainable engineering practices. To explore these properties, the study employs the Response Surface Methodology (RSM) with a structured experimental design that incorporates three levels and three factors, enabling the creation of different combinations of process variables required for fabricating high-performance polymer composites. The research focuses on investigating the effects of these process variables on the flexural

SOMSOLE, LAKSHMI NARAYANA

Software Architecture for Autonomous Vehicles Using Matlab Simulink

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

Autonomous vehicles, or self-driving cars, utilize advanced sensors, control systems, and artificial intelligence to independently navigate and operate, offering substantial improvements in road safety, traffic management, and mobility. This paper details the development and simulation of control algorithms for key functionalities in a Level 3 autonomy model of autonomous vehicles using MATLAB Simulink and IPG CarMaker. The focus spans four critical areas: Autonomous Emergency Braking (AEB), Adaptive Cruise Control (ACC), Lane Keep Assist (LKA), and object detection, integrating low-level PID controllers for precise steering, throttle, and brake actuation. AEB employs advanced algorithms, including fine-tuned PID controllers at both high and low levels and kinematic algorithms, to achieve precise braking and stopping distances under varying conditions. ACC utilizes radar data processed through sophisticated PID controllers to maintain safe following distances while minimizing passenger

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

IoT Based Smart Parking System Using Cloud Services for Automobile

2025-28-0189To be published on 02/07/2025

This paper introduces a novel Internet of Things (IoT) and cloud-based parking management system aimed at significantly improving parking efficiency and user experience. The proposed system leverages sensor-equipped parking spaces and a central cloud platform to provide real-time occupancy information and automate vehicle detection. Individual parking spaces are monitored by sensors that transmit occupancy data to a central hub, aggregated by a NodeMCU microcontroller. This data is then securely stored and processed in the cloud, accessible to users through a web application or mobile app. This real-time information guides users directly to available spaces, eliminating unnecessary searching and reducing traffic congestion within parking areas. The system also eliminates the need for manual monitoring by automating vehicle detection, ensuring accurate and reliable occupancy data. By combining real-time information, automation, and a user-friendly interface, this intelligent parking

Deepan Kumar, Sadhasivam

An Uncertain Environment for Energy Management in a Fuel Cell/Ultra Capacitor Hybrid Electric Vehicle Using Neural Network

2025-28-0196To be published on 02/07/2025

This study explores the realm of energy management in fuel cell/ultra-capacitor hybrid electric vehicles (FCHEVs) in the presence of uncertainties. Resilience, alongside fuel efficiency and the slow dynamics of the fuel cell (FC) system, is considered a crucial performance criterion. Unlike previous research that mainly aimed at achieving optimal performance in deterministic settings, this study considers uncertainties affecting power generation, conversion, and demand. Errors can arise from various factors, including variations in operational conditions, estimation, and modeling. Neglecting such uncertainties in real-world scenarios can lead to increased operational costs, reduced overall system efficiency, performance failures, and even impractical outcomes due to violations of constraints. To address this, a Neural Network (NN) based energy management system (EMS) is proposed to ensure optimal yet resilient performance when input parameters are unknown. The suggested NN-based

Deepan Kumar, Sadhasivam

Prediction of Process Parameters for Electro Chemical Machining of Inconel 718 used in Aerospace Engine Turbine

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

Silambarasan, R.

Multiple Aspects Optimization on Electrochemical Drilling of Incoloy 800HT by Taguchi Grey Approach

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

D, PALANISAMY

Autonomous Drone Solution for Human-Wildlife Conflict Management

2025-28-0198To be published on 02/07/2025

Human-wildlife conflicts pose significant challenges to both conservation efforts and community well-being. As these conflicts escalate globally, innovative technologies become imperative for effective and humane management strategies. This paper presents an integrated autonomous drone solution designed to mitigate human-wildlife conflicts by leveraging technologies in drone surveillance and artificial intelligence. The proposed system consists of stationary IR cameras that are setup within the conflict prone agricultural areas, which utilizes machine learning to identify the presence of wild animals and to send the corresponding location to a drone docking station. An autonomous drone equipped with high resolution IR cameras and sensors is deployed from the docking station to the provided location. The drone camera utilizes object detection technology to scan the specified zone to detect the animal and emit animal repelling ultrasonic sound from a device integrated to the drone to

sadanandan, Vaishnav, Sadique, Anwar, George, Angeo Pradeep, Vinod, Vishal, Raveendran, Darshan Unni

Investigation on Heat Transfer Properties of Graphene Nanoplatelets Blended Distilled Water-Ethylene Glycol Mixtures in Battery thermal management system

2025-28-0089To be published on 02/07/2025

In this investigation, the performance of graphene nanoplatelets (GNP) during heat transmission has been examined. Compared to other nanoparticles, carbon nanostructures exhibit higher thermal conductivity due to their low density and integrated thermal conductivity. The experimental findings are relevant in that compared with the base fluid, nanofluid samples had heat transfer capability. The physicochemical characteristics of investigated GNP were characterized using X-ray diffraction analysis (XRD), a scanning electron microscope (SEM), and UV–Vis spectrophotometry. The thermal conductivity and physical properties in the base fluid of Distilled water- ethylene glycol (70:30) and 100 % vol. of glycol with 120 minutes of sonication time, based on graphene nanofluids were measured. Nanofluid concentrations of 0.025, 0.05, 0.075, and 0.1 wt% were obtained for graphene nanoplatelets in a specific surface area of 500 m2/g. After investigating dispersion properties, the stability of

S, Palanisamy, Selvan, Arul Mozhi

Prediction of Process Parameters for Electro Chemical Machining of Titanium Alloy – Grade 9 for Automobile components

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

Ramesh Naik, Mude

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

Application of ANFIS Approach for Prediction of Process Parameters for Electrochemical Machining of Titanium Grade 5 Alloy for Auto parts

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

D, PALANISAMY

A Machine learning Approach for the prediction of Surface Roughness Using The Tool Vibration Data In Turning Operation

2025-28-0152To be published on 02/07/2025

Surface roughness is a key factor in different machining processes and plays an important role in ergonomics, assembly, wear and fatigue life of components. Functionality, performance and durability of parts are also affected by surface roughness. Although maintaining an optimum surface roughness is a major challenge in many manufacturing industries. Surface roughness during machining depends upon machining parameters such as cutting speed, feed rate and depth of cut. Also, tool vibrations during machining have significant influence in surface roughness. In this work an attempt is made to predict the surface roughness of machined components during the turning process by using machine learning techniques with vibration signals. By varying different machining parameters and keeping other tooling and material properties same, a range of surface roughness values can be obtained. For each condition, corresponding tool vibration signals were recorded. Our experimental setup involves

S S, Safeer, Sadique, Anwar, D, Navaneeth

Vibration-based cutting tool condition monitoring in face milling process using wavelet features and machine learning algorithms – A comparative study

2025-28-0151To be published on 02/07/2025

In automotive applications, most of the engineering components come across the material removal process in manufacturing. Face milling is one of the prominent material removal processes wherein a multi-point cutter is used to machine the flat workpiece to bring it to its required dimension. In the material removal process, the cost of the cutting tool occupies the major part of the total manufacturing cost of a product. Also, the continuous usage of the cutting tool results in tool wear. The usage of the cutting tool after the threshold value of the tool wear deteriorates the surface finish of the workpiece which leads to product rejection. Hence, optimal tool usage is inevitable. The continuous monitoring of the cutting tool condition will ensure optimal tool usage. In the present work, four real-time tool conditions are considered, namely, fresh tool (G), tool flank wear (FW), tool flaking on rake surface (FL) and tool with broken tip (B). Vibration signals are acquired while milling

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

CogniGuardianRoadscape: Advancing Safety through AI-Driven Roadway Audits

2025-28-0019To be published on 02/07/2025

The escalation of road infrastructure anomalies, such as speed breakers and potholes, presents a formidable challenge to vehicular safety, efficient traffic management, and road maintenance strategies worldwide. In addressing these pervasive issues, this paper proposes an advanced, integrated approach for the detection and classification of speed breakers and potholes. Utilizing a sophisticated blend of deep learning methodologies and enhanced image processing techniques, our solution leverages Object Detection to analyze and interpret real-time visual data captured through advanced vehicle-mounted camera systems. This research meticulously details the comprehensive process involved in the development of this system, including the acquisition and preprocessing of a vast, varied dataset representative of numerous road types, conditions, and environmental factors. Through rigorous training, testing, and validation phases, the model demonstrates remarkable proficiency in recognizing and

Thangaraju, Shanmuganathan, Raja, Selvakumar

ALLOY WHEEL RIM LINEAR CRASH VALIDATION WITH BENCH LEVEL TEST PROCEDURE

2025-28-0008To be published on 02/07/2025

Crash test plays a very crucial role in determining the passenger safety along with driver safety in most modern vehicles. This has become a prominent factor for many buyers to choose a safe car. During crash test, many components tend to fail. Amongst them, the major safety critical component which hampers the drivability of a vehicle is Wheel and Tyre Assembly. With the introduction of low aspect tyres, the failure rate of these assemblies has increased. A very high importance is given to ensure these parts withstand the subjection load as it is directly related to function of vehicle. Many methods are available to test the Wheel and Tyre assembly to ensure they pass the crash criteria. We have developed a test method which can simulate the crash pattern in the rig/bench level. The method employs a mechanical actuator which can be operated at designated load application to ensure the assembly undergoes the anticipated failure. The process is repeated with different types of contact

Medaboyina, HarshaVardhan, muthupandi, J, Senniappan, Moorthy, Singh, Ram Krishnan, Gupta, Anjali

Development of Predictive Model for Prediction of Process Parameters for Electrochemical Machining of Inconel 718 for Aero Engine Parts

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

Ramesh Naik, Mude

FREESTANDING MODE TRIBOELECTRIC NANOGENERATOR FOR SELF POWERING IN AUTOMOTIVES

2025-28-0149To be published on 02/07/2025

The triboelectric nanogenerator (TENG) has emerged as a promising technology for converting ambient mechanical energy into electricity through the coupling of triboelectrification and electrostatic induction effects. This study explores the electrical output performance of a freestanding mode TENG with five-electrode interdigitated design through finite element analysis simulations in COMSOL Multiphysics. The open-circuit voltage (Voc) and transferred charge density (Δσsc) serve as the primary benchmarks evaluated. The open-circuit voltage (Voc) and transferred charge density (Δσsc) are evaluated across the electrode array. The simulations demonstrate that as d increases from initial contact to full separation, Voc remarkably increases from 60V to 6300V. Similarly, increasing σsc from 10 to 30 C/m2. These results highlight how the interdigitated geometry coupled with optimized dielectric properties can achieve exceptionally high Voc levels up to 6.3 kV, which is promising for powering

P, Geetha

Advancing Safety Measures: Exploring Lithium-Ion Battery Thermal Runaway and Battery Thermal Management Strategies

2025-28-0083To be published on 02/07/2025

In the era of EV adoption, lithium-ion batteries are extensively used in commercial and industrial applications. Under normal operating conditions, lithium-ion batteries are safe. However, they are highly sensitive to abnormal conditions, which can pose safety hazards. The primary safety concern with lithium-ion batteries is temperature management. Battery thermal runaway can lead to extended fires or explosions if left unattended. Nowadays, there is a wide range of lithium-ion battery technologies, with some considered comparatively safe, while others are more prone to thermal runaway due to battery mismanagement. This research emphasizes that thermal runaway can result from mechanical abuse, electrical abuse, or thermal abuse, heat generation phenomena, and critical thermal issues such as the solid electrolyte interface theory potentially leading to battery electrolyte leakage, fires, and explosions. Addressing these risks requires robust battery thermal management strategies and

Dhage, Sonam, K, Barathi Raja

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

Prediction of Process Parameters for Electro Chemical Machining of Titanium Alloy – Grade 5 for auto parts

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

THE EFFECT OF FIN GEOMETRIES ON HEAT SINK UNDER NATURAL CONVECTION

2025-28-0063To be published on 02/07/2025

In recent years, effective thermal management has become one of the most serious challenges in many technologies. Fins are surfaces that extend from an object to increase the rate of heat transfer to (or) from the environment by increasing convection. Normally flat rectangular fins are used, but to enhance the heat transfer, five different aluminum fin geometries along with a cylindrical heat sink were chosen. The first fin was flat fin, second one with rectangular edges, third one with elliptical perforations besides the rectangular edge, fourth one with triangular edges, last one with elliptical perforations besides the triangular edge. The main objective of this work is to study which fin geometry can give better heat transfer rate. The predictive results from this study are triangular edges with elliptical perforation was more effective to dissipate heat especially when located near the heat source. The thermal efficiency of the proposed fin geometry in a very good acceptable

srikar Rao, Chalivendula, Tarigonda, Hariprasad

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