Browse Topic: Environment

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Effect of EGR and Ethanol additive on Performance and Emission Characteristics of Diesel Engine Fuelled with Rubber Seed Biodiesel Blends2026-28-0055To be published on 02/01/2026
Alcohol is being considered as an alternative to traditional fuels for compression ignition engines due to their oxygen content and biomass origin. Although alcohol generally has lower cetane numbers, which makes them more favorable for premixed combustion, they also offer potential for lowering emissions in internal combustion engines, particularly when combined with strategies such as exhaust gas recirculation (EGR). This research focuses on enhancing the performance of a single-cylinder, four-stroke diesel engine by introducing ethanol into the intake port during the intake phase. Diesel and rubber seed biodiesel were used as primary fuels and were directly injected into the combustion chamber. The findings indicated that adding ethanol to rubber seed biodiesel, along with 10% EGR, led to improved brake thermal efficiency and a reduction in NOX emissions. The ethanol injection timing and duration were optimized for effective dual-fuel operation. At full engine load, the highest
Saminathan, SathiskumarG, Manikandan
Intelligent Driver Behavior Analytics for Enhanced Road Safety2026-28-0054To be published on 02/01/2026
The present work on Intelligent Driver Behavior Analytics System that monitors and analyzes road users to ensure road safety and regulatory compliance, the system developed by using machine learning algorithms with the help of Raspberry Pi micro controller. It is said that most road accidents are caused by driver incompetency, yet, dangerous driving behavior is hard to detect on the road; this system monitors dangerous driving and other related behaviors that cause road accidents as well as contribute to noise pollution. It also alerts vehicle pauses on high-risk areas like road edges and also compares the routes planned to routes traveled on the GPS to alert any route slippage. Drivers, fleet managers and fleet operators get real-time feedback, and they are encouraged to take corrective action immediately. The system is expandable and is applicable to transportation agencies, public safety organizations and individuals who own vehicles and need to hone road safety and performance
Prasad, Gvl
Design and Development of Integrated Brake and Bull Cage System for Enhanced Tractor Performance and Sustainability2026-28-0005To be published on 02/01/2026
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
Galvanic Corrosion Susceptibility Analysis and Mitigation strategies in Automotive Battery Packs2026-28-0018To be published on 02/01/2026
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
Experimental Analysis on the Performance and Emission Characteristics of Direct Injection Diesel Engine Fuelled with Chlorophyta Algae Oil Biodiesel Blends2026-28-0045To be published on 02/01/2026
Chlorophyta algae, also known as green algae, are rich in oils suitable for biodiesel production. They grow quickly using minimal resources and can be cultivated on non-arable land. The extracted oils can be converted into biofuels that improve engine performance and reduce emissions. This makes Chlorophyta algae a sustainable and eco-friendly alternative to fossil fuels. This study presents an experimental investigation into the performance and emission characteristics of Chlorophyta algae oil biodiesel blends (A20 and A30) compared to conventional diesel (D100) in a direct injection (DI) diesel engine. The analysis reveals a notable enhancement in brake thermal efficiency (BTE), with A20 showing a 2.5% improvement and A30 demonstrating a 1.2% increase, attributed to enhanced combustion kinetics. Furthermore, brake specific fuel consumption (SFC) decreases by 4.1% and 6.8% for A20 and A30, respectively. Emission analysis indicates significant reductions in carbon monoxide (CO
M, SelvamR, Ganapathy SrinivasanKa, HarishSelvamani, MuthukumarB, Sanjai
Performance and Emission Analysis of Diesel Engine Fueled with Waste Polypropylene-Derived Biodiesel Blended with Diethyl Ether2026-28-0019To be published on 02/01/2026
To solve the dual environmental issues of plastic pollution and reliance on fossil fuels, this study investigates the pyrolysis of waste polypropylene (PP) plastic into alternative diesel fuel. To improve fuel performance, the refined pyrolytic oil from PP was combined with regular diesel and 5% diethyl ether (DEE). The following three blend ratios were developed and assessed for important fuel characteristics: viscosity, density, flash point, cetane number, and calorific value: B10-DEE5-D85, B20-DEE5-D75, and B30-DEE5-D65. In order to enhance cold-start performance and ignition quality, DEE was used as an oxygenated additive. A four-stroke, single-cylinder diesel engine was used to test these mixes in order to evaluate their emissions and brake thermal efficiency. According to the results, the B10-DEE5-D85 mix had the most balanced performance, reducing CO and CO₂ emissions significantly when compared to pure diesel, especially while operating at full load. However, as the amount of
K S, Karthi Vinith
Optimization of Exhaust System Design to meet Backpressure, Durability, Thermal Safety, and Accessibility for EU6 Heavy Duty Trucks.2026-28-0006To be published on 02/01/2026
Any Automotive exhaust system is evaluated based on the following criteria, namely pass-by noise (PBN), exhaust backpressure, durability & reliability (D&R), Thermal Safety, and cost. Exhaust Aftertreatment System/Devices (EATS) has become integral to BS-IV or EU-IV onwards vehicles, which require additional emissions testing. This paper covers an innovative exhaust solution for a 17L, 780 hp engine Eu6 vehicle, having a higher exhaust gas flow rate and severe application (duty cycle), and the same packing space of exhaust upstream pipe. In addition, it was the requirement to take account of field failure issues observed in earlier products (running in the field) and to resolve problems faced during the Beta Proto Build. Authors have optimized the Design using CFD (for backpressure) , Durability analysis (Structural life), IPS simulation (for Accessibility) and Thermal simulation (hot spot analysis). The designed exhaust upstream pipe is an innovative twin-bellow configuration with
Rokade, AdityaP, Balu MukeshKolavennu, PrajwalBiswas, Sanjoy
Multi-Objective Optimization of WAAM for Sustainable Production of Automotive-Grade Components2026-28-0030To be published on 02/01/2026
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
Effect of Gasoline as manifold fuel for Prosopis juliflora biodiesel fuelled CRDI stationary diesel Engine in Dual-Fuel Mode2026-28-0014To be published on 02/01/2026
Utilisation of non-edible biodiesel in the diesel engine has tremendously increased nowadays. This is due to its renewable nature and produces less pollution than conventional diesel, except for NOx emissions. To overcome the drawbacks, some additional fuel is added to take part in the combustion along with the biodiesel in a dual-fuel mode (DFM). In the present work, an investigation was carried out to assess the effect of gasoline as a manifold injection fuel (MIF) under 0, 10, and 20% energy share (ES) on Prosopis juliflora biodiesel (PJBD) fueled diesel engine in the DFM, and compared with single fuel mode (SFM). The diesel B0 (100% Diesel), and PJBD blends B10 (10% PJBD and 90% diesel), and B20 are used as direct injection fuel (DIF) in three fuel combinations. The experiment was carried out in a common rail direct injection, 3.7 kW stationary single-cylinder diesel engine under a constant speed of 1500 rpm. Compared to diesel SFM, the PJBD SFM shows a slightly lower brake thermal
Tamilvanan, A.
ALTERNATE CATALYST FOR DOC IN A CATALYTIC CONVERTER2026-28-0016To be published on 02/01/2026
Emission norms have become much more stringent to reduce emissions from vehicles. Diesel engines in particular are the predominant contributors to higher emissions. Diesel Oxidation Catalyst (DOC) in diesel engine catalytic converter systems is the crucial component in reducing harmful emissions such as Carbon Monoxide (CO) and unburnt Hydrocarbons (HC). DOCs often rely on expensive noble metals like platinum or palladium and rhodium as catalyst materials,significantly inflating the cost of emission control units. The proposed idea is to explore MnOxCeO₂ (Manganese Oxide-Cerium Oxide) as an alternative catalyst to traditional DOC materials, with the goal of delivering effective oxidation performance while reducing overall system cost. MnOx-CeO₂ catalysts are promising due to their good low-temperature activity, oxygen storage capacity, and redox behaviour, which are beneficial for diesel engines operating under varied conditions. These properties help improve the oxidation of CO and HC
C, JegadheesanT, KarthiRajendran, PawanMuruganantham, KowshiikS, Vaitheeshwaran
PERFORMANCE AND EMISSION CHARACTERISTICS OF LEMON PEEL OIL BIODIESEL WITH DIETHYL ETHER AND ETHANOL IN A CI ENGINE: AN EXPERIMENTAL INVESTIGATIONS2026-28-0052To be published on 02/01/2026
The rising global energy demand and the adverse environmental impacts of fossil fuel consumption have intensified the search for sustainable alternative fuels. Among the various biodiesel sources, lemon peel oil (LPO) offers promising potential due to its biodegradability, availability from waste resources, and favorable combustion characteristics. This study investigates the performance and emission characteristics of LPO biodiesel blended with diethyl ether (DEE) and ethanol in a compression ignition (CI) engine. Three blends B5, B10, and B15 were prepared by varying the proportions of LPO, DEE, and ethanol with conventional diesel. The physicochemical properties of the blends were evaluated as per ASTM standards and found to be compatible with CI engine requirements. Experiments were conducted on a variable compression ratio (VCR) CI engine under different load conditions. Results showed that the B10 blend exhibited superior brake thermal efficiency (BTE), achieving an improvement
M, BoopathiG, ManikandanDeepan Kumar, SadhasivamA, TamilselvanK, NithyanandhanS, Karthikj, Deepan ChakrawarthiX, Leslie Peter
Enhancing combustion, performance and emission profiles using kapok methyl ester blends with hydrogen2026-28-0058To be published on 02/01/2026
This study investigates the potential of using a dual green alternative fuel combination, the one is hydrogen fuel and another one is biodiesel for enhancing the Combustion, performance and emission characteristics of a compression ignition engine. The kapok oil methyl ester was blended with diesel in proportions of 20% (K20) and 40% (K40) by volume. The hydrogen gas was supplied at a constant flow of 4 liter per minute (LPM). The experimental fuels are neat diesel D100, K20 (80% Diesel and 20 % kapok methylester), K40 (60% Diesel + 40 % Kapok methyleter), K20 + H4L (K20 with 4 LPM hydrogen) and K40+H4L (K40 with 4 LPM hydrogen). These blends were tested in a single cylinder direct injection diesel engine under different load conditions at a constant speed of 1500 rpm, combustion, performance and emissions characteristic were evaluated and compared with base fuel. The results indicated that te use of B20 and B40 blends without hydrogen led to reduced brake thermal efficiency due to
Anbarasan, ANBARASANM, KUMARESAN
Experimental Investigation of Bio-Butanol Addition into Diesel, Biodiesel, and Diesel-Biodiesel blends on the Thermal Release of the Power Pack2026-28-0056To be published on 02/01/2026
Biodiesel and Bio-Butanol are among the renewable fuels that are manufactured from the waste cooking oil and the cut waste vegetables and fruits. This research work includes the investigation of volume of bio-butanol that can be blended with diesel, biodiesel and diesel-biodiesel blends such that the properties of the final blend along with the test of solubility under 25 deg Celsius for sixty days in a controlled environment, possesses competent properties with respect to base values of diesel. Following this an investigation of performance, combustion and emission characteristics of diesel power pack has been performed. The results indicate that biobutanol can be blended with diesel up to 20%, up to 50% with diesel-biodiesel (20%), and 35% with biodiesel. The test in the power pack depicts that the thermal efficiency, smoke , carbon monoxide and hydrocarbons from the fueled power pack are found to be higher when comparing the reference values of diesel. However, the values of fuel
B, PrabakaranYasin PhD, MohdMamat, Rizalman
Quantifying the Energy Consumption of HVAC Operation and Its Impact on the Range of Electric Buses Across Diverse Climatic Conditions2026-26-0204To be published on 01/16/2026
Electric buses (e-buses) are essential to sustainable public transport, but their real-world efficiency and range are heavily affected by auxiliary systems, particularly the Heating, Ventilation, and Air Conditioning (HVAC) system. This study investigates how ambient temperature variations and HVAC loads influence energy consumption, range, and efficiency in e-buses operating under diverse climatic conditions. The methodology combines field data collection from urban e-buses across seasons—including extreme summer and winter—with controlled lab testing. Field measurements included ambient temperature, HVAC demand, vehicle speed, state of charge (SOC) variation, and energy consumption. These inputs were used to develop real-world duty cycles, replicating actual thermal loads, passenger profiles, idling periods, and driving patterns. In the lab, these cycles were simulated using a chassis dynamometer and environmental chamber, with HVAC systems tested at controlled ambient temperatures
Vishe, PrashantDalela, SaurabhJoshi, MadhusudanSaraswat, Shubham
COMPUTATIONAL STUDY OF HYDROGEN BASED SCR TECHNOLOGY AS AN ALTERNATIVE TO UREA SCR IN HYDROGEN-FUELLED ENGINES2026-26-0213To be published on 01/16/2026
Air pollution from vehicle exhaust emissions is a growing issue in major cities around the world. Hydrogen is a clean and carbon-free fuel that presents a promising alternative to the fossil fuels. However, despite its environmental advantages, hydrogen internal combustion engines still produce some nitrogen oxides as a by-product due to high combustion temperatures. This study investigates the effectiveness of current exhaust after-treatment technologies designed to reduce NOx emissions in hydrogen-powered engines. A comparative analysis is conducted between the conventional urea-based selective catalytic reduction used in diesel engines and emerging hydrogen-based selective catalytic reduction technologies for hydrogen engines. The analysis is performed using CFD simulation in ANSYS Fluent, focusing on NOx reduction efficiency and other operational parameters. The results provide valuable insights into the feasibility and effectiveness of hydrogen SCR in achieving reduced NOx
KASHYAP, KESHAVKhandagale, AnupPetale, Mahendra
Methodology to model EMI from E-motors and controller in the frequency range from 30 to 200 MHZ2026-26-0524To be published on 01/16/2026
As EMC testing for E-motor drives gains significance due to the involvement of high-frequency switching and high current systems. The radiated emission testing as per CISPR 25 necessitates utilizing an EMC-proof dynamometer to load the E-motor drives during EMC testing inside EMC chamber, which presents a highly complex and expensive testing arrangement. This paper outlines a detailed approach for modelling radiated emission without the usage of such a complex arrangement, by measuring conducted high-frequency currents on the DC and AC lines of motors and MCUs while utilizing a non-EMC-proof motor dynamometer under loaded conditions. In this paper the measurements are conducted in the frequency range of 30 MHz to 200 MHz where usually more issues due to switching noise occurs. The developed model facilities early stage diagnosis of potential EMC issue, enabling mitigation strategies before motor EMC testing. Validation of the method was performed through experimental comparison with
M, GokulPatel, JinayMulay, Abhijit B
Multibody Dynamic Analysis of Belt-Type CVT Systems in Two-Wheelers: A Study on Slip, Misalignment, and Transmission Efficiency2026-26-0079To be published on 01/16/2026
More efficient drivetrain technologies are in greater demand in the two-wheeler market as a result of the introduction of BS6.2 emission standards. In order to satisfy these performance and regulatory requirements, Continuously Variable Transmission (CVT) systems—which are renowned for their stepless gear shifting and increased fuel efficiency—are being given more and more consideration. However, because CVT is nonlinear and multibody dynamic, accurately predicting its behavior is still a difficult task. With an emphasis on variables like belt slip, pulley misalignment, and transmission efficiency, this study provides a thorough multibody dynamic analysis of a belt-type CVT system used in two-wheelers. High-fidelity analysis of the belt-pulley interaction under various load and speed conditions is now possible thanks to the development of a novel modeling methodology using advanced multibody dynamics simulation software – Virtual Dynamics. The method makes early design validation
Shah, SwapnilMane, PrashantVoncken PhD, AntoniusEmran, Ashraf
Establishing a High-Pressure Direct Injection Hydrogen Engine Test Facility with Integrated Ammonia Fuel Capability: Technical Considerations, Safety Framework, and Best Practices2026-26-0267To be published on 01/16/2026
The transition toward zero-carbon propulsion technologies has highlighted the urgent need for specialized test infrastructure to support hydrogen and alternative fuel research. This paper presents the conceptualization, design, and operation of a High-Pressure Direct Injection (HPDI) Hydrogen Internal Combustion Engine (H2 ICE) test facility with integrated ammonia fuel testing capability, marking a significant advancement in India’s sustainable automotive research efforts. Drawing from practical experience, it outlines crucial technical specifications, safety protocols, and best practices for establishing robust, adaptable, and secure testing environments. Addressing the industry’s need for dedicated infrastructure, it is engineered for adaptability across various engine types—including heavy-duty, light-duty, and multi-utility vehicles—while aligning with global technical standards. Key technical considerations include the use of a transient dynamometer that features an advanced
Dhyani, VipinKurien, CaneonSubramanian, BalajiKhandai, ChinmayanandaMuralidharan, M
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 PhD, SuryanarayanaNarayanan, Siva Suriya
Study of real time impact on automotive cabin Air Quality due to the ambient air pollution in the severely polluted city2026-26-0531To be published on 01/16/2026
This study investigates the concentrations of PM2.5 and PM10 inside an automobile under real-world driving conditions in Delhi, one of the most polluted cities globally. India faces severe air pollution challenges in many cities, including Delhi, which are consistently ranking among the most polluted cities in the world. Major contributors to this pollution include vehicular emissions, industrial activities, construction dust, and biomass burning. Exposure to PM2.5 and PM10 has been linked to numerous adverse health effects, including respiratory and cardiovascular diseases, aggravated asthma, decreased lung function, and premature mortality. PM2.5 particles, being smaller, can penetrate deeper into the lungs and even enter the bloodstream, causing more severe health issues. In big cities like Delhi, long driving times exacerbate exposure to these pollutants, as commuters spend extended periods in traffic. Measurements were taken both inside and outside the vehicle to assess the real
Gupta, RajatPimpalkar, AnkitPatel, AbhishekKumar, ShubhamJoshi, RishiKumar, Mukesh
A systematic debugging methodology for identifying electric vehicle level EMC issues.2026-26-0525To be published on 01/16/2026
Electric vehicles present unique challenges in electromagnetic compatibility testing due to compact packaging, high-frequency switching systems. This paper presents a systematic debugging methodology for identifying radiated emission and radiated immunity issues in these EV platforms. A comprehensive approach is outlined, covering radiated emission measurement; Bulk Current Injection based immunity simulation, and near-field probing techniques. For RI evaluation, BCI testing in the 20 to 400 MHz range is used to simulate radiated threats on the vehicle's power and signal harnesses and handy transmitter near field injections for higher frequency simulation. For RE diagnosis, conducted emission measurements on vehicle harnesses are performed using current probes to capture high-frequency currents. Additionally, near-field electric probes are used at the component to identify dominant noise sources such as DC-DC converters, Motor control unit, and improperly grounded shielding. Case
M, GokulPatel, JinayMulay, Abhijit B
Technologies and Strategies for High Break Thermal Efficiency Gasoline Engine to Meet the Future CO2 Emission Targets in India2026-26-0072To be published on 01/16/2026
The Indian automobile industry is experiencing a significant shift, propelled by environmental necessities and national climate obligations set at the CoP26 summit, aiming for a 45% decrease in CO₂ emissions by 2030 and reaching carbon neutrality by 2070 [1]. Transportation continues to be a significant source of air pollution; consequently, India is enhancing its regulatory frameworks with BS VI Stage 2 regulations, CAFE Phase III norms set for 2027, and CAFE Phase IV by 2032 [2]. Furthermore, the transition from MIDC to WLTP driving cycle is meant to increase the accuracy of the efficiency and emissions assessments [2]. To comply to these upcoming regulations, the automotive industry is moving toward producing high efficiency engines in India. A naturally aspirated (NA) 1.5L, 4- cylinder inline gasoline engine was selected from Indian market for this study. Maximum Brake Thermal Efficiency (BTE) of this engine is around 35%. Assessment of new technologies were performed by
Garg, ShivamFischer, MarcusEmran, AshrafJagodzinski, BartoschFranzke, Bjoern
A Comparative Analysis of Passenger Car Fuel Economy between Laboratory and Real Driving Testing2026-26-0225To be published on 01/16/2026
In India, fuel economy is one of the most critical factors influencing a customer's decision to own a passenger car. Beyond consumer preference, fuel consumption also plays a significant role in the nation's energy security. Inline of this, the government promotes fuel-efficient vehicles and technologies through various regulations, policies, and mandates. Vehicle manufacturers, in response, focus on designing vehicles that align with both customer expectations and regulatory requirements. Fuel economy certification is typically based on standardized laboratory tests that simulate controlled environmental conditions, driving cycle (MIDC), vehicle load, and operation of electrical and electronic systems. However, actual on-road driving conditions by end user vary significantly due to factors such as traffic conditions, ambient temperature, air conditioning use, driving behaviour and variable loading of the vehicle. With implementation of Bharat Stage VI, Real Driving Emission (RDE
SINGH, ABHAY PRATAPBathina, Revanth KumarTijare, Shantanu
Performance Analysis of Hydrogen Fuel Cell Electric Vehicle for Intercity and Intracity Applications2026-26-0266To be published on 01/16/2026
Hydrogen Fuel Cell Electric Vehicles (FCEVs) are emerging as a sustainable solution to reduce greenhouse gas emissions in the transportation sector, in line with the Paris Agreement and global net-zero emission goals. This paper presents a comprehensive performance analysis of the FCEV powertrain under intercity and intracity driving conditions. The study focuses on key parameters such as fuel cell system efficiency, energy consumption, hydrogen usage, and overall drivetrain response. Using simulation models validated with real-world driving data, the performance of the powertrain is evaluated across varying speed profiles, vehicle loads, and driving cycles. The analysis also considers the impact of auxiliary load including HVAC systems and consumption of other electric components on the powertrain efficiency and energy balance. Results highlight that the FCEV powertrain performs efficiently during intercity driving due to stable speed conditions and low stop-start frequency, while
Patil, Nikhil N.Bhardwaj, RohitSaurabh, SaurabhAhmed, YasirGawhade, RavikantAmancharla, Naga ChaithanyaGadve, Dhananjay
Data-Driven Modeling for Hydrogen ICE Emission Prediction and ATS Performance Benchmarking2026-26-0386To be published on 01/16/2026
This study presents a novel methodology for benchmarking Hydrogen Internal Combustion Engine (H2E) emissions against diesel vehicle configurations, emphasizing Real-Drive Emission (RDE) test procedures. By leveraging Artificial Neural Networks (ANN) and Long Short-Term Memory (LSTM) models, emission profiles for legal cycles and RDE scenarios are predicted. Integrated data pipelines and physics-based modeling enable virtual evaluations of Selective Catalytic Reduction (SCR) system performance, ammonia dosing accuracy, and exhaust temperature dynamics. Key results demonstrate high prediction accuracy across models, including temperature (R² > 0.94, RMS error <25°C), air flow (92% accuracy, RMSE = 28 kg/h), upstream NOx (93% accuracy, RMSE <10 mg/s), and SCR (TP NOx accuracy = 85%, dosing accuracy = 90%). This approach significantly reduces the need for extensive on-road driving tests, as the model performs most of the work, thereby lowering development costs and supporting OEMs in
Shah, Jash VipinS, Manoj KumarRatnaparkhi, AdityaH, Shivaprakash
Electroluminescent Coating Systems for Heavy-Duty Trucks: Advancing Safety and Sustainability through Smart Surface Technology2026-26-0275To be published on 01/16/2026
As the transportation industry pivots towards safer and more sustainable mobility solutions, the role of advanced surface technologies is becoming increasingly critical. This paper presents a novel application of electroluminescent (EL) coating systems in heavy-duty trucks, exploring to enhance safety and environmental impact through lightweight, energy-efficient lighting integration. EL coatings, capable of emitting light uniformly across painted surfaces when electrically activated, offer a transformative alternative to conventional lighting systems and reflective materials. In the context of heavy-duty trucks, these systems can significantly improve visibility under low-light and adverse weather conditions, thereby reducing the risk of road accidents. Furthermore, illumination achieved without bulky fixtures and without interface gaps contributes to aerodynamic efficiency, fuel economy and reducing carbon emissions. use of this coating system, can optimize tooled up plastic part and
Harel, Samarth DattatrayaBorse, ManojL, Kavya
Migration from MIDC to WLTP in India: Challenges & Solutions for a Small Commercial Vehicle2026-26-0215To be published on 01/16/2026
In line with global peers (EU, Japan etc.), the Automotive Industry Standard (AIS) Committee in India has decided to adopt "World harmonized Light vehicle Test Procedure (WLTP)" for M and N category vehicles with GVW not exceeding 3500 kg. As a result, "World harmonized Light-duty vehicles Test Cycle (WLTC )" is set to replace currently applicable "Modified Indian Drive Cycle (MIDC)" in the next couple of years. The draft CAFE III & CAFE IV norms for CO2 emission limits, which are set to be implemented in 2027 and 2032 respectively refer to a shift to WLTP from MIDC. This migration to WLTP is in sync with the demand for test procedures to replicate real driving conditions more appropriately. Further, with the Indian automotive sector growing at a robust CAGR of ~9%, the move to WLTP along with stricter emission norms is going to help the government take a major step towards India's COP26 pledge to achieve net zero emissions by 2070. WLTC cycle being much more dynamic with higher
Pawar, BhushanEhrly, MarkusSandhu, RoubleEmran, AshrafBerry, Sushil
Development and Validation of a 1D Model for Evaluating Transmission Efficiency in Vehicles2026-26-0066To be published on 01/16/2026
This study develops a one-dimensional (1D) model to enhance transmission efficiency by evaluating power losses within a transmission system. The model simulates power flow and identifies losses at various stages such as gear mesh, bearing, churning, and windage losses. Using ISO/TR 14179, which provides a method for calculating the thermal transmittable power of gear drives with an analytical heat balance model, the 1D model ensures accurate thermal capacity evaluation under standard conditions. A key advantage of this 1D model is its efficiency in saving time compared to more complex 3D modelling, making it particularly useful during the conceptual stage of transmission system development. This allows engineers to quickly assess and optimize transmission efficiency before committing to more detailed and time-consuming 3D simulations. To validate the model, experimental tests were conducted at various motor speeds (RPM) and torque values, using high-precision sensors and dynamometers
Bandi, Nagendra ReddyKolla, KalyanP, SelvandranPULUGUNDLA, KRISHNA CHAITANYAM A, Naveen Kumar
Optimizing Engine Combustion and Exhaust After treatment System for Passive Regeneration in Off-Highway Applications2026-26-0221To be published on 01/16/2026
The Bharat TREM V regulations in the off highway segment mandates use of Diesel Oxidation Catalyst (DOC) to reduce gaseous emissions and Diesel Particulate Filters (DPF) to trap solid particulates from engine exhaust. DPFs undergo regeneration, where trapped soot is burned, converting it into CO2 with ash as a byproduct. Regeneration can be active, using fuel injection to raise temperatures above 550°C, or passive, relying on NO2 formation at 300-400°C. Passive regeneration is preferred as a safer mode for both DPF health and longevity as well as reduction in fuel penalty and oil dilution. This paper highlights on the selection and optimization of combustion hardware and Exhaust Aftertreatment System to achieve the desired NO2 formation which is suitable for passive regeneration. Key considerations in engine hardware selection include the design of piston bowl, injector hole configuration to increase heat release rate and combustion temperature resulting in higher NOx/soot ratio. With
Gautam, AmanRAWAT, SAURABHDogra, DaljitSinghSingh, SachleenRanjan, Piyush
Indian City Electric Bus Powertrain Optimization Using Active Learning Simulation Methodology2026-26-0657To be published on 01/16/2026
Public transport electrification is going to play a massive role in India's COP26 pledge to achieve net zero emissions by 2070. India plans to electrify 800,000 buses in a push towards 30% EV penetration by 2030. Further encouraged by government incentives under National Electric Bus Program (NEBP), eBus market is expected to grow at a CAGR of ~86% annually over the next 5 years. With most OEMs going for fleet electrification for reducing CO2 emissions and to cater to growing demand in Indian cities for cleaner public transport, improving powertrain efficiency and performance of state-of-the-art eBuses is a natural progression of e-mobility sector development in India. The first step in designing powertrain for an electric city bus is to determine the motor(s) size and transmission specifications (number of gears, gear ratios etc.). Complications arise due to a wider and non-linear operation range of eBus. This study focuses on powertrain optimization for a medium duty electric city
Emran, AshrafBerry, SushilXia, FeihongChen, BichengSandhu, Rouble
Comprehensive Engine Testing Methodologies for Hydrogen Internal Combustion Engine Validation with Combustion & Performance Evaluation techniques2026-26-0256To be published on 01/16/2026
Validation of hydrogen-fuelled internal combustion engine (H2 ICE) is critical to assess its feasibility as sustainable transportation with zero carbon emissions. This experimental analysis conducted on Ashok Leyland's 6cylinder 2V engine to evaluate the engine performance & durability with hydrogen fuel. Combustion behaviour of hydrogen ICE needs to be closely monitored during continuous operation of validation testing, due to its unique properties compared to other conventional fuels. During engine run, a pre-ignition source can cause knock event leading to instant failure of critical parts like piston assembly, spark plug, liner, valves & cylinder head. Also, hotspots inside IMF leads to backfire affecting the air intake & fuel injection assembly. This study emphasizes the significance of precise instrumentation of thermocouples across engine on cylinder head, intake manifold & exhaust manifold, to detect performance detoriation and combustion abnormalities causing knocking
Vasudevan, SindhujaJ, Narayana ReddyBolar, Yogesh GaneshPandey, SunilN, HarishN R, VaratharajKarthikeyan, KKumar D, Kishore
Study of Drive Trace Indices and their correlation with CO2 in Chassis Dynamometer testing2026-26-0517To be published on 01/16/2026
With introduction of CAFÉ norms in India, the manufacturers of all M1 Category vehicles (not exceeding 3,500kg GVW) must ascertain that they comply with Annual Corporate average CO2 target as defined in regulation. Moreover, this target will become stricter in different stages in upcoming years. Hence CO2 emissions are becoming one of the major focus parameters during vehicle development. There are various factors that can impact CO2 emissions during measurement in test cycle such as MIDC/WLTC. One such major factor is driving variations. Although speed and time tolerances are provided during the test (as part of AIS 137/AIS 175) limit the variation, even within these tolerances, drive-related effects can be significant contributors to test results variability. Monitoring and control of such variations is important to understand the true fuel economy potential of the vehicle. Drive Trace indices are standardized metrics that can be used to evaluate the driving variations. The aim of
ER, ShivramRawat, VijaypalKhandelwal, VineetKumar, ArunMalhotra, Jitendra
Emerging Trends in Emission Optimization2026-26-0229To be published on 01/16/2026
The exhaust emission control is a vital aspect of automotive development, aimed at ensuring effective control of pollutants such as NOx, CO, and HC. The traditional method of calibrating emission control strategies, that requires extensive vehicle testing with both the fresh and aged catalysts under a variety of operating conditions, is a time-consuming process. The frequent changes in emission legislation creates new challenges for achieving a faster time to market and effective utilization of resources. So, the use of automation and machine learning (ML) in the domain of emission control is the need of the hour to proactively tackle these challenges. This paper attempts to explore emerging trends in emission optimization, such as the automated measurement process and ML/AI based data analysis, that can improve the overall process efficiency in the calibration of emission control strategies. The automated measurement process is achieved using the automation software. The data
Dhayanidhi, HukumdeenBalasubramanian, KarthickA, Akash
Leveraging Advanced AI/ML Algorithms to Derive Actionable Insights from Fleet Vehicle In-Use Performance Ratio Monitoring (IUPRm) Data2026-26-0637To be published on 01/16/2026
In recent years, growing concerns over environmental pollution have led to the implementation of increasingly stringent emission regulations worldwide. These regulations require not only the reduction of pollutant emissions but also robust monitoring of critical emission control components under real-world driving conditions. The In-Use Performance Ratio Monitoring (IUPRm) framework quantifies how frequently onboard diagnostic systems evaluate these components within defined operational boundaries for each vehicle. IUPRm is organized into several monitoring groups, including catalyst monitoring, oxygen sensor monitoring, exhaust gas recirculation (EGR) monitoring, and gasoline particulate filter monitoring. The specific groups and monitoring requirements vary based on fuel type (gasoline or diesel), engine technologies (such as variable valve timing or EGR), and exhaust system configurations (single or dual bank). For automakers, analyzing these parameters across large vehicle fleets
Ghadge, Ganesh NarayanJadhav, MarishaHosur, Viswanatha
Flex-Fuel Technology for India: Challenges, Opportunities, and Compliance with Emerging Emission Norms2026-26-0109To be published on 01/16/2026
The adoption of flex-fuel vehicles (FFVs) in India presents a significant opportunity to reduce dependence on fossil fuels, lower greenhouse gas emissions, and ensure compliance with the country’s evolving emission norms. This paper explores the key aspects of flex-fuel technology in the context of Indian four-wheeler regulations, particularly Bharat Stage VI and potential future norms. The study begins with an overview of flex-fuel technology, detailing its advantages and associated challenges. A critical focus is placed on blend identification techniques, which play a vital role in optimizing combustion efficiency and ensuring seamless transitions between different ethanol-gasoline blends. Furthermore, the impact of ethanol blending on various fuel properties is examined, including changes in energy content, latent heat of vaporization, octane number rating, and stoichiometric air-fuel ratio. These factors significantly influence engine performance and emission characteristics
Balasubramanian, KarthickKR, PrabhakarKALLAHALLI SOMU, SANTHOSH KUMAR
Optimizing Diesel Emission Controls through Advanced Software techniques to improve Diesel Oxidation Catalysts efficiency2026-26-0061To be published on 01/16/2026
After the implementation of BS VI emission standards, effective exhaust after-treatment has become critical in minimizing harmful emissions from diesel engines. One significant challenge is the accumulation of hydrocarbons (HC) in the Diesel Oxidation Catalyst (DOC). Certain hydrocarbons may adsorb onto the catalyst surface yet remain unreactive, leading to potential operational inefficiencies. This phenomenon necessitates the desorption of unreactive hydrocarbons to allow space for more reactive species, thereby enhancing oxidation efficiency and overall catalyst performance. The process of desorption (DeSorb) is vital to maintaining the balance of reactive hydrocarbons within the DOC. When a vehicle is idling or low temperature duty cycles, unburnt fuel produces hydrocarbons that accumulate in the DOC. Upon acceleration, these hydrocarbons can lead to an uncontrolled rise in temperature, resulting in DOC push-out, catalyst damage, and downstream impacts on the Diesel Particulate
K, SabareeswaranK K, Uthira Ramya Balak, JanarthananA, RavikumarYS, Ananthkumar
Reverse Engineering and Digital Twins in Powertrain Design: Enhancing Performance and Sustainability2026-26-0065To be published on 01/16/2026
This study explores the application of reverse engineering (RE) and digital twin (DT) technology in the design and optimization of advanced powertrain systems. Traditional approaches to powertrain development often rely on legacy designs with limited adaptability to modern efficiency and emission standards. In this work, we present a methodology combining 3D scanning, computational modeling, and machine learning to reconstruct, analyze, and enhance internal combustion engines (ICEs) and electric vehicle (EV) drivetrains. By digitizing physical components through RE, we generate high-fidelity DT models that enable virtual testing, performance prediction, and iterative improvement without costly physical prototyping. Key innovations include a novel mesh refinement technique for scanned geometries and a hybrid simulation framework integrating finite element analysis (FEA) and multi-body dynamics (MBD). Our case study demonstrates a 12% increase in thermal efficiency for a retrofitted ICE
Bernikov, Mark AlexandrovichKurmaev, Rinat
Legislative Framework and Emission Testing using PEMS for NRMM (Non-Road Mobile Machinery) in India: A Technological Perspective2026-26-0139To be published on 01/16/2026
Emission Regulations for NRMM in India have evolved significantly over past two decades. India has progressively adopted stricter standards to align with global best practices. The latest regulations have introduced stringent caps on particulate matter (PM), nitrogen oxides (NOx), and other pollutants, ensuring compliance with environmental sustainability goals. Future legislative frameworks are expected to impose even more rigorous emission limits, focusing on further reduction of NOx and PM levels while incorporating real-world emission monitoring. This will require manufacturers to integrate advanced after-treatment systems and adopt cleaner combustion technologies to meet compliance standards. To validate compliance with these stringent limits, rigorous testing methodologies are employed. Portable Emission Measurement Systems (PEMS) have become a crucial tool for real-world emission assessment. PEMS technology allows for on-road and field testing of NRMM under actual operating
Rastogi, AadharGarg, VarunRagot, Nicolas
A comprehensive strategy for Diesel Particulate Filter calibration to address the diverse applications of Stage V Construction Equipment Vehicles.2026-26-0143To be published on 01/16/2026
The legislation of CEV Stage V emission norms has necessitated advanced Diesel Particulate Filter calibration strategies to ensure optimal performance across diverse construction equipment applications in the Indian market. Considering the various duty cycles of cranes, backhoe loaders, forklifts, compactors, graders, and other equipment, different load conditions and operational environments require a comprehensive strategy to enhance DPF efficiency, minimize regeneration frequency, and maintain compliance with emission standards. The DPF, as an after-treatment system in the exhaust layout, is essential for meeting emission standards, as it effectively traps particulate matter. Regeneration occurs periodically to burn the soot particles trapped inside the DPF through ECU management. Therefore, understanding soot loading and in-brick DPF temperature behavior across various applications is the key. This paper explores the challenges in DPF calibration for CEV Stage V and provides a
Mohanty, SubhamChaudhari, KuldeepakPatil, LalitMahajan, AtishMadhukar, Prahlad
Optimizing Powertrain Performance: A Customer Usage-Centric Approach2026-26-0067To be published on 01/16/2026
The optimization of new generation trucks is crucial for enhancing performance, efficiency, and compliance with regulatory standards. In the conventional product development, the manufacturer often optimises the powertrain to meet the stringent emission which might not account for the customer usage. This study uses the simulation-based approach that integrates customer usage with help of logged vehicle data across various applications, to develop a single engine platform equipped with multiple drivetrain options. Using a data driven approach, real-world usage pattern analysis is conducted to identify key performance metrics required to optimize the driveline components tailored to each application. Additionally, the impact of certification requirements on vehicle performance is examined to ensure compliance while maximizing the benefits of the proposed optimization strategies. The findings of this research will provide valuable insights for manufacturers and fleet operators, enabling
Mohan, VigneshDarzi, Mahdi
Revolutionizing Urban Mobility in India: The Emergence of the 2-3 Wheel Combi Vehicle and the L2-5 Regulatory Framework.2026-26-0187To be published on 01/16/2026
Urban mobility in India is evolving rapidly under the pressures of population growth, increasing congestion, and the demand for innovative transportation solutions. With infrastructure development and urbanization accelerating, there is a growing need for versatile vehicles that can adapt to both personal and commercial purposes while addressing urban vehicle density. To meet this demand, the 2-3 Wheel Combi Vehicle has emerged as a groundbreaking modular mobility solution, enabling seamless transitions between two-wheeled (2W) and three-wheeled (3W) configurations. This is world's 1st class changing vehicle, exemplified by Hero's SURGE. It offers a single, multi-functional platform that supports agile urban mobility, e-commerce deliveries, and income generation. This innovation is underpinned by India's pioneering and newly created L2-5 category, a unique regulatory framework established by the Ministry of Road Transport & Highways (MoRTH) under the Central Motor Vehicle Rules (CMVR
Ali Khan, FerozGupta, Eshan
Design & Optimization of CV shaft system to address powertrain induced NVH issues2026-26-0336To be published on 01/16/2026
The automotive industry is a crucial sector that plays a significant role globally. Government policies have a profound impact on this automotive industry in defining the regulatory standards and emission controls. Such regulations incentivized automakers to invest in research and development complying those standards towards reduction of vehicle emission which intern result in higher torsional vibrations and excitations amplitudes. To address the rising NVH related concerns in driveline system. Drive shafts (CV shafts) is an important component in power-train system in vehicle. Drive shaft’s main purpose to transfer torque from engines to wheels at multiple speeds with different articulation angles. The roughness generated by the engine follows a transfer path from engine to transaxle and transaxle to half shafts in monocoque vehicles which generates discomfort to the drivers whenever the vehicle is driven. The roughness can also be addressed by proper design of driveshaft stiffness
M A, Abdul AzarrudinJayachandran, Suresh kumarKUMAR, ShivaniBhardwaj, KinshukM, DevamanalanKanagaraj, Pothirajahire, Manoj
Vehicle interior material emissions and contributions in passenger vehicle cabin air quality2026-26-0287To be published on 01/16/2026
Polymer compounds used in the manufacturing of automotive interiors are formulated with various kind of additives, pigments, fillers, and resins. These compounded polymers are prone to the emission of chemicals called volatile organic compound (VOC) over a period of usage, temperature exposure etc. VOCs include a variety of chemicals, some of which may have short term adverse health effects like nausea, headache, vomiting, and long-term adverse health effects like cancer, even death if beyond the permissible limits. Studies indicates the concentrations of many VOCs are consistently higher in indoors (up to ten times higher) than outdoors and hence these chemical emissions are required to be controlled within the defined limits. This paper is focused on the identification part and material, evaluation against the recommended test (Odor/Fogging/VOC/Carbonyl compound emissions) and development of materials used inside the car cabin. This study further provides the guidelines for the
Shukla, Sandeep KumarBalaji, K VVaratharajan, Senthilkumaran
Enhancing Thermal Comfort and Vehicle Energy Efficiency: A Simulation Study Using GT ISE + TAITherm2026-26-0458To be published on 01/16/2026
The automotive industry is encountering difficulties in balancing occupant thermal comfort with HVAC system energy efficiency, particularly under the hot Indian conditions, to meet user expectations and address range anxiety in electric vehicles. Front-loaded comfort-based approach simulations during the development stages have the potential to increase energy savings compared to the stages required at the end of product design. The focus of the current research targets HVAC energy consumers, such as blower flow rates, temperatures, and Cabin heaters, and investigates how these factors influence occupant overall comfort. Additionally, design elements like glass properties and the impact of solar radiation on human comfort are studied at the early concept stages to adopt an energy-based approach for comfort optimization. Simulations are conducted using GT-SUITE and GT-TAITherm software, integrated with CFD field maps platforms to obtain exact flow field predictions. The simulation
BAVIRISETTI, SAI SAMPATH KUMARChothave, AbhijeetGummadi, GopakishoreKhan, ParvejThiyagarajan, RajeshRaju, KumarA Sr, Mahesh
The Aerodynamic development of a Compact SUV for FE improvement and compliance with CAFE norms2026-26-0595To be published on 01/16/2026
The Mahindra 3XO is a compact SUV, the first-generation was introduced by Mahindra in 2018. This paper explores some of the challenges entailed in developing the next generation of this successful product, maintaining exterior design cues while at the same time improving its aerodynamic efficiency. A development approach is outlined that made use of both CFD simulation and Coastdown testing at MSPT (Mahindra SUV proving track). Drag coefficient improvement of 40 counts (1 count = 0.001 Cd) can be obtained for the best vehicle exterior configuration by paying particular attention to: • AGS development to limit the drag due to cooling airflow • Front wheel deflector optimization • Mid underbody cover development (beside the LH & RH side skirting) • Wheel Rim optimization • Rear wake control strategy In this paper we have analysed the impact of these design changes on the aerodynamic flow field, Pressure plots and consequently drag development over the vehicle length is highlighted. An
Vihan, Nikhil
Electric mobility and materials circularity - a study of recycled PET textiles for automotive interiors2026-26-0237To be published on 01/16/2026
The adoption of sustainability in electric mobility has made it crucial to investigate environmentally friendly materials. Polymer materials used in automotive application plays very important role in material circularity contributing significant value addition to the overall carbon footprint index. This study discloses the development of recycled polyester textiles from PET bottle waste, use for automotive interior parts and carbon footprint impact. The use of recycled textiles is directly helping the organization in scope 3 emissions to get the lower carbon footprint value by eliminating the use of fossil fuel resources in making the PET textiles. In this study, the development road map methodology adopted, and validation cycle of recycled polyester textiles (PET) were explained broadly with results of different constructions, color and finishes against automotive critical requirements such as sun load UV resistance, abrasion durability, color migrations, soiling resistance
Palaniappan, ElavarasanVaratharajan, SenthilkumaranBalaji, K VDodiya, Rohanbhai
A study on the thermal degradation of chlorinated Polyethylene rubber2026-26-0276To be published on 01/16/2026
Elastomeric materials are essential in advanced automotive engineering for mobility, isolation, damping, fluid transfer (cooling, steering, fuel, and brake), and sealing because of their unique physio mechanical properties. Elastomers are commonly used in both static and dynamic components, such as hoses, mounts, bushes, and tires. Engine emission standards and weight optimization have caused higher temperature exposure conditions for automotive components. The steering system uses special purpose elastomers like Chlorinated Polyethylene that can deteriorate under abnormal conditions during vehicle operation or manufacturing process due to the high temperature exposure. Therefore, it is crucial to comprehend the causes and consequences of thermal degradation of elastomers. Thermal degradation is a significant phenomenon that changes the physical and chemical properties of elastomers, which results in a product not meeting functional requirements. This study investigates the thermal
THIRUPPATHI, ANANDHIMishra, NitishKrishnamoorthy, Kunju
Optimization of Battery Mixing Strategies to Enhance Electric Vehicle Performance and Efficiency2026-26-0209To be published on 01/16/2026
Fleet operators increasingly contend with a patchwork of battery‑pack generations that remain electro‑chemically compatible yet differ markedly in capacity, internal resistance and residual life. Conventional “like‑for‑like” replacement policies oblige service providers to retain costly legacy inventories or to install brand‑new packs in ageing vehicles—both scenarios inflating warranty exposure and material waste. Deploying a rational mixing strategy for packs of different vintages therefore offers a compelling path to lower costs and improve sustainability, but industry‑wide guidance is limited and confidence in performance impacts remains low. This paper presents an optimisation‑driven framework that determines when and how heterogeneous packs can be paired at the moment of integration while maintaining vehicle performance targets and minimising life‑cycle cost. The methodology combines: a physics‑based electro‑thermal performance model parameterised for discrete state‑of‑health
Nair, Sandeep R.Ravichandran, Balu PrashanthHallberg, Linus
Vibration modelling of high-pressure fuel lines driven by pressure pulsation.2026-26-0319To be published on 01/16/2026
When the flow of fluid within a high-pressure line is abruptly halted, pressure pulsations are generated. This phenomenon is known as the water hammer effect. This may lead to significant stress and, in the worst-case scenario, result in various types of failures within the highly pressurized system. Similar issue is observed in diesel high pressure fuel line where pressure is well above 1600 bar. Due to multiple injection on off event, pressure pulsation gets created inside high pressure fuel lines (HPFL) which leads problems such as high strain on high pressure fuel lines, mechanical damage, uneven fuel injected quantity, vibration beyond specification limits for rail pressure sensor or in worst case extreme noise. Due to pressure pulsation, fluid will have its own natural frequency, and resonance occurs when it interacts with structural frequency. In this work, A comparative FEA analysis is conducted to evaluate strain in two distinct high-pressure fuel lines, with pressure
Bawache, Krushna RameshSethy, Girija Kumari
All New 1.2L Turbocharged Gasoline Direct Injection Engine from Tata Motors2026-26-0071To be published on 01/16/2026
A continuous stress on meeting stringent emissions regulations alongside rising consumer expectations for enhanced driving performance and refinement on powertrain applications on passenger cars. To address this customer aspirations Tata Motors has engineered the advanced 1.2L 3-cylinder turbocharged gasoline direct injection engine HYPERION. This next-generation powertrain is designed to maximize efficiency, lower emissions and deliver superior performance with improved noise, vibration, and harshness (NVH) characteristics. Key innovations includes highly optimized fuel injectors injector operating at 35 MPa, CVO-3 (3rd Gen Controlled Valve Operation), Miller Cycle with Electrically actuated VGT turbocharger and an AI-enabled engine management system, which collectively enhances efficiency and performance. The exhaust after-treatment system incorporates a Three-Way Catalyst (TWC) and an integrated Four-Way Conversion Catalyst (FWC+TM) for efficient emission control. The BS6 phase 2
Hosur, ViswanathaGhadge, Ganesh NarayanJoshi, ManojJadhav, AashishPanwar, Anupam
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