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Virtual recording generation using Generative AI and Carla Simulator

2024-28-0261To be published on 12/05/2024

A Field Operation Test (FOT) and Use case scenario recording capture is very expensive due to the amount of necessary material (vehicles, measurement equipment, headcount, data storage capacity/complexity, trained drivers/professionals) and all-time robust working vehicle setup is not available, mileage is directly proportional to time, along with that it cannot be scaled up due to physical limitations. During the early development phase, ground truth data is not available, and data that can be reused from other projects may not match 100% with current project requirements. All event scenarios/weather conditions cannot be ensured during recording capture. Carla is an autonomous open-source driving simulator, used for the development, training, and validation of autonomous driving systems, by integrating generative AI, particularly Generative Adversarial Networks (GANs) and Retrieval Augmented Generation (RAG) which are deep learning models, the process of creating synthetic data, and

Sehgal, Vishal, Sekaran, Nikhil

Evaluation of joining performance of different coated steel sheets used in automotive applications

2024-28-0163To be published on 12/05/2024

To meet corrosion target of automotive vehicles, different coated steel sheets are used in various parts of body in white, chassis and powertrain. Hot dip galvanized (GI) and hot hip galvannealed(GA) are the two most commonly used steel sheets across world. Other coatings such as Zn-Ni, Al-Si , Zn plating and electro galvanized zing coating are application specific coating, which are used suitably to meet different performance requirement. To meet robust corrosion and performance requirement, there is trend of increase in coated steel sheet use in automotive vehicle. While different coated steels are having different corrosion performance, they also exhibit different joining and paint adhesion performance. Spot welding is the most common technique used for joining automotive parts. Joint strength majorly depends on steel base material grade, chemistry and properties. However, coating on base material also influence joining performance. Major challenge is faced when different coated

Jain, Vikas, Misal, Swapnali, Deshmukh, Mansi, Paliwal, Lokesh

Relevance of Autonomous Vehicles in the Indian Context

2024-28-0122To be published on 12/05/2024

Autonomous vehicles (AVs) are positioned to revolutionize transportation by eliminating human intervention through the use of advanced sensors and algorithms, offering improved safety, efficiency, and convenience. In India, where rapid urbanization and traffic congestion present unique challenges, AVs still hold significant promise. This technical paper discusses the relevance of autonomous vehicles in the Indian context and the challenges that need to be addressed before the widespread adoption of autonomous vehicles in India. These challenges include the lack of infrastructure, concerns regarding road safety, software vulnerabilities, adaptability to change towards autonomous vehicles, and the management of traffic. The paper also highlights the government's initiatives to encourage the development and adoption of autonomous vehicles, the ideology behind the legal framework, and the required changes in terms of technological advancements and urban planning. In a brief manner, this

Mishra, Adarsh, Mathur, Gaurav

CAE simulation based structural assessment of steering wheel

2024-28-0200To be published on 12/05/2024

The structural integrity of the steering wheel is important for vehicle operations. It is subjected to various load conditions during the vehicle motion and thus becomes important to understand various aspects of the same which includes stiffness, natural frequency, regulatory requirements i.e body block test, head form impact test. Simulation plays an important role in structural integrity and design validation requirement at design stage itself. This paper discusses modelling and simulation of steering wheel at both armature level and at complete steering wheel level. As armature is critical from structural strength and stiffness point of view, certain simulations like modal analysis are performed first at armature level and design iterations were done to achieve the natural frequency target. List of simulations performed includes modal analysis, bending rigidity, static compression, bending stiffness, body block test and head form test as per AIS -096 etc. Simulation results which

Rathore, Gopal Singh, Kumar, Ankit, Chauhan, Adesh Kumar, Das, Dr. A.P., Sahu, Hemanta Kumar

Investigation on Thermal Performance of Battery Cooling Plate for Lithium-ion Battery

2024-28-0259To be published on 12/05/2024

Electric Vehicles are regarded to be the most effective way to lower emissions of greenhouse gases from transportation industry. Lithium-ion batteries are rechargeable and ideally suited for vehicle electrification due to their high specific energy and energy density in comparison to others. Electric Vehicle performance greatly depends on efficient operation of Li-ion Battery. Battery thermal management plays a crucial role in ensuring the optimum vehicle operation. Heat dissipation from the battery should be dealt with, for safe operation and to prolong the battery life cycle. To achieve the battery’s optimal temperature, an efficient cooling system should be established. Battery cooling plate is an essential component which is necessary for heat transfer from battery pack to coolant. Four different battery cooling plates such as dimple, U shaped, Splitter, Serpentine with varying profiles are modeled for computational fluid dynamics simulation. Models are compared based on pressure

K, Muthukrishnan, S, Saikrishna, K, Keshavbalaje

Vehicle underbody small parts detection using Computer vision

2024-28-0190To be published on 12/05/2024

Manual installation of vehicle underbody small parts is tedious task which sometimes results in incomplete & inaccurate installation. Based on process quality guidelines, this comes under potential defect category at End of line inspection area for which few hours of manual efforts are required for identifying location of error & doing rework activity. Existing deep learning & image comparison method falls short in identifying error location. To overcome this challenge, deep learning algorithm with co-ordinate system developed which comprises of identifying plurality of entities present in test and reference image and indexing it as a small part & a hole. This further comprises of determining 2D position in terms of X and Y co-ordinate of each indexed hole & small parts between reference & test image. By seamless integration of deep learning-based part detection with coordinate constraints logic, our system enables real-time identification of incorrectly assembled parts or the absence

Dhumal, Abhishek Trimbak, Mishra, Jagdish, Tote, Anuj, Nurukurthi, Lakshmi, Kumar, Prakash

An Experimental Study of White Deposit formation on IG coil in SI Engine

2024-28-0206To be published on 12/05/2024

This paper primarily focuses on the ignition coil (IG) by enclosing factors like vibration of surrounding components, temperature etc. IG coils are the components which convert low battery voltage into high voltage required to generate the flashover between the electrodes on the spark plug so that combustion cycle can be started. Considering the importance of IG coils in engine operation which has a direct impact on the engine performance. Any failure in the IG coils is judged as a critical failure and encompasses severe repercussions. This paper intends to capture one such issue of White deposition on IG coils. White deposit was observed in IG Coils during new model development in bench level durability test. Failure investigation was carried out using various techniques such as vibration analysis, thermal analysis, white deposit chemical analysis etc. for identifying the root cause. Possible countermeasures were identified, and the issue was resolved by hardware design optimization

PATEL, HARDIK MANUBHAI, Gupta, Vineet, Chand, Subhash, KUMAR, NITISH

Smart Testing Methodology For Air Suspension System Of Buses

2024-28-0201To be published on 12/05/2024

In the fast growing automotive sector, reliability & durability are two terms of utmost importance along with weight and cost optimization. Therefore it is important to explore new technology which has less weight, low manufacturing cost and better strength. It also seek for a quick, cost effective and reliable methodology for its design validation so that any modification can be made by identifying the failures. This paper presents the rig level real world usage pattern simulation methodology to validate and correlate the vehicle level targets for micro strain, wheel forces and displacement on suspension components like optimized Z spring, torque rods, pan hard rod & mounting brackets of newly developed light weight two bellow air suspension for buses. The newly developed suspension consist of two air bellows instead of four air bellows along with unique Z spring which replaces conventional parabolic leaf spring and specially designed to take forces in vertical as well as longitudinal

Tangade, Atul Bandu, Babar, Sunil, Bankar, Milind Achyutrao, Mehendale, Ravindra, Dhumal, Kailas, Bhusari, Deepak, Sonawane, Ravindra, Shinde, Saurabh

Correlation Study for Radial Lash in Sliding Bushings of a Steering System

2024-28-0249To be published on 12/05/2024

Investigation of clunking noise in a steering system fitted into a test vehicle indicated radial lash in sliding bushings, which are press fitted into housings, as one of the possible causes for clunk. To study the behavior of sliding bush under the influence of assembly clamp loads, manufacturing tolerances and road loads, sliding bushes are modelled in more detail in the steering system finite element models. Further for correlating the bushing measurements from test vehicle to the finite element model, a radial lash output is derived which is not directly available in finite element software. Finally, the correlated model is used to assess the updated design and check for radial lash improvement

Badduri, Jaideep, Pandey, Ashish

Impact Of Time Aligned Measurement Parameters On Brake Specific Emissions

2024-28-0132To be published on 12/05/2024

As per global emissions legislation requirements running test cycles and reporting brake specific emissions is the key requirement. Engine gaseous emissions measurement is mandatory requirement for ON Highway and OFF Highway applications for transient duty cycles during testing at test cells. To meet the stringent emission limits is one of the challenging tasks considering the nature of transient duty cycles with accurate measurement of lower emission values. Similarly calculating accurate results is critical since there are several factors which impacts the accuracy of calculated results. As per regulatory test methods, there is guidance on measuring the time lag through an experiment method and accounting the same during the results calculation, however during dynamic conditions, the time lags will vary and influence the calculated results. This paper focuses on understanding critical parameters which leads to variations in dynamic condition of time lag of measured emissions

Patil, Rahul Chandrakant, Rajoapdhye, Sunil, Mudassir, Mohammed, Mokhadkar, Rahul, Phadke, Abhijit Narahari, Bharambe, Niraj, DHURI, SANTOSH

Application of TOPSIS approach for Optimization on Additive Manufacturing (Fusion Deposition Modeling) of TPU Material: A Systematic Approach for Process Enhancement

2024-28-0232To be published on 12/05/2024

Additive Manufacturing (AM), specifically Fusion Deposition Modeling (FDM), has transformed the manufacturing industry by allowing the creation of complex structures using a wide range of materials. The objective of this study is to enhance the FDM process for Thermoplastic Polyurethane (TPU) material by utilizing the Technique for Order of Preference by Similarity to Ideal Solution (TOPSIS) optimization method. The study examines the influence of FDM parameters, such as layer height, nozzle temperature, and infill density, on important characteristics of the printing process, such as tensile strength, flexibility, and surface finish. The collection of experimental data is achieved by conducting systematic FDM printing trials that cover a variety of parameter combinations. The TOPSIS optimization method is utilized to determine the optimal parameter settings by evaluating each parameter combination against the ideal and anti-ideal solutions. This method determines the optimal parameter

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

Optimization and Regression Modeling of Wire Electrical Discharge Machining for Cupronickel Material

2024-28-0244To be published on 12/05/2024

Wire Electrical Discharge Machining (WEDM) is a highly accurate machining method that is well-known for its capacity to create complex forms in conductive materials with exceptional precision. Cupronickel, a hard material consisting of copper, nickel, and additional components, is widely employed in marine, automotive, and electrical engineering fields because of its exceptional ability to resist corrosion and conduct heat. The objective of this study is to optimize the parameters of Wire Electrical Discharge Machining (WEDM) for Cupronickel material and create regression models to accurately forecast the performance of the machining process. An investigation was carried out to examine the impact of important parameters in wire electrical discharge machining (WEDM), namely pulse-on time, pulse-off time, applied current on key performance indicators such as material removal rate (MRR), surface roughness (Ra). The methodology of design of experiments (DOE) enabled a systematic

Natarajan, Manikandan, D, PALANISAMY, Pasupuleti, Thejasree, A, GNANARATHINAM, Umapathi, D, Silambarasan, R

Optimization and ANFIS Predictive Modeling of Wire Electrical Discharge Machining for Invar 36 Material

2024-28-0243To be published on 12/05/2024

Wire Electrical Discharge Machining (WEDM) is a highly accurate machining technique that is well-known for its capability to create intricate forms in materials with high levels of hardness and intricate geometries. Invar 36, a nickel-iron alloy, is extensively utilized in industries that demand exceptional dimensional stability across a wide temperature range. The objective of this study is to optimize the parameters of Wire Electrical Discharge Machining (WEDM) for Invar 36 material. Additionally, a predictive model called Adaptive Neuro-Fuzzy Inference System (ANFIS) will be developed to forecast the machining performance. The study involved conducting experimental trials to investigate the impact of crucial parameters in Wire Electrical Discharge Machining (WEDM). These parameters included pulse-on time, pulse-off time, wire tension, and wire feed rate. The objective was to analyze their influence on key performance indicators such as material removal rate (MRR), surface roughness

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

Evaluation of Dynamic Load Coming on E-Driveline Due to Bump and Study its Effect on Motor Mountings and Battery Position

2024-28-0171To be published on 12/05/2024

During the development of E-Driveline, it is observed that loading failure encountered with On-highway vehicle’s E-Drivelines has increased in comparison with traditional driveline. The major cause of these failures is motor and battery reaction loads acting on driveline in electric vehicles. The main source of load generation is acute dynamic reaction coming from road conditions i.e., bumps, potholes, ditch, uneven surfaces and get transferred to motor or batteries through the E-Driveline. The uneven distribution of motor and battery loads in vehicle will amplify the dynamic reactions which may lead to severe failures. It will be useful if we predict the dynamic loads in early design and simulation stage for accurate solution. This work is based on development of multi body dynamic modeling and simulation approach to predict loads coming on to E-Driveline due to road conditions and correlate it with test setup of actual vehicle running on these road conditions. After the correlation

Deshmukh, Shardul, NIKAM, VINOD

Implementation of a Hybrid Hardware-in-the-Loop (HIL) Test System for Automotive Software Validation and Verification

2024-28-0252To be published on 12/05/2024

The automotive industry relies heavily on software to enhance safety, performance, and user experience. The increasing complexity of automotive software demands rigorous testing methodologies. Ensuring the quality and reliability of this software is critical. In this paper, we propose an innovative approach to software validation and verification using a Hybrid Hardware-In-the-Loop (HIL) test system. Our methodology integrates diverse hardware and software tools to establish a flexible and efficient testing environment. This environment can evaluate the Device Under Test (DUT) with minimal alterations. Our comprehensive solution includes the development of test strategies, plant model simulation, and compliance assurance, all in accordance with automotive standards such as ASPICE and ISO26262. We also introduce a Personality module for the DUT, enabling sequential testing of multiple products using the same HIL setup. This is achieved by loading a DUT-specific signal mapping

Yadav, Vikaskumar, Bhade, Nilesh

Review of Integrated Thermal Management system for electric vehicle

2024-28-0227To be published on 12/05/2024

Electric vehicles use Li-ion batteries due to their high energy and power densities. Working of Li-ion batteries is very sensitive to temperature thus thermal management system becomes very important to provide safety and performance under different working conditions. This paper review different integrated thermal management system developed for electric vehicles. integrated thermal management content Battery thermal management, cabin thermal management and Electric drive thermal management. These systems share some common objectives and common parts so integrating these systems will help to optimize the number of components in the electric vehicles thermal management system. The integrated thermal management system also helps to optimize the weight and use of waste heat to heat the cabin or battery which will also help in optimization of energy consumed by the thermal management system and range improvement. But integrating different systems which content refrigerant and coolant

Mhaske, Pramodkumar Chimaji

Dynamic modeling of torque & emissions: Digital twin to simulate combustion process and exhaust emissions for diagnostics & prognostics applications

2024-28-0172To be published on 12/05/2024

A large fraction of today’s energy consumption is attributable to the transportation sector. Therefore, further development of internal combustion engines has a huge potential to reduce environmental impact through modelling complicated, fast and unsteady phenomena including the changes of emission gases concentration and output torque observed during diesel emission and combustion process. This paper presents research on the emission and combustion characteristics of a heavy vehicle diesel engine, elaborating an engineered framework for prognostics/diagnostics, state monitoring, and performance trending of heavy-duty vehicle engine and after treatment system (ATS). The proposed framework leverages advanced simulation and modeling methodologies to ensure precise predictions and diagnostics. By integrating physics-based models with data-driven techniques, the framework accurately models engine and exhaust system behaviors under various operating conditions. For exhaust system, framework

Singh, Prabhsharn, Thakare, Ujval, Hivarkar, Umesh

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

2024-28-0246To be published on 12/05/2024

Wire Electrical Discharge Machining (WEDM) is a non-conventional machining technique that provides distinct benefits in machining materials with high hardness and intricate geometries. Invar 36, a nickel-iron alloy with a low coefficient of thermal expansion (CTE), is widely used in the aerospace, automotive, and electronic industries because of its excellent dimensional stability across a broad range of temperatures. The main objectives are to optimize the machining parameters and create regression models that can accurately predict the key performance indicators. Experimental trials were performed utilizing a Wire Electrical Discharge Machining (WEDM) setup to fabricate Invar 36 specimens under different cutting conditions, such as pulse-on time, pulse-off time, wire tension, and wire feed rate. The machining performance was evaluated by measuring the material removal rate (MRR), surface roughness (Ra). The methodology of design of experiments (DOE) was utilized to systematically

Natarajan, Manikandan, Pasupuleti, Thejasree, Kiruthika, Jothi, Krishnamachary, PC, Silambarasan, R

Parametric Analysis of Relationship between Tyre and Braking Performances in Electric Vehicle

2024-28-0180To be published on 12/05/2024

Braking Performance is a measure of stopping distance & stability of the vehicle. When it comes to Electric vehicle, balancing Tyre performances i.e RRc, Traction, Tyre life & NVH characteristics is a challenge due to higher axle weights, higher moment of inertia and higher instantaneous torque. This study presents the Braking performances of EV intended tyres at various contact surfaces with different coefficient of friction in both Dry & Wet conditions. Impact of Tyre design attributes like Tyre tread Pattern, contact patch, Tread Compound, Tyre Constructions & Characteristics studied on 5 different tyres of Standard and Ultra High-Performance tyres on Braking performances. This paper contains the study & analysis of 1) Footprint Analysis with respect to Shape of the footprints , Pressure distribution, Land-sea ratio, Contact Area 2)Tyre tread design such as Grooves ,Ribs & Sipes design and Pitch length 3) Compound property studies like Hardness, Modulus ,Tensile strength ,Tear

V, Padmasri, Vellandi, Vikraman, SUNDARAM, RAGHUPATHI, Singh, Ram Krishnan, P, Praveen, CHITTIBABU, SANTHOSH

Calibrated Accelerated Life Testing (CALT) First Load Determination Using Systematic Step Stress Concept

2024-28-0251To be published on 12/05/2024

Calibrated Accelerated Life Testing (CALT) is a sequential and quantitative method to Accelerated Life Testing (ALT). Its design aims to optimize test efficiency by minimizing both test duration and sample size while estimating product life. In the CALT context, the focus is on testing specimen under three or more distinct stresses or loads to estimate the life span/BX life, which is a crucial parameter in reliability estimation. Determining the first load in CALT typically involves exploratory testing on a limited number of specimens and relies heavily on engineering judgments such as analyzing Finite Element Analysis (FEA) outcomes, referencing test data from comparable designs and materials, and considering stiffness results etc. This often leads to challenges in accurately identifying the first load/stress. To address this issue, we propose a systematic step-stress test approach instead of exploratory testing. This approach aims to efficiently identify the first load in CALT. The

Patidar, Nitin, Soma, Nagaraju

Study of impact forces on wheel rim from pothole impacts and improvement of flange design to eliminate wheel bend

2024-28-0262To be published on 12/05/2024

Typically, an automotive passenger car wheel rim can withstand gradual loading contributed from the vehicle during cornering and high-speed maneuvering and as per the standard as well as customer requirements wheel has to withstand some impact forced contributed from radial and inclined loading. But in some cased wheel rim may not withstand the impact forces generated during impact on potholes and curbs with high-speed maneuvering. This Study helps to understand the impact on wheel rim and the forces acting on the rim flanges during pothole impact and high-speed curb impact. For Electric vehicles, always unsprung mass contributes for lesser range and the wheel rim design contributes huge for the aero drag. Due to this the wheel rim weight plays an active role for vehicle performance and dynamics. In this study author tends to explain about the design of the rim flanges considering the impact forces the wheel rims are exposed to during pothole impact. Also, In this study, road load data

THIYAGARAJAN, SRIRAM, Jithendhar, A, Singh, Ram Krishnan, SUNDARAM, RAGHUPATHI, Paua, Ketan

Deployment of Continuous Integration and Continuous Testing in Mobility For Software Qualification

2024-28-0198To be published on 12/05/2024

Title: Deployment of Continuous Integration and Continuous Testing in Mobility For Software Qualification Abstract: In the rapidly evolving field of automotive engineering, the drive for innovation is relentless. One critical component of modern vehicles is the automotive ECU. Ensuring the reliability and performance of ECU is paramount, and this has led to the integration of advanced testing methodologies such as Hardware-in-the-Loop (HIL) testing. In conjunction with HIL, the adoption of Continuous Integration (CI) and Continuous Testing (CT) processes has revolutionized how automotive ECU are developed and validated. This paper explores the integration of CI and CT in HIL testing for automotive ECU, highlighting the benefits, challenges, and best practices. Continuous Integration and Continuous Test (CI/CT) are essential practices in software development. Continuous integration process involves regularly integrating code changes into the main branch, ensuring that it does not

Hande, Sheetal Vikram, Mandava, Balaji Bharath

Parametrized Twist Beam Suspension for Enhanced Ride and Handling : A Design Iteration Approach

2024-28-0181To be published on 12/05/2024

Objective: - The parametrized twist beam suspension is a pivotal component in the automotive industry, profoundly influencing the ride comfort and handling characteristics of vehicles. This study presents a novel approach to optimizing twist beam suspension systems by leveraging parametric design principles. By introducing a parameter-driven framework, this research empowers engineers to systematically iterate and fine-tune twist beam designs, ultimately enhancing both ride quality and handling performance. Methodology: - Affordable vehicles are widely equipped with twist-beam suspensions since they are simple to design, take up less space, and are less expensive to manufacture. It is difficult to design an axle made with twist-beam profiles due to the variety of possible configurations, and the suspension arm and axle beam stiffness must be adjusted. To address the challenges of optimizing the twist beam model, this study presents a simplified optimization model using MSC ADAMS. This

Pakala, Pradeep Kumar, Ganesh, Lingadalu

Optimization of Additive Manufacturing (Fused Deposition Modeling) of PETG Material Using Taguchi Grey Relational Analysis

2024-28-0234To be published on 12/05/2024

Additive Manufacturing (AM), specifically Fused Deposition Modeling (FDM), has become a highly promising method for creating intricate shapes using different materials. Polyethylene Terephthalate Glycol (PETG) is a highly utilized thermoplastic that is recognized for its exceptional strength, resistance to chemicals, and effortless processing. This study aims to optimize the process parameters of the FDM technique for PETG material using Taguchi Grey Relational Analysis (GRA). An empirical study was carried out to examine the impact of various FDM process parameters, such as layer thickness, infill density, printing speed, and nozzle temperature, on important outcome variables like dimensional accuracy, surface quality, and mechanical properties. The Taguchi method was used to systematically design a series of experiments, while GRA was used to optimize the process parameters and performance characteristics. The results unveiled the most effective parameter combinations for attaining

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

Low Cycle Thermo-Mechanical Fatigue Life of Solder Joints using Cohesive Zone Model

2024-28-0253To be published on 12/05/2024

A temperature dependent cohesive zone model considering the thermo-mechanical fatigue loadings are used to simulate and predict the failure process of solder joint interface in power electronics modules. Cohesive Zone Models (CZMs) are gaining popularity for modeling the fracture and fatigue behavior in various class of materials such as metals, polymers, ceramics, and their composite materials. Unlike the traditional fracture mechanics which considers concept of infinitesimal crack, CZMs assume a fracture process zone in which external energy is distributed in vicinity to propagating crack. In order to predict the fatigue-fracture process under thermo-mechanical cyclic loading, a damage accumulation variable is utilized. The calculation of damage is performed using a progressive mechanism, and the cohesive zone model is updated to reflect the present level of damage. The existing cohesive forces are influenced by both the current damage status and the extent of separation

Singh, Praveen Kumar, Sahu, Abhishek, Chirravuri, Bhaskara, miller, Ronald

Influences of porosity shapes and sizes on stress and strain fields in the Casted Aluminum using Finite Element Modelling

2024-28-0159To be published on 12/05/2024

Porosity is a common issue in Aluminum casting. The contemporary casting technologies have succeeded to some extent in predicting and controlling the casting defects. It is still impossible to eliminate various defects such as porosity, voids, and inclusions. It is also difficult to predict the exact shape and size of defect. Consequently, a key challenge in designing casted components is to validate durability by predicting accurate stress, strain, and strength by considering casting defects. In the present work, a set of static elastic-plastic finite element analyses (FEA) performed to obtain the stress and strain fields distribution near the voids/pores, and their resultant impact on tensile strength of Aluminum under tensile testing is studied. Using FEA, the stress and strain fields are determined for simple tensile test samples/specimens without and with voids/discontinuities modeled under a uniform displacement applied at a far field. The stress concentration is evaluated as a

T, Kalinga, Sahu, Abhishek, Chirravuri, Bhaskara, miller, Ronald, Xu, Siguang

Simulation methodology for hydrogen concentration and dilution strategy in a hydrogen fueled internal combustion engine

2024-28-0220To be published on 12/05/2024

Manufacturers of internal combustion engines are changing their focus to non-conventional fuels like hydrogen in response to the worrying global warming situation. When compared to conventional fuels like gasoline or diesel, the use of gaseous hydrogen fuel in an internal combustion engine powered by hydrogen can lessen the engine's negative environmental effects. But occasionally, hydrogen can leak to the engine top cover through the high-pressure fuel injection system or as blowby within the crankcase. Static zones may emerge as a result of these H2 leaks. Potential explosion or fire can result when the H2 concentration in these stagnation zones is more than 4% and triggers a minimum ignition energy of 0.02 mJ. A CFD simulation methodology incorporating multi-species model, piston, and crank motion is developed to estimate the H2 concentration within crankcase. The blowby values are determined from the experimental measurement and used as the inputs. The dilution strategy and system

Sahu, Abhay Kumar, Nagawade, Shubham, Veerbhadra, Swati

Characterization of Cut and Chip Damage in Ultra Low Rolling Resistance Tire for Electric Vehicles

2024-28-0175To be published on 12/05/2024

Since the inception of battery driven electric vehicles in the automotive world, there has been a constant challenge in maximizing the range of an electric vehicles through various means including battery technology, vehicle weight optimization, low drag coefficients etc. The tires being a viscoelastic composite material have now become a vital to the range performance of an EV. The rolling resistance of a tire is now become a hotter topic than ever. The rolling resistance coefficient (RRC) is the measure of energy loss during rolling due to viscoelastic dissipation in the tire. The viscous dissipation in tire arises due to hysteresis in the various components of a tire including tread, sidewall, inner liner, apex etc rubber compounds. The internal friction between layers of body ply, steel belts and tread crown ply also contribute to the internal heat generation. Therefore, the development of ultra-low RRC tires is a serious challenge for tire engineers. Nevertheless, the recent

Mishra, Nitish, Singh, Ram Krishnan

Analyzing effect of reinforcement on stir casted 7075 Aluminum alloy

2024-28-0165To be published on 12/05/2024

Growing demand for fuel-efficient vehicles and lower CO2 emissions has led to the development of lightweight materials. Aluminum composites are being used to achieve light weighting in order to improve performance, efficiency, and sustainability across various industries. The unique properties of aluminum composites make them an attractive choice for researchers and designers looking to optimize their products. Reinforcement materials play a vital role in the development of these composites, acting as barriers to dislocation movement within the aluminum matrix. This effectively strengthens the material and prevents deformation under load, resulting in increased tensile strength and fatigue resistance. Additionally, aluminum composites exhibit improved thermal and electrical conductivity, making them suitable for automotive applications. In this study, metal matrix composites (MMCs) of aluminum 7075 alloy were developed using silicon carbide (SiC) and fly ash as reinforcements. Three

Manwatkar, Asmita Ashok, Santosh Jambhale, Medha, Mahagaonkar, Nitin, Sharma, Dipesh

Comprehend Dynamic Behaviour of Vehicle Body for Refined NVH Performance

2024-28-0265To be published on 12/05/2024

Modal performance of a vehicle body often influences tactile vibrations felt by passengers as well as their acoustic comfort inside the cabin at low frequencies. This paper focuses on a premium hatchback’s development program where a design-intent initial batch of proto-cars were found to meet their targeted NVH performance. However, tactile vibrations in pre-production pilot batch vehicles were found to be of higher intensity. As a resolution, a method of cascading full vehicle level performance to its Body-In-White (BIW) component level was used to understand dynamic behavior of the vehicle and subsequently, to improve structural weakness of the body to achieve the targeted NVH performance. The cascaded modal performance indicated that global bending stiffness of the pre-production bodies was on the lower side w.r.t. that of the design intent body. To identify the root cause, design sensitivity of number and footprint of weld spots, roof bows’ and headers’ attachment stiffness to BIW

Titave, Uttam Vasant, ZALAKI, NITIN, Naidu, Sudhakara

Effect of vibrational abuse on the electrodes of Nickel Manganese Cobalt (NMC) and Lithium Iron Phosphate (LFP) 18650 cells

2024-28-0156To be published on 12/05/2024

In light of the growing demand of Electric vehicles (EVs) as a sustainable mode of transportation, it becomes essential to understand the effect of various abuse conditions that batteries undergo. Vibrational abuse is a significant condition experienced by batteries in operation. Vibrations caused by road roughness, acceleration inertia, and other factors can affect key performance indicators such as cycle life, capacity retention, and safety. These cells undergo various chemical and mechanical reactions over time, leading to degradation of components like the anode, cathode, electrolyte, separator, and current collector, resulting in reduced performance. Therefore, understanding battery degradation is important for managing system performance. This study is focused on a detailed analysis of Lithium Iron Phosphate (LFP) and Nickel Manganese Cobalt (NMC) cells subjected to vibrational abuse. Vibration testing was carried as per International Electrotechnical Commission (IEC) standard

Manwatkar, Asmita Ashok, Pandit, Sachin Prabhakar, Santosh Jambhale, Medha, Mahagaonkar, Nitin

Equivalent Circuit Modeling of Sodium-Ion Batteries Incorporating Temperature Effects: A Comprehensive Investigation

2024-28-0225To be published on 12/05/2024

The shift from internal combustion engine vehicles to electric vehicles has driven significant advancements in battery technology, aiming for safer and more reliable energy storage solutions. While Lithium Iron Phosphate (LFP) batteries are known for their safety, they are dependent on critical elements such as copper, lithium, and graphite. The safe transport of Li-ion batteries remains a concern. Addressing these challenges, Sodium Ion Batteries (SIBs) have emerged as sustainable alternatives suitable for lightweight electric vehicles (EVs). Ensuring their seamless integration into EV battery packs requires preparedness for the rapid evolution of SIB technology. Model-based approaches, including Equivalent Circuit Models (ECMs), play a pivotal role in developing advanced Battery Management Systems (BMS) and State of Charge (SoC) estimation algorithms for precise battery control. This study conducts a comprehensive evaluation using various order resistance-capacitance (RC) ECM

Ns, Farhan Ahamed Hameed, Gupta, Shubham, Jha, Kaushal

Novel UWS mist injection technique for SCR performance improvement

2024-28-0133To be published on 12/05/2024

The present study aims to meet the Euro-VII compliance applicable for internal combustion engines (diesel and hydrogen) by improving the performance of selective catalytic reduction (SCR) system using a novel UWS mist generation technique. The SCR system helps to convert the harmful NOx emission into harmless by-products by injecting the UWS, which is converted into ammonia (NH3). Despite the proven technology, there are several challenges presented in the existing system which degrade the SCR performance: (i) incomplete droplet evaporation (ii) solid deposit formation (iii) non uniformity of NH3 distribution at the catalyst entrance. The past studies shows that the droplet size plays a major role in this context. Further, it is noted that the smaller size droplets are desirable to overcome the impediments and enhance the efficiency of SCR application. Therefore, the current work numerically investigates the effect of mist (contains very fine size droplets) injection on the droplet

Venkatachalam, Palaniappan, Shiva, Shashidhar, GOVINDARAJAN, VAISHALI, Soni, Prerna, PATIDAR, SACHIN

ADVANCE METHOD OF MEASURING TCD "TURNING CIRCLE DIAMETER" FOR VEHICLE

2024-28-0267To be published on 12/05/2024

Turning circle diameter (TCD) of vehicle is critical parameter which is used to determine the turning capability of vehicle. TCD is the smallest circular turn that a vehicle can make of given drive track. The TCD mainly depends on vehicle wheel lock angles, wheelbase, and geometric architecture of vehicle. The Regulation certification requirement of steering system, states that the maximum TCD should be less than 24m & TCCD 25m (M&N category). (IS 12222:2011 & R79). This invention relates to measuring the TCD of vehicle Vehicle's TCD is measured in plenty of open space. Road wheel is steered to full lock condition either in left or right and driven at low speed. Outer side wheel mark is traced on ground with help of chalk, or some other means and final trace mark is measured with tape from center. This is popular and most used TCD measurement, this process involves lot of manual intervention, time consuming, safety concern and has more room for error. Our proposed solution : The

Yadav, Satyendra, Ojha, Vijay, Chatterjee, Anupam, Saikrishna, VNL, karthik, V

Developing AI Safety-Critical Applications: A Framework Using Model-Based Design, Verification, and Validation

2024-28-0257To be published on 12/05/2024

In the rapidly evolving landscape of Artificial Intelligence (AI), deploying AI models in safety-critical industries such as aerospace, automotive, and healthcare necessitates a rigorous framework for ensuring their accuracy, reliability, and trustworthiness. This paper delves into the crucial roles of Verification and Validation (V&V) techniques in the lifecycle of AI models, underlining their significance in the certification and deployment of AI systems in environments where errors can have severe consequences. Drawing upon recent advancements and regulatory frameworks, including adapting traditional V&V workflows into a more comprehensive W-shaped development process, the paper offers insights into the methodologies for systematically verifying and validating AI models. Through the lens of a case study on developing the Battery Heat Prediction Model, we exemplify the application of these V&V techniques from gathering requirements to creating a robust AI model. Through W cycles we

Shirke, Koustubh, Sehgal, Nukul

MBSE for SDV: A Framework for Efficient Resource Allocation and System Behavior in Software-Defined Vehicles

2024-28-0255To be published on 12/05/2024

The emergence of Software Defined Vehicles (SDVs) presents a paradigm shift in the automotive domain. In this paper, we explore the application of Model-Based Systems Engineering (MBSE) for comprehensive system simulation within the SDV architecture. This MBSE approach can help to reduce the complexity involved in Software-Defined Vehicle Architecture making it more flexible, consistent and scalable. The proposed approach facilitates the definition and analysis of functional, logical, and physical architectures, enabling efficient resource allocation and verification of system behavior. Our framework addresses key aspects of SDV development: • Functional Decomposition: We establish high-level system functions at the root level, and decompose each function to make them abstract for defining the overall functionality of the SDV. • Logical Architecture: This layer focuses on component logic and data communication between Electronic Control Units (ECUs), High-Performance Compute Devices

Navas, Akhil, Sehgal, Nukul, Paul, Annie

Methodology for designing traction motor for an Electric Vehicle with tandem application of vehicle system 1D simulation and electromagnetic simulation

2024-28-0226To be published on 12/05/2024

This paper presents a comprehensive methodology for sizing a machine for a given vehicle performance target and analyzing the machine performance at different operating zones of the electric vehicle. Designing the powertrain of an electric vehicle starts with understanding the on-road performance requirements of the vehicle relevant to the application such as top speed, gradient and acceleration targets. It is critical to define the operating performance boundary of the vehicle based on end user preference. This paper illustrates a comprehensive approach of implementing 1D simulation tool namely GT-Suite to simulate the vehicle model for different on-road performance targets so as conclude the traction motor specifications. These specifications along with the other boundaries of the vehicle such as battery limitations and MCU limitations are taken as input parameters for the electromagnetic simulation assisted by Ansys Motor-CAD to design optimized machine that can meet the application

Ghule, Gopal Arjun, Neelakantan, Subramoniyan

Driver comfort improvement for a deep mine tipper vehicle for sustained fatigue free persistent driving

2024-28-0208To be published on 12/05/2024

Drivers of heavy commercial tipper vehicles are required to work in the application of carrying heavy loads as well as the rough terrain in off-road conditions. Due to the nature of the application, the primary vehicle/chassis suspension and the cabin suspension are designed to take higher tonnages of load carrying capacity as well as to withstand the rigors of the tough off road terrain conditions. The primary objective of the vehicle and cab suspension design is to enhance the vehicle durability and endurance life suitable for the application. This results in the drivers being subjected to continuous or intermittent exposure of comprehensive magnitudes of low frequency high amplitude whole-body vibration. Short term impact of such vibration results in blurred vision, headache, dizziness and fatigue, etc Prolonged exposure to such vibration has been associated with disorders of the lumbar spine and the connected nervous system. This effectively poses a critical occupational hazard to

Venkatesh, Srinivasa, prabhakaran, Baskaran

Automotive 5G : Roadmap and Challenges

2024-28-0217To be published on 12/05/2024

The advent of 5G technology is set to revolutionize the automotive industry, enabling a host of new applications that align with emerging automotive megatrends such as connectivity, autonomy, and enhanced user experiences. This paper provides an overview of the roadmap for integrating 5G into the automotive sector and examines the challenges that must be addressed to realize its full potential. 5G's high-speed, low-latency communication capabilities are pivotal in advancing vehicle-to-everything (V2X) connectivity. This facilitates real-time data exchange between vehicles, infrastructure, pedestrians, and networks, supporting applications such as advanced driver assistance systems (ADAS), autonomous driving, and intelligent traffic management. Enhanced V2X communication enables vehicles to make faster, more informed decisions, thereby improving safety and efficiency on the roads. Moreover, 5G technology enables enhanced in-car experiences through high-bandwidth applications like

Rajappa, Yashavanth

Parameter Identification techniques for PMSM: An Overview

2024-28-0151To be published on 12/05/2024

In hybrid and electric vehicles, the stable and precise operation of the motor significantly impacts vehicle performance. The Motor’s operation depends on its electrical and mechanical parameters. This paper focuses on PMSM motor’s electrical parameters such as stator resistance, D-Q axis inductance, and permanent magnet flux linkage. Identifying the electrical parameters of a PMSM motor is complex due to the non-linear relationship between input and output. A change in one parameter can alter the motor’s dynamic response. This paper presents a comparative analysis of various PMSM electrical parameter's identification techniques. Further the paper proposes an optimized sequence of conducting these techniques

Tank, Kartik, Pandey, Pramod, Sharma, Shashank, Mandal, Sandeep, Hasan, Mohammad

Drag Prediction of an Electric Cargo Scooter

2024-28-0173To be published on 12/05/2024

Drag prediction is a very important stage in the design of an electric cargo scooter. Early knowledge of the drag forces will enable designers to accurately estimate the motor power, size, battery pack size, vehicle range, and the maximum speed of the vehicle. In the present paper we present a simulation-based methodology to estimate the drag forces and drag coefficient accurately and to identify possible design changes to optimize and reduce them. The main advantage of simulation-based method is reducing the number of prototypes built during the initial design stages and reducing wind tunnel tests. Future variants also will not require any wind tunnel measurements as they can be accurately predicted using the established process. Reynolds Averaged Navier Stokes (RANS)-based steady state Computational method is utilized. The study includes mesh independence, inlet velocity independence, and Turbulence model independence

Balachandran, Karthik, Das, Alok, Shinde, Pranav

A Simulation-based Methodology for Optimizing correlation of Brake Disc

2024-28-0183To be published on 12/05/2024

Brake disc thermal capacity is a key factor for brake performance and brake part life. Hence it is very important to optimize the correlation of brake disc for thermal capacity by considering the critical parameters. Optimization algorithm is used to optimize the critical parameters to achieve the correlation. A front loading tool is developed to optimize the brake disc keeping target thermal capacity via optimization algorithm

Negi, Ayush Singh, Kochhar, Raman

A predictive controller for battery cooling systems to tackle the comfort-safety-efficiency dilemma

2024-28-0147To be published on 12/05/2024

The advent of electric vehicles has increased the complexity of air conditioning systems in vehicles which now must maintain the safety and comfort of occupants while ensuring that the high voltage battery temperature is kept within safe limits. This new task is critical due to the influence of the cell and battery pack temperature on the efficiency. Moreover, high temperatures within the battery pack can lead to undesirable effects such as degradation and thermal runaway. Classical solutions to this problem include larger air conditioning components to support worst case scenario conditions where the cooling request from the battery and the cabin happen at the same time. In such conditions, for the safety of the battery, the cooling request is assigned to battery system which may cause discomfort to the passengers due the significant temperature increase in the cabin during such events. The probability of such events happening is certainly dependent on the weather conditions but in

Palacio Torralba, Javier, Kulkarni, Shridhar Diliprao, Shah, Geet, Jaybhay, Sambhaji, Kapoor, Sangeet, Locks, Olaf

Cost Optimization Techniques for EV Charging Stations based on Renewable Energy Sources and Grid power

2024-28-0146To be published on 12/05/2024

Adoption of Electric Vehicles (EVs) reduces air pollution by reducing harmful gas emissions. Such adoption, however, needs a reliable and convenient charging infrastructure, including smart EV charging. Renewable energy sources such as solar photovoltaic cells, battery and wind energy systems can address these infrastructural gaps which work in conjunction with main grid power supply thereby providing low-cost electricity. This paper introduces an energy management algorithm for integrated renewable and grid power sources available at charging stations across India that considers techno-economic and environmental factors. The current work proposes a supervisory controller model that manages the load power demand of the charging station. The controller effectively deploys low cost energy sources based on the status of all available power supplies and reduces the overall charging costs in real time. The energy management algorithm ensures adequate stand-alone energy generation and

SHUKLA, ANKIT, Kushwah, Yogendra Singh, Suman, Saurabh

Trailer Disengage confirmation Alarm System for Electric Subsystems

2024-28-0213To be published on 12/05/2024

This paper presents a Trailer-Tractor Disengage Alarm System (TTDAS) designed to enhance safety in electrical connections between the tractor and trailer of commercial vehicles. The proposed system addresses the critical issue of unintentional disengagement of electrical connections, which can lead to hazardous situations on the road. The system employs sensor technologies and intelligent algorithms to continuously monitor the status of the electrical connection between the tractor and trailer. In the event of a disconnection, the system activates a robust alarm mechanism to promptly notify the driver, mitigating the risk of accidents and ensuring the safety of both the vehicle and other road users. Key features of the Trailer Disengage Confirmation Alarm System include real-time monitoring, rapid response time, and compatibility with various trailer configurations. The paper details the system architecture, including the integration of sensors, control units, and the alarm mechanism

Singh, Amandeep, KUMAR, Pradeep, SURESH, KARTHIKRAJAN, KOTIAN, PRADEEP, T, THIRUNAVUKKARASU, Chitreddy, Bharath, R, Sunilkumar

Synthesis and characterization of advanced multi nanoparticle based nanofluid stabilized by surfactants

2024-28-0139To be published on 12/05/2024

Recently, there has been a growing emphasis on Thermal Management Systems (TMS) for Lithium-ion battery packs due to safety concerns related to fire risks when temperatures exceed operating limits. Elevated temperatures accelerate electrochemical reactions, leading to cell degradation and reduced electronic system performance. These conditions can cause localized hotspots and hinder heat dissipation, increasing the risk of thermal runaway due to high temperatures, flammable gases, and heat-producing reactions. To tackle these issues, many automotive manufacturers employ indirect liquid cooling techniques to maintain battery pack and electronic system temperatures within safe limits. Engineered nanofluids, particularly those containing multi-nanoparticles dispersed in water and ethylene glycol, are being explored to enhance thermo-physical properties. This paper focuses on the experimental characterization of nanofluid containing Titanium Dioxide (TiO2), Copper Oxide (CuO), Aluminum

Nahalde, Sujay, More, Hemant, Honrao, Gaurav

A Comprehensive Analysis of Electromagnetic NVH in Electric Powertrain

2024-28-0136To be published on 12/05/2024

In this paper, a comprehensive analysis of NVH in electric powertrains due to electromagnetic sources is presented. The spatial harmonics model of the traction motor, which is dependent on the motor design structure, rotor poles, stator teeth, and slots, is used for the analysis of the electromagnetic forces from the motor in the electric powertrain. The time harmonics model of the injected current of the motor dependent on the drive electrical circuit and control strategy is also considered for the electromagnetic force calculation. A complete workflow of this electromagnetic NVH analysis for electric powertrain covering the spatial harmonics and time harmonics model is presented. The spatial harmonics model result is presented as flux linkage with respect to dq-axes current and rotor position. The time harmonics are also presented by the injected current of the motor. In addition, a set of operating points on the torque-speed boundary of the traction motor is selected and results are

Joshi, Nakul, Kumar, Vinit, Tsoulfaidis, Antonios, Huang, Zhenhua, Schmaedicke, Marcel, Fialek, Gregory, Zhang, Dapu, Wimmer, Joe

A comprehensive review of advancement in anode material with modified architecture for lithium-ion batteries

2024-28-0142To be published on 12/05/2024

Anode material, responsible for the critical storage and release of lithium ions during charge and discharge cycles, holds paramount importance. By strategically altering the material design and composition of the current graphite, researchers aim to significantly improve fast charging capabilities, energy density, cycling stability and overall electrochemical kinetics within Lithium ion battery. Anode materials operate through three primary mechanisms: insertion/de-insertion that is allowing for reversible lithium ion accommodation within the host structure; alloying, where lithium ions form chemical bonds with the anode material; and conversion reactions, involving the creation of new phases during charge/discharge cycles. This review delves into a captivating array of advanced anode materials with the potential to surpass the limitations of traditional graphite. Carbon-based nanomaterials like graphene and its derivative, reduced graphene oxide, offer exceptional conductivity and

Borkar, Shweta, Nahalde, Sujay, More, Hemant, Ruban J S, Alwin

Safe Phase Current Measurement for Motor Controlled Traction-Inverter Application

2024-28-0141To be published on 12/05/2024

The Traction-Inverter is a key component of electric vehicles, as it connects the battery, the motor, and the vehicle control systems as automotive industry is moving towards electrification. Phase current measurement one of its functionalities ensures to achieve accurate motor control, efficient torque production and optimal performance in traction inverter application. This paper proposes method for phase current measurement of PMSM (Permanent magnet synchronous motor) with EVADC (Enhanced Versatile Analog-Digital-Converter) to measure current of three phases motor synchronously. To accomplish measurements free of current ripples, the EVADC module converts sensed data synchronously at the middle of the PWM (Pulse Width Modulation) trigger signal. Due to due to its high precision and flexibility, conversion speed, synchronization and parallel sampling, DMA (Direct Memory Access)- driven result handling, anti-aliasing filtering, system integration, arbitration and conversion sequences

Birari, Ashwini Anil

Evaluation of Mechanical Properties of Reduced Stress Localized Aluminium Composites for Automobile Applications

2024-28-0241To be published on 12/05/2024

The modern-day development in the field of mobility demands the development of advanced engineering materials for various engineering applications. Composite materials play a pivotal role in the advancement of mobility by achieving overall weight reduction and thereby contributing to the sustainability of the environment. Metal matrix composites has played a crucial role over the last few decades in the automotive industry replacing the conventional metal in achieving a better strength to weight ratio. Metal matrix composites can be a combination of a metal and a ceramic combined at a macroscopic level to achieve better mechanical and tribological properties at a reduced weight to strength ratio. Aluminium being one of the largest metals widely used in automobiles, are gradually being replaced with Aluminium metal matrix composites. Aluminium – silicon carbide composite is a key interest among the researchers due to the attractive mechanical and tribological properties that enhance the

VALSAN, ASHRAY

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