Browse Topic: Design Engineering and Styling

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Structural Redesign and Functional Integration of an Electrohydraulic Brake Valve for Enhanced Performance and Manufacturability2026-28-0002To be published on 02/12/2026
The Electrohydraulic Brake Valve (EBV) is a critical component in full-power brake systems, particularly in heavy-duty and off-highway vehicles, where precise braking control and system reliability are paramount. This paper presents a comprehensive cost and weight optimization initiative focused on the EBV housing, which currently accounts for approximately 75% of the total assembly weight due to its bar-machined construction. The project involved a complete redesign of the EBV housing with the dual objective of reducing mass and enhancing functionality. Key improvements include the integration of sensor ports for real-time pressure monitoring, a dedicated provision for nameplate mounting to support customer traceability, and a transition to a cast-based design optimized through advanced core modeling. Material substitution and structural simplification were explored to further improve manufacturability and cost-efficiency. Finite Element Analysis (FEA) was employed to validate the
R, Thangarajan
Virtual Development Kit (VDK) for Software Defined Vehicle2026-28-0120To be published on 02/12/2026
This paper explores the technological and architectural shifts essential for the advancement of Software-Defined Vehicles (SDVs), with an emphasis on decoupling hardware from software. It highlights the constraints of traditional development models and proposes modern architectural approaches, including MPU-based designs and virtualization techniques. Furthermore, it presents strategic pathways to cultivate an open and adaptable development ecosystem, empowering software engineers to experiment, innovate, and drive SDV evolution. These efforts aim to accelerate time-to-market and deliver a superior development experience across the SDV lifecycle. The idea is to develop a Virtual Development Kit (VDK) that enables the design, validation, and scaling of Software-Defined Vehicles (SDVs) even before the physical hardware is available. This comprehensive suite will include hardware platform emulators, operating systems, software stacks, and middleware tailored for high-performance computing
KHAN, Misbah UllahGupta, Vishal
Preliminary Design and Analysis of Dual Throat Fluidic Thrust Vectoring Nozzle for Supersonic Aerospace Application2026-28-0106To be published on 02/12/2026
The project investigates the performance characteristics of dual-throat nozzle used for fluidic thrust vectoring (FTV) in supersonic aircraft applications, offering a potential alternative to mechanical vectoring methods. Fluidic thrust vectoring provides benefits such as reduced weight, lower radar signature, and improved manoeuvrability and control. Computational methods are used to study the effects of geometric and operational parameters, including nozzle pressure ratios and secondary injection rate and injection angle, on thrust-vectoring efficiency and system dynamics. The study aims to develop optimized design configurations and validate using computational models.
Suresh, VigneshM, AkashSENTHILKUMAR, NIKILSundararaj, SenthilkumarA, Garry KiristenSingh, Swaraj
Evolution of a Novel Hybrid Stab-Link for a Born Electric Sports Utility Vehicle2026-28-0001To be published on 02/12/2026
The present study details the design evolution and failure analysis of a novel hybrid stabilizer bar link (stab link) developed for the front suspension of a born electric sports utility vehicle (SUV) platform characterized by higher gross vehicle weight (GVW), increased wheel travel, and constrained packaging space. To address these challenges, a unique hybrid stab link was designed featuring dual plastic housings at both the metal ball joint ends, connected by a steel tube, and achieving a 30% weight reduction while offering enhanced articulation angles for extremely lower turning circle diameter (TCD) of the vehicle, compared to the conventional stab link. The unique hybrid stab failed under complex loading conditions during accelerated durability testing (ADT), prompting a comprehensive investigation. The failure analysis included road load data acquisition across various stab bar diameter configurations evolved during suspension tuning, different stabilizer link designs evolved
SELVENDIRAN, PJ, RamkumarNAYAK, BhargavM, SudhanPatnala, Avinash
Multi-Objective Optimization of WAAM for Sustainable Production of Automotive-Grade Components2026-28-0030To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) has emerged as a promising technology for fabricating large-scale metal components with reduced material waste and lead time, aligning with the goals of sustainable manufacturing. This study presents a multi-objective optimization approach for WAAM to enhance both the manufacturing efficiency and sustainability of automotive-grade components. Key process parameters such as travel speed, wire feed rate, and current were systematically varied to evaluate their impact on dimensional accuracy, mechanical performance, and energy consumption. A statistical design of experiments framework was employed, and multiple performance objectives were optimized simultaneously using suitable decision-making techniques. The results demonstrate that optimized WAAM settings not only meet structural and functional requirements for automotive applications but also contribute to material and energy savings. This approach supports the integration of sustainability into
Pasupuleti, Thejasree
Aerodynamics Performance Analysis of Effect of Interference on Drone Arms Unsig Computational Fluid Dynamcis Simulations2026-28-0046To be published on 02/12/2026
In this research, the aerodynamic behavior of drone arms by comparing two different shapes – a traditional cylindrical arm and an airfoil-shaped arm. The main focus is to analyze and compare the interference drag created by both shapes using computational fluid dynamics (CFD). In general, cylindrical arms are commonly used in commercial and custom drones, but they create more drag during flight, which reduces the drone’s overall efficiency. On the other hand, airfoil-shaped arms have the potential to reduce drag and improve flight performance. To understand the drag characteristics, both geometries will be designed using Catia V5 software and simulated in ANSYS Fluent under uniform airflow conditions and k-ω turbulence model. The simulation was carried out at different inlet conditions such as freestream velocity of 50 m/s and 100 m/s and maneuvering at different angles of attack varies from 0 to 30 m/s with steps of 5 deg. This research work helps to reveal different aerodynamics
Ganesan, BalajiA, RohithvarmanM, Shyam SundarT, AathishS, SasikumarRaja, VijayanandhG, BoopathyGANESAN, SANTHOSH
CFD Simulation of Combustion and Emission Characteristics of Pure Spirulina Microalgae Biodiesel in a Single-Cylinder DI Diesel Engine2026-28-0043To be published on 02/12/2026
This study examines the combustion and emission characteristics of pure Spirulina microalgae biodiesel (B100) in a single-cylinder direct-injection (DI) diesel engine using computational fluid dynamics (CFD) in ANSYS Fluent. A 2D axisymmetric sector model of the engine was developed and simulated with a moving mesh to capture dynamic piston motion throughout the engine cycle. The Discrete Phase Model (DPM) was applied to simulate spray atomization and droplet evaporation, while a non-premixed combustion model and RNG k-ε turbulence model were used to resolve in-cylinder combustion dynamics. The thermophysical properties of Spirulina biodiesel were defined from literature data to accurately model fuel injection, vaporisation, and ignition phenomena. The study focused on analysing in-cylinder pressure, temperature, and emission characteristics such as NOx, CO, and soot, and compared the results with those of conventional diesel fuel. Simulation results indicated that Spirulina biodiesel
Kumar, B Varun
Statistical Optimization of Wire Arc Additive Manufacturing Parameters Using Taguchi Methodology2026-28-0035To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) is an emerging metal additive manufacturing process known for its high deposition rates and cost-effectiveness in fabricating large-scale components. However, the quality of the final build is highly sensitive to process parameters such as wire feed rate, travel speed, voltage, and current. In this study, the Taguchi method is employed to statistically optimize key WAAM process parameters with the aim of improving surface finish and mechanical integrity of the deposited parts. An L9 orthogonal array was used to design experiments, and signal-to-noise (S/N) ratios were analyzed to identify optimal parameter settings. Analysis of variance (ANOVA) was performed to determine the significance of each factor on the selected output responses. The results demonstrated that specific combinations of process parameters can significantly reduce surface roughness and enhance bead geometry. The optimized settings obtained through the Taguchi approach provide a
PN, Vani
Design and Development of Integrated Brake and Bull Cage System for Enhanced Tractor Performance and Sustainability2026-28-0005To be published on 02/12/2026
Conventional tractor transmission systems feature separate Brake and Bull Cage housings, with brakes often being proprietary components and Bull Cage designed by the Original Equipment manufacturer (OE). To optimize design and performance, an innovative integrated system was developed, combining an in-house braking system with a unitized Bull Cage assembly. This robust design reduces part count, eliminates proprietary dependency (except for friction liners), and enhances performance. Virtual simulations performed under RWUP conditions demonstrated enhanced strength and stiffness in the integrated design. In this Integrated Brake & Bull Cage assembly (IBCA) , the braking layout was reconfigured from a 4+1 friction design to a 3+2 configuration which improved balancing, enhancing customer braking experience and increasing contact area by 11%. This adjustment extends friction liner life and boosts mechanical advantage by 7.5%, significantly improving tractor stability and performance
Dumpa, Mahendra ReddyDhanale, SwapnilPerumal, SolairajGomes, MaxsonRedkar, DineshSavant, KedarnathV, SARAVANAN
Vibration Analysis of Rectangular and Circular Plates with Fixed Edges: Analytical and Computational Validation2026-28-0108To be published on 02/12/2026
This research is intended to comprehend the vibration response of two types of flat plates, rectangular and circular, when all their boundaries are constrained and they are in free vibration. These structures are common in aerospace components, mechanical enclosures, and civil structures where vibration parameters like natural frequency and mode shape decide their performance and reliability. We used three methods to research this: classical analytical models in terms of plate theory and Bessel functions, numerical analysis in ANSYS APDL, and Python customized code to model the theoretical calculations and show the vibrational response. The Python code computed the first 10 natural frequencies and plotted mode shape plots, which correlated well with analytical values at low modes and were useful in assessing where analytical models start deviating. For rectangular plates, analytical and simulation convergence was strong for the first mode with less than 1% deviation, but the deviation
N, SuhasR, SanjayBhaskara Rao, Lokavarapu
A Nature-Inspired Optimization Approach for Vienna Rectifier Control in EV Fast Charging Applications: Performance Comparison with NPC and Swiss Topologies2026-28-0112To be published on 02/12/2026
The growing adoption of electric vehicles (EVs), particularly those utilizing High Voltage battery systems, demands fast-charging infrastructure that ensures high efficiency and power quality. This study proposes a Golden Jackal Optimization (GJO)-based control strategy for a Vienna rectifier used exclusively in a High Voltage EV fast-charging system. Unlike conventional systems that incorporate an additional DC-DC converter stage, the proposed architecture utilizes only the Vienna rectifier for AC-DC conversion, thereby reducing system complexity and improving overall reliability. The GJO algorithm, inspired by the cooperative hunting behavior of golden jackals, is employed to optimize the switching control parameters of the Vienna rectifier, enhancing system performance in terms of efficiency, power factor correction (PFC), and total harmonic distortion (THD). A detailed comparative analysis is performed between the Vienna rectifier, Swiss rectifier, and Neutral-Point Clamped (NPC
R, Mohammed AbdullahN, Kalaiarasi
Computational fluid dynamic and fatigue analysis of turbocharger turbine wheel2026-28-0070To be published on 02/12/2026
Turbochargers are essential for improving engine efficiency by compressing air and delivering it to the engine at higher pressure, thereby increasing power output. The turbine wheel in a turbocharger operates under severe mechanical and thermal stresses, making it highly susceptible to fatigue failure, which can occur even under conditions below the rated operating load. To ensure long-term reliability, detailed analysis of the turbine’s fatigue life is essential. This study combines computational fluid dynamics with fatigue analysis to predict the performance and lifespan of a turbocharger's turbine wheel, with a focus on Inconel alloys known for their durability in extreme conditions. A numerical mesh analysis, employing 1,165,610 nodes, was conducted to achieve convergence for both temperature and stress evaluations, leading to the selection of a 2 mm mesh size. Pressure contours at the turbine-fluid interface revealed a pressure range between 1.09 and 1.05 bar, with most of the
Chelladorai, PrabhuBalakrishnan, Navaneetha KrishnanG, NareshT J, Sreejaun
An Integrated Model Approach for Predicting Vehicle Dynamics Performance during HiL Validation2026-28-0044To be published on 02/12/2026
In the automotive industry, increasing noise regulations are influencing product sales and passenger comfort, creating a need for more effective noise testing methods. Hardware-in-Loop (HiL) based virtual acoustic testing serves as a critical step before Driver-in-Loop testing, allowing for the assessment of noise levels inside and outside the vehicle under various conditions before real-world testing is performed. This study addresses the conversion of a physical vehicle model in the AMESim environment into FMU-RT (Linux) format, and the translation of a powertrain control system from Simulink to C++ code. Key challenges in the FMU-RT conversion include the integration of appropriate submodels for each component and enabling the interfaces necessary for SCANeR and virtual acoustic testing. In the C++ code conversion, challenges involved configuring the correct parameters, ensuring the model runs at a fixed time step and sampling time of 1 ms, and resolving issues related to the
Visuvamithiran, RishikesanChougule, SourabhSrinivasan, RangarajanLaurent, Nicolas
Statistical Modeling of Wire Arc Additive Manufacturing Parameters Using Regression Analysis2026-28-0024To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) is gaining prominence for fabricating large metal components due to its high deposition rate and cost-effectiveness. However, the quality and performance of WAAM-fabricated parts are strongly influenced by process parameters such as wire feed rate, travel speed, arc voltage, and current. This study presents a statistical modeling approach using regression analysis to predict the effects of these key parameters on critical output responses, including bead geometry, surface roughness, and material deposition rate. Experiments were designed using a structured methodology, and the collected data were analyzed to develop linear and multiple regression models. The accuracy and reliability of the models were evaluated using statistical metrics such as R² and p-values. The results demonstrate that regression-based models can effectively predict WAAM outcomes, enabling process optimization and quality control. This approach provides a valuable tool for
Pasupuleti, Thejasree
Parameter Selection Strategies for High-Performance WAAM Structures in Automotive Engineering2026-28-0033To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) has gained traction as an advanced fabrication technique for producing large, structurally demanding components in the automotive industry. Achieving high-performance WAAM structures requires precise control and selection of key process parameters, which directly influence mechanical strength, dimensional accuracy, and surface quality. This study investigates the effect of critical process variables—including wire feed rate, travel speed, current, voltage, and inter-layer cooling time—on the structural integrity of WAAM-fabricated components designed for automotive use. A systematic experimental approach, supported by statistical modeling and optimization tools, was employed to identify parameter combinations that yield optimal results. The outcomes demonstrate improved microstructural uniformity, reduced residual stresses, and enhanced tensile properties in the fabricated parts. The findings serve as a foundation for developing robust parameter
V, Aravind
Optimized Design, Analysis, and Validation of a Tractor Muffler for Enhanced Back-Pressure Control and Cost Efficiency2026-28-0004To be published on 02/12/2026
Internal combustion engines generate intense acoustic pulses during combustion, necessitating the use of exhaust mufflers to suppress noise emissions. With evolving regulations on permissible noise levels and the automotive industry's drive toward lightweight, high-performance vehicles, muffler designs must balance effective sound attenuation, minimal back pressure, and reduced mass. This study presents a comparative analysis of three muffler configurations serpentine, rectangular, and zigzag designed using SolidWorks for a light commercial vehicle (LCV) diesel engine. The models were evaluated using computational fluid dynamics (CFD) simulations to assess their acoustic and flow performance. Each design incorporated internal baffle arrangements to enhance sound absorption while aiming to minimize back pressure. The serpentine model featured a perforated baffle layout that promoted multiple reflections and dissipated acoustic energy more efficiently. Simulation results indicated that
Deepan Kumar, SadhasivamPalaniselvam, Senthil KumarD, AshokkumarR, KrishnamoorthyMahendran, MPasupuleti, ThejasreeG, DhayanithiL, BOOPALAN
Efficient Multi-Parameter Optimization of a Twist Beam Rear Axle for Electric Vehicles using TOPSIS method for Durability2026-28-0067To be published on 02/12/2026
This study investigates the parameter optimization of a Rear Twist Beam (RTB) for an electric vehicle (EV) during the early stages of product development. Adapting the RTB design from a current Internal Combustion Engine (ICE) vehicle platform presents a complex challenge: accommodating increased rear vehicle load while minimizing cost and maintaining existing rear hard points. To address this, a Computer-Aided Engineering (CAE)-driven optimization using the Taguchi method was employed, avoiding costly physical durability tests. The key design parameters considered were the thickness and material grade of the RTB's child parts: the cross beam, trailing arms, and reinforcements, while preserving their original shapes. An L8 orthogonal array was utilized to efficiently evaluate the influence of these parameters on durability performance, and the optimal combinations for maximizing durability were identified. Furthermore, an Analysis of Variance (ANOVA) was conducted to quantify the
Madaswamy, ArunachalamDhanraj, SudharsunGovindaraju, KarthikLokaiah, Srinivasan
Design and Analysis of Fixtures for HMC – HSX 8602026-28-0096To be published on 02/12/2026
Fixtures are used for holding the work piece to avoid misalignment and to achieve maximum accuracy in manufacturing. Complex work pieces of the pump such as liquid head, hydraulic manifold, gearbox require fixture. These components are manufactured in VMC (Vertical Machining Center) as well as in HMC (Horizontal Machining Center) and so to avoid loading and unloading time fixtures are designed as per the requirements. To design optimum fixture finite element analysis is to be done considering the machining procedure of the components. Cutting forces and clamping forces are taken into consideration during analysis. Analysis is carried out at different tool positions to calculate the maximum deformation occurred. Keywords: Fixture, clamp, cutting force, clamping force, Machining Center
Kshirsagar, SwapnaBhaskara Rao, Lokavarapu
Selection and Optimization of Process Parameters in Wire Arc Additive Manufacturing for Automotive Structural Applications2026-28-0039To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) has emerged as a promising technology for fabricating large, complex metal structures with reduced material wastage and improved design flexibility. In the automotive sector, WAAM offers significant potential for producing lightweight and high-strength components, particularly for structural applications. However, the quality and performance of WAAM-fabricated parts are highly dependent on the careful selection and optimization of process parameters such as wire feed rate, travel speed, arc voltage, current, and inter-pass temperature. This review focuses on the systematic evaluation of key process parameters influencing the mechanical properties, surface integrity, dimensional accuracy, and microstructural characteristics of WAAM-produced structures intended for automotive applications. The study also explores various optimization techniques—such as Taguchi, response surface methodology (RSM), and artificial intelligence (AI)-based approaches
V, Aravind
Parameter Optimization for Improved Surface Finish in WAAM-Fabricated Steel Structures2026-28-0023To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) is a cost-effective and scalable metal additive manufacturing technique widely used for fabricating large metallic components. However, surface finish remains a critical challenge, especially for structural applications where post-processing needs to be minimized. This study focuses on optimizing key process parameters to improve the surface finish of ER70S-6 steel structures fabricated using the WAAM process. Experiments were designed using a statistical approach to systematically vary parameters such as wire feed rate, travel speed, voltage, and inter-pass cooling time. Surface roughness was measured using standard metrology tools, and the results were analyzed to identify the most influential parameters. An optimized parameter set was proposed based on the experimental outcomes, leading to a significant reduction in surface roughness without compromising the structural integrity of the deposited material. The findings contribute to enhancing
PN, Vani
TOPSIS-Based Multi-Criteria Optimization of WAAM Parameters for Automotive Component Fabrication2026-28-0026To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) can make huge, complicated metal parts quickly and cheaply, making it popular in the automobile sector. This study uses TOPSIS, a multi-criteria decision-making method, to improve WAAM process parameters such wire feed rate, travel speed, and current. Automotive applications need surface roughness, deposition rate, and dimensional precision, which WAAM-fabricated components must meet. TOPSIS normalizes and ranks experimental findings to find parameter combinations that perform best across many quality metrics. The results show that integrated optimization improves component quality and consistency, making WAAM a feasible and economical sustainable vehicle manufacturing option.
Pasupuleti, Thejasree
AI-Driven Process Optimization in Wire Arc Additive Manufacturing of Nickel Alloys Using ANFIS2026-28-0025To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) is gaining significance in recent years as a process for additive manufacturing that produces large and complex components with high deposition rates at economically feasible rates. Nickel-based alloys, praised for their unique features, like mechanical strength, corrosion resistance, and thermal stability, find widespread application in the aerospace, marine, and energy sectors. However, achieving the desired surface finish, dimensional precision, and mechanical performance of WAAM nickel alloy structures is a continuing challenge because of the complex interactions occurring between the process parameters. The study presents an experimental analysis conducted to establish the effect of important process parameters of WAAM-wire feed rate, travel speed, welding current, interpass temperature-on the quality indicators such as surface roughness, dimensional accuracy, and hardness. For the purpose of prediction and process control, the Adaptive Neuro
Natarajan, Manikandan
Modelling and Analysis of Complex Shaped Cracks2026-28-0048To be published on 02/12/2026
This study offers a thorough analysis using finite element methods (FEA) to examine how fatigue cracks grow in three different materials: Structural steel , Titanium alloy (Ti Grade 2), and epoxy/aramid-based printed circuit board (PCB) laminates. Using ANSYS Workbench, we ran simulations under both static and repeated loading to understand how these materials fracture. The approach was based on Linear Elastic Fracture Mechanics (LEFM), employing the Maximum Circumferential Stress Criterion to predict where cracks might start and how they could spread. Also, the Equivalent Domain Integral (EDI) method helped us calculate the Stress Intensity Factors (SIFs) when cracks are under mixed loading modes. We modeled the growth of fatigue cracks using the Paris Law, relying on material-specific constants (C and m) drawn from previous studies and experimental tests. For example, titanium Grade 2 showed Paris Law constants with C values between 1.8 × 10⁻¹⁰ and 7.9 × 10⁻¹² m/cycle, and m values
T, LokeshBhaskara Rao, Lokavarapu
Galvanic Corrosion Susceptibility Analysis and Mitigation strategies in Automotive Battery Packs2026-28-0018To be published on 02/12/2026
As electric vehicles continue to revolutionize transportation, ensuring the reliability of their powertrain systems and battery packs has become a critical focus. One key challenge is galvanic corrosion, which occurs when dissimilar metals in contact are exposed to an electrolyte, such as seashore moisture or road salt used in snow or ice zones. This corrosion can weaken structural components, compromise electrical conductivity, and reduce the lifespan of critical systems. Common areas at risk include metallic joints within battery enclosures, busbars, cooling systems, and electrical connectors. Environmental factors such as high humidity and temperature fluctuations further amplify the issue, making it a pressing concern for manufacturers. This paper aims to systematically identify critical galvanic joints within electric powertrain systems and battery packs and provide effective strategies to mitigate corrosion risks. Preventative measures include choosing compatible materials with
NARAIN, ADITYAVenugopal, SivakumarGopalan, VijaysankarVaratharajan, Senthilkumaran
Genetic algorithm based optimization of Chaboche kinematic hardening parameters along with the validation of FE model through characterized crack initiation2026-28-0086To be published on 02/12/2026
In the context of electro-mobility for commercial vehicles, the failure analysis of a low voltage (LV) connector panel in a DCDC converter is crucial, particularly regarding crack initiation at the interface of busbar and plastic component. This analysis requires a thorough understanding of thermo-mechanical behavior under thermal cyclic loads, necessitating kinematic hardening material modeling to account for the Bauschinger effect. As low cycle fatigue (LCF) test data is not available for thermo-plastic composite material Ultramid A3U44G6, we have adopted a novel approach of determining non-linear Chaboche Kinematic Hardening (CKH) model parameters from monotonic uniaxial temperature dependent tensile test data of Ultramid A3U44G6. In this proposed work a detailed discussion has been presented on manual calibration and Genetic Algorithm (GA) based optimization of Chaboche parameters. Due to lack of fiber orientation dependent test data for Ultramid A3U44G6, here von Mises yield
Basu, ParichaySrinivasappa, Naveen
Simultaneous scheduling of machines, tool transporter and tools in a multi machine FMS with alternative routing using crow search algorithm in Automotive Manufacturing2026-28-0089To be published on 02/12/2026
In modern automobile manufacturing systems, achieving high efficiency in production scheduling is crucial for cost reduction and delivery optimization. This paper addresses the integrated scheduling problem of machines, Tool Transporters (TT), and tools with consideration of alternate machines in a multi-machine Flexible Manufacturing System (FMS) considering tool transfer times to minimize makespan, specifically within an automobile production context. Due to economic constraints, only a single copy of each tool type is maintained, stored centrally in a shared Central Tool Magazine (CTM), which serves multiple CNC machining centers involved in automobile component manufacturing. The problem is to select machines and assignment of tools to job-operations, job-operations’ sequencing on machines, corresponding trip operations including the dead heading trip and loaded trip times of tool transporter for makespan minimization. This paper introduces a nonlinear Mixed Integer Programming
Mareddy, Padma LalithaNatarajan, ManikandanKatta, Lakshmi NarasimhamuSiva Rami Reddy, Narapureddy
Methodology for Shower Water Management in Electric Car Applications2026-28-0068To be published on 02/12/2026
All automotive vehicles with enclosed compartments must pass the Shower test standard - IS 11865 (2006). One of the most severe and critical areas of water leakage is “Water entry into HVAC opening”. Excess water flow in high-pressure conditions and seepage during long-time low-pressure conditions could potentially have a significant impact on water entry inside the HVAC suction cutout and subsequently into the cabin. The study clearly indicates that for making leak proof HVAC opening (suction interface), it is crucial for the structure of BIW Plenum, Trim Applique and its sealing components to be robust enough to effectively collect and divert the water during shower test condition. This robustness is necessary to ensure leakage prevention thru HVAC cutout in varying rain scenarios during customer usage of the vehicle. A systematic approach is followed for assessing leak tightness of the HVAC area. 1. CFD simulation performed to verify the flow path of water during shower test. It is
Gunasekaran, MohanrajNAMANI, PrasadRamaraj, RajasekarJunankar, AshishRaju, Kumar
Common Mode Voltage Reduction in Quasi-Z Source Inverter for Electric Vehicle Applications Using MBPWM Technique2026-28-0102To be published on 02/12/2026
Unlike traditional voltage source or current source inverters, ZSI/qZSI can boost and invert DC power in a single stage, making them attractive for applications like EVs where battery voltage may vary. Common mode Voltage (CMV) is the voltage between the neutral point of the motor and ground. High CMV in motor drive systems can cause: Higher leakage currents, Electromagnetic interference (EMI), Insulation stress, bearing currents, leading to premature motor failure. Reducing CMV is essential for reliable and safe EV operation. Pulse-width modulation (PWM) is used to control the QZSI output voltage. The QZSI offers several advantages over traditional inverters, including improved efficiency, reduced cost, and increased reliability. The proposed system is designed to reduce the CMV through a combination of passive LC filtering and shoot-through (ST) modulation techniques. The LC filter is designed to attenuate high-frequency components of the CMV while the ST modulation is used to
N, KalaiarasiR, RajarajeswariD, Anitha
Tractor Cabin Structure Borne Noise Reduction in the Virtual Environment2026-26-0101To be published on 01/16/2026
In recent days, cabin variants in the tractor are preferred by the farmers for the Coziness and longer field hour operation with less fatigue. Noise perceived by customer is the most important factor taken into account during the design stage, as it’s directly linked with operator’s comfort. Observed noise levels has to be within the defined limits as per national/international standards Overall cabin noise levels is contributed by the structure borne noise below 630 Hz. Structure borne noise is the noise typically radiated by the door, roof, windshield, floor, fender and structure assembly due to the engine excitation through the transmission housings and backstories. This paper depicts the process of tractor cabin structure borne noise prediction in the virtual environment. Firstly, Engine bearing loads and axle bearings has been extracted in the virtual stage from the vehicle level driveline model using commercially available MBD software. The finite element (FE) model of the cabin
Qunasekaran, PandiyanayagamK, SomasundaramChavan, Amit
Comprehensive Evaluation of Bolster Behavior: Field Data Insights for Design Modifications2026-26-0497To be published on 01/16/2026
Bogie suspension systems are increasingly being used in tipper vehicles to enhance their performance and durability, especially in demanding environments like construction and mining areas. Bolsters play a very crucial role in the bogie suspension systems of tipper vehicles, contributing significantly to their overall performance and durability. Bolsters help in evenly distributing the load across the suspension system, reducing stress on individual components and enhancing the vehicle’s stability. They act as shock absorbers, mitigating the impact of rough terrains and heavy loads, which is essential for maintaining the structural integrity of the vehicle. By dampening vibrations, bolsters improve ride comfort and reduce wear and tear on the vehicle’s components, leading to longer service life. Bolsters assist in maintaining proper alignment of the suspension system, ensuring optimal performance and safety. This study focuses on the comprehensive testing and evaluation of bolsters to
V Dhage, YogeshKolage, Vikas
Material-Optimization in Rib-Stiffened Polymer structures: A Computational & Analytical Study2026-26-0498To be published on 01/16/2026
Background The demand for lightweight yet rigid polymer components continue to drive innovation in structural design, particularly for applications requiring optimal stiffness-to-weight ratios. This study examines an alternative rib-stiffening approach for polypropylene plates, where conventional single-rib geometries are reconsidered in favor of parallel micro-rib configurations. While single ribs have been extensively studied, the potential benefits of distributed rib architecture remain less explored, particularly regarding their combined bending and shear performance. Key objective: This study systematically evaluates how parallel rib configurations influence mechanical performance in polypropylene plates, with specific focus on:  Bending stiffness preservation through optimized moment of inertia distribution  Shear resistance enhancement via controlled rib spacing  Coupled effect of the bending and shear resistance Prior art and their limitations: Current literature primarily
Sreejith, M PJain, DeepakRavi, AbhikrishnaMaheshwari, PankajKumar, Mandeep
Investigating Thermal Fatigue Cracks in Exhaust Manifolds of Longitudinally Mounted 1.2L 4-Cylinder Engines2026-26-0488To be published on 01/16/2026
This study addresses the challenge of ensuring the durability of closed couple exhaust manifolds in the compact engine bays of modern vehicles, focusing on a longitudinally mounted 1.2L 4-cylinder engine. The original sheet metal Exhaust manifold design failed thermal fatigue bench durability test, requiring a complete redesign to improve strength without changing materials. Initial simulation predictions significantly deviated from physical test results, with repeated cracks observed during accelerated thermal fatigue bench testing, despite simulations predicting a higher number of cycles before failure. This difference highlighted the need for a deeper understanding of the manifold's failure modes, primarily thermal fatigue, and mechanical vibration during engine transients. The design of experiment (DOE) approach was used to find the effect of different parameters e.g., gas temperature, surface temperature, air flow, thermal gradient, on the durability result & also to understand
Krishnan, K.S.GopalaMishra, AshutoshYadav, Sanjay KumarKumar, DeepakTripathi, ManasKumar, Prabhakar
Digital Twin for Motor & MCU incorporating Deep learning AI-ML algorithms for intelligent prognostics for Electric vehicles2026-26-0479To be published on 01/16/2026
As electric vehicles (EVs) become more advanced, so ensuring the reliability of critical components like the motor and Motor Control Unit (MCU) is essential. This paper presents a digital twin model designed to predict failures in motor and MCU components using machine learning. The approach focuses on detecting early signs of failure through real-world data and advanced analytics. We collected thermal and performance data from field vehicles, capturing both normal (healthy) and abnormal (faulty) operating conditions. Using this dataset, we developed and trained an Auto Encoder-based machine learning model that learns what “normal” looks like and flags deviations as potential issues. One key outcome of this study is the successful early prediction of Insulated Gate Bipolar Transistor (IGBT) degradation, where the system identified subtle behavioral changes long before any visible failure symptoms appeared. This digital twin acts as a virtual replica of the physical components
Joshi, PawanPandey, SuchitKONDHARE, ManishUpadhyay, AbhayJaganMoahanarao, VanaTank, Prabhu
NN FMU: Deep Learning Models for Next-Gen xiL Vehicle Simulation2026-26-0452To be published on 01/16/2026
Functional Mock-up Units (FMUs) have become a standard for enabling co-simulation and model exchange in vehicle system development. However, traditional FMUs derived from physics-based models can be computationally intensive, especially in scenarios requiring real-time performance. This paper presents a Python-based approach for developing a Neural Network (NN) based FMU using deep learning techniques, aimed at accelerating vehicle simulation while ensuring high fidelity. The neural network was trained on vehicle simulation data and developed using Python frameworks such as TensorFlow. The trained model was then exported into FMU, enabling seamless integration with FMI-compliant platforms. The NN FMU replicates thermal behavior of vehicle with high accuracy while offering a significant reduction in computational load. Benchmark comparisons with Physical Thermal Model demonstrate that the proposed solution provides both efficiency and reliability across various driving conditions
Srinivasan, RangarajanAshok Bharde, PoojaMhetras, MayurChehire, Marc
Master Complexity of Version Management in SDM by AI-Driven Assistance2026-26-0439To be published on 01/16/2026
Simulation-driven product development involves numerous CAE model iterations, where each version represents a critical difference. Usually, these multiple model versions are generated by hundreds of simulation engineers working in teams distributed across the globe, making functional collaboration a key for effective product development. To manage vast amounts of CAE data generated by engineers working simultaneously on a project, it is imperative to have a robust version management system to track changes in the CAE data. A robust version management is the backbone of an effective simulation data management (SDM) system. It involves capturing and documenting model changes at every design iteration. An accurate documentation of the model changes is crucial as it helps in understanding the model evolution and collaboration among engineers. However, documenting is usually considered a boring and tedious task by many engineers. This often leads to bad change documentation, which in turn
Thiele, MarkoSharma, Harsh
Multi-Material Front Structures: A Pathway to Safer and More Sustainable Vehicle Design2026-26-0456To be published on 01/16/2026
Frontal crash structures play a vital role in occupant safety, but traditional designs often involve a trade-off between structural strength and weight efficiency. In the pursuit of safer and more sustainable mobility, this study explores a physics-based methodology that leverages the principle of dynamic equilibrium to guide the integration of dissimilar materials in front-end vehicle structures. Specifically, we examine a novel configuration wherein aluminum High pressure die cast (HPDC) is introduced in swan neck region of the front longitudinal member, while retaining steel in the frontal crush zone. This arrangement aims to redistribute crash loads and control deformation mechanisms, enabling improved energy absorption without compromising structural integrity. To evaluate the proposed strategy, a series of detailed finite element simulations were conducted using LS-DYNA, a widely adopted tool for vehicle crash analysis. The results reveal that the dynamic equilibrium approach
Revanth, GoshikaBhagat, MilindJoshi, VikasMankhair, AbhijitSudarshan, B.SudarshanKollipara, Jahanavi
Dimensional Management in Automotive Vehicle Design & Development for Perceived Quality Improvement in Buses2026-26-0447To be published on 01/16/2026
Perceived quality (PQ) is one of the most important factors in engineering signoff as well as customer delight and product improvement (feel, look & touch). The PQ is something related to feel of the product in terms of gap, flushness, fitment and appearance as per the costumer perceptions and expectations. Validate both design and engineering with the perceived quality review. In today's automotive bus industry this is equally applicable. In this paper we have explored the dimensional management scope in improving the PQ requirements and expectations by utilising the dimensional variation analysis (DVA) approach. We have explored & explained the fundamentals of vehicle aggregates fitment process and impact of fitment tolerances as used in DVA model to resolve vehicle packaging issues (critical gaps & clearance variation as per expected no. of vehicles to be manufactured in future at initial stage of the vehicle design). It is further extended into system level DFMEA to include DVA in
Singh, Vinay KumarDewangan, Ved PrakashKumar, RahulDeep, Amar
Transforming Manufacturing: Increasing Throughput and Reducing production Complexity with Digital Twins2026-26-0449To be published on 01/16/2026
In traditional manufacturing, increasing production line capacity often involves physical trials, leading to downtime, high costs, and operational risks. This paper presents a bidirectional digital twin developed for the Fischertechnik Smart Factory Kit, enabling real-time simulation and validation of production line modifications before actual deployment. The digital twin integrates with a Siemens PLC to mirror real-world operations, capturing live production data and visualizing key parameters like cycle time and machine utilization in a 3D environment. Engineers can test various optimization scenarios adjusting conveyor speeds, optimizing robot paths, and modifying buffer sizes to enhance efficiency. The best-performing configurations are identified based on throughput, cycle time, and resource utilization, and validated changes are automatically deployed to the PLC, ensuring seamless implementation. Beyond capacity optimization, this solution improves overall production efficiency
Kumar, RahulSingh, Randhir
Multi-Model Analysis of O-Ring Compression and Relaxation Force Predictions Using Machine Learning and CAE Simulations2026-26-0466To be published on 01/16/2026
O-rings play a critical role in ensuring leak-proof seals in a wide range of engineering systems. Accurate prediction of their compression and relaxation behavior under various material and geometric configurations is essential for optimal design and reliability. This study presents an analysis of machine learning techniques to predict two key performance outputs, compression force and relaxation force (after 10 minutes) trained on computer-aided engineering (CAE) simulation data. The experimental setup was represented in CAE simulation and the results were compared with experimental data conducted at ZF test facilities. Simulation results correlated well with the experimental data (deviation was less than the 5%). To create a dataset for training machine learning (ML) models, realistic ranges for the input parameters such as hardness and geometrical parameters were determined, and simulation data were generated using design of experiments (DOE). Multiple ML models were developed and
Kosgi, DurgaprasadAlva, P PanchamDangeti, VenkataKrishna Pavan
Automated Parameterization of CAE Model Based on Test Data Response Bands2026-26-0436To be published on 01/16/2026
This study presents a data-driven approach aimed at enhancing the correlation between physical test data and Computer-Aided Engineering (CAE) simulations, with an emphasis on adapting the standard CAE model's response to minimize any gaps relative to the response of a given test specimen. Leveraging historical test data, machine learning techniques are used to categorize responses into distinct bands, effectively capturing the inherent variability observed in real-world scenarios. This categorization step recognizes patterns across a wide range of test data, forming the foundation for closely matching and adapting CAE models to new, unseen hardware data. In typical automotive simulation workflows, tuning a standard CAE model to match new hardware test data involves iterative parameter adjustments and simulations. This process can be time-consuming and often lacks predictive insight into the necessary modifications. The approach developed in this study addresses this challenge by
Khopekar, MariaArya, BibhuSridhar, RaamMohan, PradeepKurkuri, Mahendra
Thermo-Mechanical Fatigue Assessment of Cylinder Heads Using Advanced Simulation Techniques2026-26-0465To be published on 01/16/2026
Thermo-mechanical fatigue (TMF) is a critical durability concern for cylinder heads in internal combustion engines, particularly under severe cyclic thermal and mechanical loads. TMF-induced damage often initiates in geometrically constrained regions with high thermal gradients and can significantly reduce component life. As performance demands increase, understanding and mitigating TMF becomes essential to ensure the structural integrity and long-term reliability of engine components. This study presents a simulation methodology for evaluating thermo-mechanical fatigue (TMF), a temperature-dependent low-cycle fatigue (LCF) mechanism that arises from repeated thermal expansion and contraction under mechanical constraints, leading to cyclic plastic deformation and damage. The methodology consists of two key phases. Phase I involves global finite element (FE) simulations—both thermal and structural—to obtain temperature and displacement fields under rated and idle engine conditions
Ghotekar, SunilKumbhar, Dipak MadhukarPendse, Ameya
Comprehensive Durability Assessment of Planet Carrier in Heavy-Duty Tipper Gearboxes Using RLDA Torque Data2026-26-0443To be published on 01/16/2026
In heavy-duty tippers, where challenging conditions demand high torque, planet carriers play a crucial role by enabling efficient load distribution and torque transmission while supporting gear ratio and speed variation in space-constrained systems such as automatic transmissions, hybrid drivetrains, and electric vehicles. This paper focuses on the comprehensive durability performance assessment of planet carriers using duty cycles derived from RLDA measurements for a heavy-duty tipper gearbox development program. The existing Design Validation Plan (DVP) for the planet carrier considers first gear utilization of 10-15% at 40% vehicle overload, in line with historical data. However, recent trends in mining applications revealed vehicle overloads of 55-65%, leading to an increase in first gear utilization (25-35%). This shift presents challenges for OEMs to enhance design durability while incorporating additional safety margins to meet the demands of a competitive, cost-driven market
Bagane, ShivrajPendse, Ameya
Fatigue Life Prediction Methodology for Vehicle Suspension System and correlation with Physical Test2026-26-0459To be published on 01/16/2026
Fatigue Analysis is a safety critical area in design engineering for load bearing members. The design of a durable suspension system forms the foundation of vehicle architecture. The challenge lies in accurately predicting fatigue in critical areas to reduce field failures, primarily due to the absence of a validated methodology for fatigue calculation. This study provides an overview of fatigue assessment for Knuckle assembly/Rear Twist Beam based on digital Road Load/test Data for Finite Element Analysis (FEA) process for design development. This study makes use of Computer Aided Engineering (CAE) solvers such as Optistruct for model setup and fatigue tool such as nCode/FEMFAT for Fatigue Analysis. The methodology used for Fatigue estimation of rear suspension components such as Rear Twist Beam and Knuckle assembly is based on Digital Road Load Data/duty cycle loads applied to the suspension components at the hard point location at assembly level. The fatigue process used for
Kokare, SanjayNagapurkar, TejasIqbal, Shoaib
Automated evaluation of drive file simulation accuracy2026-26-0528To be published on 01/16/2026
In the area of structural durability testing using servo-hydraulic actuators, developing drive files for the actuators is a major step. Testing outcomes depend on ensuring the simulation accuracy of each drive file. These drive files are developed in an iterative process for different test track surfaces at different road and load combinations till the time we achieve better correlation. Evaluation of simulation accuracy of the drive files is an extensive manual review process, making it time-consuming and resource-intensive. To address this challenge, an application has been developed to automate the comparison of actuator signals with predefined target signal files. This tool enables quick and accurate analysis of each drive file in a test run, facilitating a comprehensive review of signal deviations. Each test run has thousands of drive files based on road-load mix and actuator settings. This application helped us significantly optimize the simulation workflow by reducing the manual
Soni, YashKatake, VrishaliMullapudi, DattatreyuduChaskar, Mithun
Determination of Acrylonitrile Content in Nitrile Butadiene Rubber Vulcanizates by Py-GCMS Techniques2026-26-0546To be published on 01/16/2026
Nitrile Butadiene Rubber (NBR), a copolymer of butadiene and acrylonitrile is known for its superior resistance to hydrocarbon oil, low gas permeability and excellent thermal stability. It is extensively used in seals, O-rings, conveyor belts and pneumatic tires. It is worth mentioning that these performance attributes are predominantly influenced by acrylonitrile content. While solid-state 13C Nuclear Magnetic Resonance (NMR) is an established technique for structural characterization of rubber vulcanizates, its high cost and accessibility limits its application in routine industrial analysis. This study aims to develop Pyrolysis-Gas Chromatography/Mass Spectrometry (Py-GCMS) as a robust, precise, cost-effective alternative to determine acrylonitrile content in NBR vulcanizates. This research demonstrates and establish a method to determine the acrylonitrile (ACN) content in finished rubber vulcanizates through pyrolysis gas chromatography-mass spectrometry (Py-GCMS). This method
Samanta, RajyasreeGhosh, DebojitAnjana, KanhaiyaSen, AmitGuria, BiswanathChanda, JagannathSamui, BarunGhosh, PrasenjitMukhopadhyay, Rabindra
Wheel side load calculation using the strain measurement on swingarm and duty cycle development2026-26-0583To be published on 01/16/2026
Typically duty cycle development for any component carried out in the absence of direct acting load will be based on the measured strain from the Road Load data Acquisition(RLDA) and comparing it with the rig level testing. The biggest drawback from such an approach is the fact that the selected loads can be drastically different from the actual experienced peak load from the actual RLDA. This happens because the strain gauges will have sensitivity toward all three directional loads and sometimes due to complex structure design uni-directional sensitive locations are difficult to find out or strain gauge. This will lead to over predicting the loads in some cases and the selected load may end up yielding the component in a single cycle itself. This paper discusses the method employed to calculate the loads at the input load location using the strain gauges which are cross sensitive and using that input loads to select the loads for the testing of the component. Also it talks about the
Anandh, SudheepPrasad, SathishR S, Mahenthran
Electro Magnetic Radiation Analysis for the Vehicle Cable and Shielding Techniques and Performance Assessment2026-26-0563To be published on 01/16/2026
This paper addresses the challenges and methodologies for evaluating radiated emissions from automotive electronic systems, which is critical for achieving electromagnetic interference and compatibility (EMI/EMC) standards. The rapid integration of advanced electronic components in modern vehicles has transformed automotive systems, their potential to generate electromagnetic interference (EMI) becomes a significant concern, particularly due to its impact on vital communication and safety systems. The study mainly investigates radiated EMI, which is the unintentional emission of electromagnetic energy emitted by HV cables in the wiring harness layout, potentially disrupting the operation of nearby systems. This study utilized CST Studio Suite to analyse the electromagnetic behaviour of vertically and horizontally polarized antenna configuration in electric vehicles. The simulated results are benchmarked against international EMI/EMC standards such as CISPR-12 and CISPR-25, which
Manuelraj, MasilamaniPrasad, SuryanarayanaNarayanan, Siva Suriya
Enhanced Integrated Cooling-Protection Plate for Battery pack Underbody Impact Resistance in Electric Vehicles2026-26-0169To be published on 01/16/2026
In the quest for enhancing electric vehicle performance and safety, this paper presents a comprehensive investigation into the design and performance of high-voltage (HV) battery cooling plates featuring dedicated cooling channels, integrated with structural bottom protection members positioned at the bottom. The study aims to address the dual challenges of effective thermal management and enhanced crash protection in electric vehicles. Through a combination of Design iterations, Thermal performance evaluation and Crash simulations, the research evaluates the cooling efficiency and structural resilience of the proposed design. Findings reveal that the integrated cooling plates not only maintain optimal battery temperatures under various operating conditions but also significantly improve the vehicle's crashworthiness. The paper concludes with the results of numerical simulations, rigorously validated against the robust design requirement globally accepted for series components to
Dusad, SagarKummuru, SrikanthJoshi, Amarja
A strategic approach to the selection of switchgear and busbars for EV battery packs2026-26-0165To be published on 01/16/2026
With the rising adoption of electric vehicles (EVs), the need for robust and efficient power distribution systems has become increasingly important. This paper outlines a strategic method for selecting switchgear and busbars in EV battery packs, emphasizing key factors such as safety, energy efficiency, thermal control, and future scalability. Proper optimization of these components can significantly improve performance, minimize power losses, and ensure durability under demanding operating conditions. The design and selection of battery conducting components, such as switchgears and busbars, are typically based on the maximum continuous and peak current capabilities of the EV battery pack. While this approach ensures that the components can withstand extreme conditions, it often leads to over-engineering, resulting in unnecessary costs and added weight. However, this method overlooks the dynamic power demands of the vehicle, which fluctuate based on driving conditions and usage. Real
Soman, Anusatheesh, GouthamK, Mathankumar
A Novel Analytical Approach to Predict Vehicle Parking Brake Cable Performance and Optimize Cable Routing2026-26-0483To be published on 01/16/2026
The performance of vehicle parking brake cables are critical for ensuring vehicle safety and functionality. Vehicle manufacturer evaluate the robustness of cable performance at different road gradient conditions. Effort and stroke performance are among the key parameters for evaluating cable performance. While parking brake system should be designed to minimize effort losses through the cable routing, packaging constraints often prevent it. Therefore, it is essential to estimate the losses through cable routing and optimize parameters of the parking brake cable system. Currently, the methods used for evaluating cable performance are either experimental or empirical based. CAE methods using finite element analysis (FEA) and multibody dynamic approaches are computationally expensive and not yet fully established due to modelling and solving complexity of dynamic cable which involves continuously changing and updating contacts. The available analytical approaches incorporates cable system
Iqbal, ShoaibSabri, SalahSiddiqui, Arshad
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