Browse Topic: Fuels and Energy Sources

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Flow-Based Corrosion Analysis of NBR-PVC Fuel Hoses in Ethanol-Gasoline Blends2026-28-0079To be published on 02/12/2026
The integration of ethanol into gasoline presents compatibility challenges for automotive fuel system materials. This study examines the degradation of NBR-PVC fuel hoses exposed to ethanol-gasoline blends (E30, E50, E70, and E100) under dynamic flow conditions. A custom-designed test rig simulates real-time fuel circulation for 1,200 hours. Analysis using FESEM, ATR-FTIR, and elemental mapping identifies ethanol-induced degradation, including dehydrochlorination, plasticizer leaching, and filler detachment. Among the blends, E30 exhibits the least material degradation, while E100 shows significant surface damage and chemical alteration. The study recommends multilayered fuel hose structures with ethanol-resistant inner linings for enhanced durability.
PC, MuruganL S, AdhityaG, Arun PrasadW, Beno WincyT, Karthi
Enhancing combustion, performance and emission profiles using kapok methyl ester blends with hydrogen2026-28-0058To be published on 02/12/2026
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, BM, KUMARESANBalamurugan PhD, SRajesh, Munnusamy
Dual use of Electric Vehicle infrastructure for Enhancing Grid Resilience and Urban Sustainability2026-28-0114To be published on 02/12/2026
The rapid global adoption of Electric Vehicles (EVs) has led to a surge in the deployment of EV charging stations. Beyond their primary role of vehicle charging, these stations hold potential as dynamic, grid-connected assets for sustainable cities and communities (SDG 11). When integrated with renewable energy sources such as wind or solar, EV charging stations can function as decentralized power units, supplying energy to the grid during times of need. This dual functionality allows them to act as flexible loads that mitigate voltage fluctuations during grid faults, facilitating access to reliable energy (SDG 7). Utilizing existing EV infrastructure in this way reduces the need for additional grid-support devices and supports resource efficiency (SDG 13) promoting a low-carbon energy transition. However, their ability to support the grid is limited when fully committed to meeting charging demands, especially during grid faults. To address this challenge, a novel coordinated operation
R, UthraRangarajan, RaviD, SuchitraD, Anitha
Enhanced Solar Desalination Using Natural Dolomite-Integrated PCM and MWCN Thermal Storage: An Experimental Study2026-28-0082To be published on 02/12/2026
Systems for solar desalination provide a practical and environmentally friendly way to turn salty or polluted water into drinkable water. Three configurations are experimentally investigated in this study: a traditional solar desalination system, a system integrated with a thermal energy storage unit (TESU) based on phase change material (PCM), Multi wall Carbon nano particle were mixed with PCM at 1% of total volume of the PCM and a system that incorporates powdered natural dolomite into the PCM-based TESU. Each of the four configurations was created, tested simultaneously, and thoroughly examined. In comparison to the traditional system, the experimental findings showed that the adoption of PCM-based TESUs increased daily cumulative water output by 11.41%, 14.8% with addition of MWCNT and the addition of dolomite powder further increased productivity by 18.60%. Furthermore, the energy efficiency increased by16.1% with PCM, PCM with MWCNT is increased by 17.43% and 18.18% with the
R L, KrupakaranPetla, RatnakamalaAnchupogu, PraveenP, UmamaheswarraoSATYA MEHER, RDunna PhD, Vijay
Development of Plug-in Hybrid Motorbike and Analysis towards Sustainable Urban Mobility2026-28-0111To be published on 02/12/2026
The transportation system is one major catalyst to urban ecological imbalance. In developing countries, two-wheelers are considered a major mode of urban personal transportation because of their compactness, easy maneuver in heavy traffic and good fuel efficiency. In India, middle and lower middle-class people prefer to choose two wheelers and these vehicles are dominantly fueled by gasoline. Although, the energy consumption by a two-wheeler is comparatively less than that of a four-wheeler, they use about 60% of the nation's petroleum for on-road vehicles and the impact on urban air quality and climatic change is significantly high. This high proportion of gasoline utilization and emission contribution by two wheelers in cities demand greater attention as a way to improve urban air quality and near-term energy sustainability. Electrification of two-wheelers through the application of a plug-in hybrid idea is a promising solution. A plug-in hybrid motorbike was developed by putting
Kannan, PrashanthShaik, AmjadTalluri, Srinivasa Rao
Multi-Objective Optimization of WAAM for Sustainable Production of Automotive-Grade Components2026-28-0030To be published on 02/12/2026
Wire Arc Additive Manufacturing (WAAM) has emerged as a promising technology for fabricating large-scale metal components with reduced material waste and lead time, aligning with the goals of sustainable manufacturing. This study presents a multi-objective optimization approach for WAAM to enhance both the manufacturing efficiency and sustainability of automotive-grade components. Key process parameters such as travel speed, wire feed rate, and current were systematically varied to evaluate their impact on dimensional accuracy, mechanical performance, and energy consumption. A statistical design of experiments framework was employed, and multiple performance objectives were optimized simultaneously using suitable decision-making techniques. The results demonstrate that optimized WAAM settings not only meet structural and functional requirements for automotive applications but also contribute to material and energy savings. This approach supports the integration of sustainability into
Pasupuleti, Thejasree
CFD Simulation of Combustion and Emission Characteristics of Pure Spirulina Microalgae Biodiesel in a Single-Cylinder DI Diesel Engine2026-28-0043To be published on 02/12/2026
This study examines the combustion and emission characteristics of pure Spirulina microalgae biodiesel (B100) in a single-cylinder direct-injection (DI) diesel engine using computational fluid dynamics (CFD) in ANSYS Fluent. A 2D axisymmetric sector model of the engine was developed and simulated with a moving mesh to capture dynamic piston motion throughout the engine cycle. The Discrete Phase Model (DPM) was applied to simulate spray atomization and droplet evaporation, while a non-premixed combustion model and RNG k-ε turbulence model were used to resolve in-cylinder combustion dynamics. The thermophysical properties of Spirulina biodiesel were defined from literature data to accurately model fuel injection, vaporisation, and ignition phenomena. The study focused on analysing in-cylinder pressure, temperature, and emission characteristics such as NOx, CO, and soot, and compared the results with those of conventional diesel fuel. Simulation results indicated that Spirulina biodiesel
Kumar, B Varun
Intelligent Steering System to Improve Fuel Efficiency in Heavy Duty Vehicles2026-28-0103To be published on 02/12/2026
In commercial vehicles, conventional engine-driven hydraulic steering systems result in continuous energy consumption, contributing to parasitic losses and reduced overall powertrain efficiency. This study introduces an Electric Powered Hydraulic Steering (EPHS) system that decouples steering actuation from the engine and operates only on demand, thereby optimizing energy usage. Field trials conducted under loaded conditions demonstrated a 3–6% improvement in fuel economy, confirming the system’s effectiveness in real-world applications. A MATLAB-based simulation model was developed to replicate dynamic steering loads and vehicle operating conditions, with results closely aligning with field data, thereby validating the model’s predictive accuracy. The reduction in fuel consumption directly translates to lower CO₂ emissions, supporting regulatory compliance and sustainability goals, particularly in the context of tightening emission norms for commercial fleets. These findings position
T, Aravind Muthu SuthanMani, KishoreAyyappan, RakshnaD, Senthil KumarS, Mathankumar
AI Smart Timer-Based Power Control and Energy Monitoring System for Home Appliances2026-28-0060To be published on 02/12/2026
This paper presents an intelligent home automation system that combines timer-based power control, real-time energy monitoring, and cloud-based AI analytics for individual appliances. The system is built using a Wi-Fi-enabled embedded controller connected to sensing circuits that measure voltage, current, and power consumption. Electromechanical relays are used to control appliance power based on user-defined timers. Users can configure either a fixed runtime or a scheduled cutoff, enabling automated energy-saving without manual input. Alongside local control, the system collects energy consumption data and transmits it to a cloud platform for storage and analysis. A dedicated mobile or web app provides live monitoring, device status, and remote control access. A major innovation is the integration of a cloud-based AI engine that processes historical and real-time data to offer predictive insights. The AI module forecasts energy use, detects anomalies, classifies appliances by behavior
D, AnithaD, SuchitraJain, UtsavMAITY, SOUVIKDinda, Atish
Development of Multiple level Auto Mode for Climate control in electric vehicles2026-28-0008To be published on 02/12/2026
Electric vehicles, or EVs, are significantly transforming the automotive industry as a cleaner and more environmentally friendly which finds an alternative solution for the vehicles propelled using internal combustion engines. As EV utilize the energy directly from the battery which causes customer or a user to be in panic state as charging infra is not developed well in most of the countries, thus improving vehicle efficiency and driving range requires optimizing energy consumption from battery of EVs. Apart from traction motor load for driving, major supplemental loads in electric car are climate control system, sometimes referred to as HVAC (Heating, Ventilation, and Air Conditioning). HVAC systems can consume a lot of battery power, especially during severe temperatures, which can drastically reduce the vehicle's range. Range anxiety continues to be an important barrier to the general adoption of EVs, the intelligent climate management systems which helps to reduce HVAC power usage
Mulamalla, Sarveshwar ReddySV, Master EniyanM, NisshokAnugu, AnilE A, MuhammedGuturu, Sravankumar
Design evolution of novel rear sub frame structure for multilink suspension and electric vehicle platform2026-28-0007To be published on 02/12/2026
As there is a major shift in customer demand for energy efficient transportation electric vehicle development has taken immediate significance worldwide as they provide pollution free, noise free mobility environment. In the current work, the authors evaluate novel Rear sub-frame assembly structure with multilink suspension and further for a born electric vehicle platform with increased rear axle weight contribution due to rear motor and battery weight. The Sub Frame is the important structural component of the chassis system. Hence designers face the challenge of providing a best-in-class optimized Rear sub-Frame in terms of cost and weight within the available vehicular boundary. Rear sub-Frame assembly is designed with unique cross member structure and novel motor mounting arrangement on the side member with the given complex hard points or attachments of the suspension linkages, to meet the electric vehicle packaging requirement. Sub frame is designed with light weight to withstand
Nidasosi, Basavraj MarutiJ, RamkumarNAYAK, BhargavMANI, ARUNM, Sudhan
Innovative Preconditioning Solutions for Efficient High-Current Battery Charging2026-26-0167To be published on 01/16/2026
In high-performance charging systems, managing higher currents is crucial for efficient battery charging. However, elevated battery and charging gun pin temperatures pose significant challenges, limiting the duration and effectiveness of high-current charging. Our advanced control system addresses these barriers by optimizing charging time while maintaining optimal temperature ranges for both the battery and charging gun. This is achieved through innovative preconditioning solutions that incorporate both active and passive cooling configurations. Our system features a unique preconditioning approach with dedicated cooling circuits for the charging socket and battery. The passive liquid cooling system ensures effective temperature management without additional energy consumption, while the active liquid cooling system provides enhanced cooling capabilities for more demanding scenarios. By integrating these cooling configurations, our control system significantly reduces charging time
Badgujar, Pankaj RavindraBhosale, SubhashDave, Rajeev
Performance Evaluation and Optimization of Engine Brake System using Chassis Dynamometer2026-26-0511To be published on 01/16/2026
Engine braking is a deceleration technique that leverages the internal friction and pumping losses within the engine. By closing the throttle and potentially selecting a lower gear, the engine creates a retarding force that slows the vehicle. This practice contributes to better fuel economy, decreased brake system load, and improved vehicle handling in specific driving scenarios, such as steep declines or slippery road surfaces. To alleviate stress on their primary braking systems and prevent overheating, heavy vehicles frequently incorporate engine-based braking. While older trucks relied on simple exhaust brakes with a butterfly valve to restrict exhaust flow, these had limited impact. Hence contemporary heavy vehicles almost exclusively use more advanced engine braking technologies. Traditionally, our heavy-duty vehicles use Exhaust brake system to elevate the braking performance on hilly terrains. Hence an improved sample of Engine brake was developed for enhanced braking
M, Vipin PrakashRajappan, Dinesh KumarR, SureshN, Gopi Kannan
Drive Cycle Based Energy Audit & Range Estimation for 4X2 Electric Truck2026-26-0163To be published on 01/16/2026
Transportation sector in India accounts for 18% of total energy consumption. Demand of energy consumption is being met by the imported crude oil, which makes transportation sector more vulnerable to fluctuating international crude oil prices. India is mindful of its commitment in 2016 Paris climate agreement to reduce GHG emissions by 35% by 2030 as compared to 2005 levels. To fast track the decarbonization of transportation sector, commercial vehicle manufacturers have been exploring other viable options such as battery electric vehicles (BEVs) as a part of their fleet. As on today, BEV has its own challenges such as range anxiety & high total cost of ownership. Range anxiety can be certainly addressed by optimum sizing of electric powertrain, reduction in specific energy consumption (SEC) & use of effective regeneration strategies. Higher SEC can be more effectively addressed by doing vehicle energy audit thereby estimating the energy losses occurring at each powertrain component of
Gijare, SumantKarthick, K.Juttu, SimhachalamThipse, Sukrut S.A, JothikumarJ, Frederick RoystonSR, SubasreeG, HariniM, Senthil Kumar
A strategic approach to the selection of switchgear and busbars for EV battery packs2026-26-0165To be published on 01/16/2026
With the rising adoption of electric vehicles (EVs), the need for robust and efficient power distribution systems has become increasingly important. This paper outlines a strategic method for selecting switchgear and busbars in EV battery packs, emphasizing key factors such as safety, energy efficiency, thermal control, and future scalability. Proper optimization of these components can significantly improve performance, minimize power losses, and ensure durability under demanding operating conditions. The design and selection of battery conducting components, such as switchgears and busbars, are typically based on the maximum continuous and peak current capabilities of the EV battery pack. While this approach ensures that the components can withstand extreme conditions, it often leads to over-engineering, resulting in unnecessary costs and added weight. However, this method overlooks the dynamic power demands of the vehicle, which fluctuate based on driving conditions and usage. Real
Soman, Anusatheesh, GouthamK, Mathankumar
First in the Industry 8.5 Ton GVW on Four Tyre Truck with 245/90R16 Tyre – A Global First2026-26-0602To be published on 01/16/2026
This project introduced a brand-new tire size—245/90R16—for the first time globally in the 16-inch tube-type category, designed specifically for commercial vehicles with Vehicles 8.5T -14T gross vehicle weight (GVW). The main goal was to create a compact vehicle that can carry more payload, reduce overall weight, and improve fuel efficiency with use of rear single tyre instead of twin tyre in 8.5T. This helps customers lower their operating costs and improve vehicle performance, especially on narrow roads. The new tire supports high load capacities: up to 2300 kg for single tire use and 2180 kg for dual tire fitment. It enables a new type of vehicle to be developed—an 8.5-ton GVW vehicle with rear single tires—offering better payload capacity without increasing the size of the vehicle. By using this new tire, the kerb weight of the vehicle is reduced, which increases the payload and helps improve fuel economy. It also helps lower the cost of the vehicle by allowing the use of lighter
Pawar, Dhondiram DnyandeoShaikh, MatinAmbekar, Prasad
Optimizing Busbar Design by Investigating Critical Parameters and Their Influence on Electrical and Thermal Behaviors for Reliable Electric Vehicle Battery Packs.2026-26-0474To be published on 01/16/2026
With the rise of EVs, researchers are focusing on optimizing busbar design to meet the demands of high energy density, fast charging, and compact battery packs. The busbar design starts with selecting the cross-sectional area based on current-carrying capacity and material type. The width matches or exceeds the battery cell terminal size, while the length is optimized based on space constraints. The research also highlights the risk of busbars to oxidation and corrosion, which increases resistance and decreases thermal conductivity for which Plating and coating techniques are applied to improve surface hardness, durability, and thermal conductivity while minimizing heat loss. Using simulations and experimental validation, the study examines three key design parameters: weld diameter, electrical resistance, and contact resistance. A detailed analysis investigates how weld diameter influences electrical resistance and temperature rise, as well as the impact of contact resistance between
Nogdhe, YogeshSingh, Shobit KumarPaul, JibinMishra, MukeshMenon, Praveen
Transforming Gear Manufacturing_ A Deep Learning Approach to Quality Prediction2026-26-0646To be published on 01/16/2026
The automotive industry is rapidly transitioning towards Industry 4.0, transforming vehicle manufacturing. To achieve a lower carbon footprint, it is crucial to minimize raw material wastage and energy consumption. Reducing component wastage, lead time, and automating gear manufacturing are key areas. Gear micro-geometry inspection is vital, as variations affect service life and NVH (Noise, Vibration, Harshness). Despite standards for permissible errors, manual evaluation is often needed.This subjective evaluation approach will have a possibility that a gear with undesired variations gets assembled into the product. These issues can be detected during NVH testing, leading to replacement of part and re-assembly thus increasing lead time. This generates a need for an automated system which could reduce the human intervention and perform the activity. This paper discusses methodologies to meet these requirements and achieve desired results. The research aims to develop a deep learning
Ramakrishnan, Gowtham RajBaheti, PalashPR, VaidyanathanDurgude, RanjitBathla, ArchanaR, GreeshmitaV, Rangarajan
Data-Driven Prediction of Global Automotive Trends: Forecasting Fuel Economy and CO₂ Emissions Using Machine Learning2026-26-0643To be published on 01/16/2026
In the pursuit of cleaner transportation and environmental sustainability, the global automotive industry is undergoing rapid transformation. This study leverages historical multi-decade vehicle data to develop predictive models for fuel economy and CO₂ emissions across a wide range of vehicle technologies. By utilizing advanced machine learning algorithms in Python and integrating insights through Power BI visualizations, the project identifies key correlations between vehicle attributes—such as weight, powertrain, and footprint—and their environmental performance. Results highlight the increasing impact of electric vehicle adoption, hybridization, and light weighting on overall emissions reduction. These insights help forecast the direction of fuel economy standards, emission patterns, and technology shifts across manufacturers and vehicle types. Beyond technical predictions, the study offers a decision-support framework for global policymakers, automotive designers, and
Hazra, SandipTangadpalliwar, SonaliHazra, Sanjana
Next-Gen Driver Health and Wellness Platform for Fatigue Detection and Emotional Wellbeing Monitoring2026-26-0639To be published on 01/16/2026
Driver fatigue and emotional distress are major contributors to traffic accidents, especially among long-haul and professional drivers, making their detection a critical area in road safety and public health. While existing research has explored various sensor-based and wearable solutions to monitor driver states, these approaches often suffer from high cost, intrusiveness, or limited scalability. Camera-based systems have recently gained attention for being less invasive and more practical for real-world deployment; however, many still depend on multiple sensors or cloud-based processing, which raise concerns around energy consumption, privacy, and integration complexity. To address these gaps, we present a sustainable, camera-only Driver Health and Wellness Platform for real-time fatigue detection and emotional wellbeing monitoring. The system leverages a single in-cabin camera and applies lightweight, edge-optimized computer vision models to analyze facial features, eye dynamics
Iqbal, ShoaibImteyaz, Shahma
Qualitative and Quantitative Correlation Study for Exterior Aerodynamics for Automotive Vehicle2026-26-0407To be published on 01/16/2026
The objective of the exterior aerodynamic performance assessment of automotive vehicles is to reduce the aerodynamic drag pressure and rear side wake zone, which improves overall energy consumption of the vehicle. Almost 30 to 40% of the energy is required to overcome the drag force and wake zone pressure offered by the air on the automotive vehicle. With the increase in high performance computing power (HPC) and its affordability, computational fluid dynamics (CFD) has become a popular and more effective tool for aerodynamic design and analysis in the automobile industry. In the real-world scenario, automotive vehicle is subjected to varying wind and operating conditions which affect its aerodynamic characteristics, and therefore it is difficult to reproduce such physical phenomenon in a conventional wind tunnel. Hence, the entire aerodynamic assessment was done in wind tunnel which is equipped with advanced aerodynamic assessment techniques like wheel rotations, boundary layer
Chalipat, SujitBiswas, KundanTare, Kedar
Comparative Analysis of Charger Identification Methods in Electric Truck Routing Algorithms2026-26-0206To be published on 01/16/2026
Optimizing Vehicle Routing is a key application for determining the most effective sequence of locations in electric trucks. This optimization not only enhances operational efficiency but also minimizes energy consumption and reduces overall costs. A critical aspect of Optimal Vehicle Routing is identifying charging stations along the route, particularly for electric vehicles with specific range requirements. The availability of these charging stations are crucial for maintaining the continuity of operations and preventing delays. This paper explores multiple methods for charger identification, simulating and comparing their effectiveness. The primary parameter for comparison is the execution time of the algorithm, which directly impacts the feasibility of real-time applications in logistics. The results of this study provide insights into the efficiency of different charger identification methods within the Optimal Vehicle Routing framework. By analysing execution times, the paper
Bhat, AdithyaPrasad P, ShilpaKolakar, RakshitaMyers, MichaelKlein, FischerShrivastava, Himanshu
Dynamic Prime Mover Management for Enhanced Energy Efficiency in Electric Tractors2026-26-0185To be published on 01/16/2026
Electric tractors present unique opportunities for efficient power management by decoupling traction and auxiliary loads. In the proposed system, two independent electric motors are employed: one dedicated to vehicle traction and the other to drive the power take-off (PTO) and hydraulic functions, including steering and auxiliary attachments like loaders. Hydraulic flow demand directly impacts operational productivity; traditionally, hydraulic flow is linked to engine speed, requiring frequent manual adjustments. This paper proposes an innovative dynamic control strategy that optimizes motor speed based on real-time application demands, introducing three distinct modes: Low Idle Mode, Loader Mode, and PTO Mode. The Vehicle Control Unit (VCU) at the heart in coordination with the Farm Machinery Control Unit (FMCU) and Motor Control Unit (MCU), dynamically selects the appropriate mode based on user inputs such as PTO activation and joystick controls Low Idle Mode minimizes energy usage
Natarajan, SaravananP, ShanmugavelJoshi, PriyankaSundaram, PavithraSameer, KamatSingh, RubyArvind, KumaranT, Senthil Kumar
1D Simulation Approach for Common Rail Injection Systems for a Marine 2 Stroke Diesel Engine2026-26-0395To be published on 01/16/2026
This study presents a comprehensive 1D simulation approach of an automotive solenoid-based diesel fuel injector and a common rail injection system for a marine engine using Simcenter AMESim. The injector model was developed to analyse the injection rate and total injected fuel at various solenoid actuation durations (1.2 ms and 2.0 ms) and common rail pressures. The experimental results from a well-established research study are used for validating the simulation results of the solenoid-based injector. The model demonstrates strong agreement at higher rail pressures (above 1000 bar) and solenoid actuation times. Building on this validated injector model, a detailed marine common rail system was developed incorporating key hydraulic components: a check valve to maintain pressure inside the rail, flow limiting valves to prevent overpressure in the fuel injector, and a combination pressure relief valve. The simulation was used to study rail pressure dynamics at full engine load for
Bhoware, YashPise, UdaySaha, DiptaGaikwad, Nilesh
Advanced Thermal Management for High-Tonnage EVs: Increasing Coolant Flow and Reducing Energy Losses2026-26-0196To be published on 01/16/2026
With the increasing tonnage of electric heavy commercial vehicles, there is a growing demand for higher power and torque-rated traction motors. As motor ratings increase, efficient cooling of the EV powertrain system becomes critical to maintaining optimal performance. Higher heat loads from traction motors and inverters pose significant challenges, necessitating an innovative cooling strategy to enhance system efficiency, sustainability, and reliability. Battery-electric heavy commercial vehicles face substantial cooling challenges due to the high-pressure drop characteristics of conventional traction system cooling architectures. These limitations restrict coolant flow through key powertrain components and the radiator, reducing heat dissipation efficiency and constraining the operating ambient temperature range. Inefficient cooling also leads to increased energy consumption, impacting the overall sustainability of electric mobility solutions. This paper presents a novel approach to
Dixit, SameerPatil, BhushanGhosh, Sandeep
Thermal Shock Test Rig for CNG Shut-off Valve2026-26-0526To be published on 01/16/2026
In Automobile, Gasoline Engines are being used along with electrically operated shut-off valve installed at the roof of bus in case of higher capacity of CNG systems. In order to start/ stop CNG supply from cylinder for running of engine/ safety/ servicing an electrical operated ignition switch/ key controlled CNG Shut-Off Valve is placed just after the cylinders. There have been few failures of these CNG shut-off valves in field application. On investigation, it was observed that the CNG shut-off valve gets failed due to water ingress in coils from the cracks on surface generated due to spray of water (due to daily washing of bus and rain) on heated shut-off valves. In order to validate this field failure and subsequent validation of modified design, a need was felt to use a test rig which can exactly simulate the water spray based thermal shocks. However, there was no low cost facility available to simulate the field service condition for validation. Therefore, a low cost test set-up
Srivastava, Pravin KumarVivekanand, VivekanandKumar, Satish
Curvature-Continuous Trajectory Refinement for Autonomous Vehicles Using a Pure Pursuit Based Path Smoothing Framework2026-26-0135To be published on 01/16/2026
Path planning is a key element of autonomous vehicle navigation, allowing vehicles to calculate feasible paths in challenging environments. Algorithms such as Hybrid A*, Reeds-Shepp, and Dubins paths effectively generate collision-free paths but tend to create curvature discontinuities. These discontinuities result in sudden steering transitions, which create control instabilities, higher mechanical stress, and lower passenger comfort. To overcome these issues, this paper suggests a path-smoothing technique based on the pure-pursuit algorithm to produce curvature-continuous, distortion-free paths appropriate for real-world driving. This method utilizes the practical approach of the original path but removes sudden transitions that destabilize control. By ensuring smooth curvature, the vehicle undergoes fewer jerky steering actions, enhanced energy efficiency, less actuator wear, and improved high-speed tracking. Experimental verifications, such as real-time tests on autonomous vehicles
S, ShriniyathiA, JosanaEdwin J, JoelT, AkshayaaM, Senthil VelKumar, Vimal
Testing Methodology to Calculate the Fuel Economy in Km/Kg of Hydrogen Fuel Cell Electric Vehicle (FCEV) based on Current (Ampere) Method and Flow Method2026-26-0248To be published on 01/16/2026
The globe is looking headlong to set up new benchmarks for the reduction of GHG (Green House Gases) considering short-term and long-term strategies. Efforts in the Internal Combustion Engines (ICE) domain have been accelerating to find an alternative way to reduce harmful emissions. Hydrogen is considered as a promising fuel to leapfrog this transition. Hydrogen fuel can be categorized into vast mobility areas viz. ICE and Fuel Cell Electric Vehicle (FCEV). Hydrogen fuel has attracted global attention from engine researchers due to the crude oil crisis and its rise in prices in recent years. This will serve the nation's goal towards carbon neutrality. Hydrogen has a few advantages such as less fueling time, higher heating value and more efficiency making it an eye-touching fuel for the automotive industry. In the contemporary FCEV segment, many fuel cell technologies have evolved, wherein the development of Proton Exchange Membrane (PEM) fuel cell technology has taken a new height for
Joshi, Ashish RajendraKandalgaonkar, SiddheshSontakke, Rushikesh
Experimental evaluation of Energy and Exergy of Hydrogen, CNG and Gasoline fuelled High-Speed Spark Ignition Engine2026-26-0258To be published on 01/16/2026
HIGHLIGHTS The maximum power is recorded with Gasoline than CNG and Hydrogen fuel. The maximum exergy and energy efficiency is with Hydrogen, followed by CNG and then Gasoline. Hydrogen fuel has a maximum potential to convert into energy. The maximum energy destruction of 48.7kW for gasoline fuel at 3000 rpm and followed by CNG and hydrogen. The maximum entropy generation of 85.5 W/K with Gasoline and 60.72 W/K and 29.39W/K for CNG and hydrogen engine respectively at 10000 rpm. The entropy generation rate increase with engine speed. The highest rate of heat release is from hydrogen fuel, followed by Gasoline and CNG.   ABSTRACT- The analysis was performed on a single Cylinder, Multivalve, Electronic Fuel Injection, high-speed motor fuelled engine with Gasoline, CNG and Hydrogen to assess energetic and exegetic performance. The engine was evaluated from 3000 rpm to 10000 rpm on each of the three fuels. All tests are led at Wide Open Throttle condition.The Gasoline and CNG
Shinde, Apurwa BalasahebKadam, Tusharkarunamurthy, KSHINDE, DR BALU
Evaluating Thermal Control Strategies to Improve Electric Vehicle Range Using GT Suite2026-26-0362To be published on 01/16/2026
This study focuses on enhancing energy efficiency in electric vehicle (EV) thermal management systems through the development and optimization of control logic. A full vehicle thermal management system (VTMS) was modeled using GT-Suite software, incorporating sub-systems such as the high-voltage battery (HVB), e-powertrain (EPT), and an 8-zone cabin. Thermal models were validated with experimental data to ensure accurate representation of key dynamics, including coolant-to-cell heat transfer, cell-to-ambient heat dissipation, and internal heat generation. Control strategies were devised for Active Grille Shutter (AGS) and radiator fan operations, targeting both cabin cooling and e-powertrain thermal regulation. Energy consumption was optimized by balancing aerodynamic drag, fan power, and compressor power across various driving conditions. A novel series cooling logic was also developed to improve HVB thermal management during mild ambient conditions. Simulation results demonstrate
Chothave, AbhijeetKumar, DipeshGummadi, GopakishoreKhan, ParvejThiyagarajan, RajeshPandey, RishabhS, AnanthAnugu, AnilMulamalla, SarveshwarGangwar, Adarsh
A Novel Design of energy efficient 4x4 MIMO Antenna for 4G LTE-A and 5G IOT Communications2026-26-0371To be published on 01/16/2026
This paper presents the design and analysis of a low-profile monopole antenna with a Multiple-Input-Multiple Output (MIMO) configuration, optimized for requirements of modern wireless communication systems. The proposed antenna consists of staircase-like rectangular patches with a stub to enhance bandwidth. Printed on Rogers RT Duroid 5880 substrate, the antenna covers a compact size of 96 x 96 mm2, making it suitable for integration into space-constrained devices. Operating within the frequency range of 2.13-4.2 GHz, the proposed antenna achieves an Envelope Coefficient Correlation (ECC) below 0.015, Mean Effective Gain (MEG) of less than -3 dB, Diversity Gain upto 10 dB, and Channel Capacity Loss (CCL) below 0.12 bps/Hz, thus making antenna suitable for LTE-A and 5G-IoT communications.
Gupta, ParulPrasad, Anjay
Digital Twin-Enhanced Chassis Dynamometer for EV Drivetrain Testing2026-26-0363To be published on 01/16/2026
Accurate prediction of drivetrain performance and energy efficiency in electric vehicles (EVs) remains a challenge due to the limitations of conventional chassis dynamometer testing, which often overlooks dynamic vehicle-roller interactions, suspension responses, and regenerative braking effects. This paper presents a novel digital twin-enabled testing framework using a compact, two-roller chassis dynamometer integrated with real-time multibody dynamics and electromechanical co-simulation. The physical test bench is coupled with a virtual model of the EV, including suspension geometry, rear-to-front axle load distribution, tire–roller contact mechanics, and motor-inverter dynamics. By enabling bi-directional data exchange between the physical and virtual domains, the system emulates real-world load shifts, torque demand variations, and energy recovery under standardized drive cycles. This integrated approach enhances simulation fidelity, supports certification-compliant testing, and
Kumar, AkhileshV, Yashvati
Development of high BMEP natural gas engine with knock mitigation2026-26-0121To be published on 01/16/2026
The stringent emission norms over the past few years have driven the need to use low carbon fuels and after treatment technology. Natural gas is a suitable alternative to diesel for heavy duty engines with applications in power generation and transportation sectors. Stoichiometric combustion mode offer the advantages of complete combustion and low carbon dioxide emissions. The combination of turbocharging and cooled exhaust gas recirculation (EGR) technology enhances the power density along with reduced exhaust emissions simultaneously. However, there are several constraints in the operation of natural gas spark ignition engine such as exhaust gas temperature (EGT) limit of 750 °C, sufficient before turbine (BT) pressure for EGR drivability, boost pressure (2.5 bar), peak cylinder pressure limit and knocking. These limits may restrict the brake mean effective pressure (BMEP) of the engine. In the present study, tests were conducted on a V12, 24 litre, dedicated heavy duty natural gas
Khaladkar, OmkarMarwaha, Akshey
Evaluation of Intercooler Effectiveness with No Fan, Single Fan, and Dual Fan: A Simulation and Experimental Study2026-26-0579To be published on 01/16/2026
Turbochargers play a crucial role in modern engines by increasing power output and fuel efficiency through intake air compression, thereby improving volumetric efficiency by allowing more air mass into the combustion chamber. However, this process also raises the intake air temperature, which can reduce charge density, lead to detonation, and create emissions challenges-such as smoke limits in diesel engines and knock in gasoline spark-ignited (GSL) engines. To mitigate this, intercoolers are used to cool the compressed air. Due to packaging constraints, intercoolers are typically long and boxy, limiting their effectiveness, especially at low vehicle speeds where ram air flow is minimal. This study investigates the use of auxiliary fans to enhance intercooler performance. Two methodologies were adopted: 1D simulation using GT-Suite and experimental testing on a vehicle under different fan configurations-no fan, single fan, and dual fans (positioned near the intercooler inlet and outlet
Patra, SomnathHibare, NikhilGanesan, ThanigaivelGharte, Jignesh Rajendra
Design & analysis of Dual Mass flywheel during Engine startup condition in 3 Cylinder Gasoline application2026-26-0349To be published on 01/16/2026
Modern automotive powertrains are increasingly adopting engine downsizing and down speeding to meet stringent emission regulations and improving fuel efficiency However, these changes result in higher torsional vibrations and excitation amplitudes makes more challenge in NVH (Noise, Vibration, and Harshness) refinement. With growing customer expectations for premium driving experiences conventional clutch are no longer sufficient. To meet the NVH performance targets of the vehicle Dual Mass Flywheels (DMFs) are used In DMF due to lower stiffness and inertia separation there is a great advantage on torsional filtration in normal drive and idle condition. but the resonance frequency of the connected DMF is lower than the idle RPM. Engine startup is a key drawback with DMF equipped vehicles. The proper tuning of starter motor performance & DMF stiffness is required to cross the resonance zone faster otherwise it will lead to DMF to stay in the resonance zone for a longer time leading to
Jayachandran, Suresh KumarVijayaragavan, ThirupathiM, DevamanalanKanagaraj, PothirajAhire, ManojVellandi, Vikraman
For CNG and FFV fuel application robustness improvement of Exhaust Valve2026-26-0125To be published on 01/16/2026
Today, globally, automotive manufacturers are striving to meet the increasing demand for fuel economy, high performance, and silent engines. The fundamental approach to achieving these requirements is through designing low friction mechanisms, resulting in less wear and higher durability. The demand for CNG vehicles has surged exponentially in recent years, prompting increased government focus on alternative fuels such as CNG and hydrogen. These dry fuels lack lubricating properties, unlike conventional fuels like petrol, diesel, and biofuels, which are wet and liquid. Consequently, the operations and failures associated with these fuels differ. The materials and designs of engine parts, such as fuel lines, ECU, exhaust valves, and cylinder heads, vary depending on the fuel used. This study discusses the countermeasures adopted to address the high seat and guide wear in cylinder heads and valves. The investigation focuses on material, design, and manufacturing process improvements
Poonia, SanjayKumar, ChandanSharma, ShailenderKhan, PrasenjitBhat, AnoopP, PrasathNeb, Ashish
Data analysis -Driven Calibration Enhancement for Alternative Fuel Engine Start2026-26-0123To be published on 01/16/2026
In the pursuit of improving cold-start performance in alternate fuel vehicles, data analysis has become a cornerstone for driving informed calibration decisions. Cold start is very critical for flex fuel vehicles since it has higher latent heat of vaporization and lower vapor pressure compared to gasoline. Ethanol blend fuels deteriorate engine starting at low ambient temp. This case study highlights how pivot table based analytics were effectively employed to enhance engine start strategy during the development of small commercial vehicle running on E20 and E85 fuel blends. The approach showcases how structured data interpretation can significantly support development work in Flex Fuel calibration. The analysis concentrated on various critical engine start events such as first crank success, failure to start, battery voltage behavior, and post-start stability across a range of coolant temperatures, particularly below 20°C. Real-world test data was segmented using data analysis based
Undre, ShrikantKulkarni, DeepakThonge, RavindraUpadhyay, RajdipKanchan, Shubham
Combustion noise quality improvement in a common rail Diesel Engine at Low idle for Agriculture Tractor2026-26-0329To be published on 01/16/2026
Vehicle level NVH performance plays major role in customer comfort criteria. Tractor low idle rpm Sound Quality can be one of the parameter which influences customer purchasing decision based on comfort criteria. Modern diesel engines with stringent emission norms together with fuel economy requirements pose challenges to noise control. Common rail engine technology has advantage of precise fuel delivery and combustion control which needs optimization to achieve the conflicting requirements of noise, emission and fuel efficiency. Engine noise at low idle condition is dominated by combustion noise which depends on rate of pressure rise inside the cylinder during combustion. The important parameters which influence cylinder pressure rise are fuel injection timing, pilot injection quantity and its separation, rail pressure and EGR valve position. The study is carried out to understand which combustion parameter is most influencing to achieve better sound quality of engine. Taguchi design
P, PriyadarshanChavan, AmitA, KannanswamyPatil, SandeepChaudhari, Vishal V
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
India WLTC vs MIDC: Comparative Analytical study on BEV Range & Energy Consumption as per AIS175 draft & AIS039/0402026-26-0244To be published on 01/16/2026
The Main Objective of WLTP (Worldwide Harmonized Light Vehicles Test Procedure) was to standardize the Globally Harmonized Test Procedure for evaluating Emission/ FE/ Range of Light Duty Vehicles. Europe has already adopted the WLTP from 2018. WLTC is a global harmonized test cycle that provides realistic emissions/ Range estimation based on its aggressive driving patterns. In India, currently Continuous Full MIDC (Modified Indian Driving Cycle) used to declare the Range of BEV's. Automotive Industry Standard (AIS) released a AIS 175 draft report for development of WLTP regulation in India (iWLTC : India WLTC). The real road Range of Battery Electric Vehicle (BEV) is observed 25% ~ 35% lower than declared Range of Full MIDC AER (All Electric Range). In Europe, real road range of BEV is 10% ~ 15% lower than declared range of WLTP AER. Analytical study performed on BEV Range/ EC as per AIS 175 draft & AIS 039/040 regulation to compare the impact of iWLTC vs MIDC cycle. The Range & Energy
Shiva Kumar, MucharlaTentu, Kavya
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
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
Development of above 500 kW Diesel Engine & After treatment System to meet CPCB-IV+ Emission Norms2026-26-0234To be published on 01/16/2026
The CPCB-IV+ emission compliance for genset application is applicable with effect from 1st July 2023 as per as per GSR 804(E). The CPCB-II to CPCB-IV+ changeover in very stringent in emission front by almost 90 % emission reduction. It's a significant advancement in environmentally sustainable powertrain technology. To meet the CPCB-IV+ Emission, combustion development & ATS technology plays an important role. First is the base engine need to optimize enough with combustion & associated parts. Second is the after treatment system which will carry the battle further to the engine emission with 10% minimum engineering target. This paper present the systematic approach followed to meet CPCB-IV+ emission norms for upgradation of 21 liter TCIC engine for the power range (56 <P ≤ 560). Here the challenge is that we don't want to major changes in the existing CPCB-II FIE recipe & meet the CPCB-IV+ emission with ECU calibration & ATS system calibration with its potential. Here interesting
Rane, VikasJagtap, ShaileshGothekar, SanjeevPawar, Narendra VKhedkar, PrasadKagade, SamadhanKendre, MahadevG Bhat, PrasannaThipse, S
Manufacturing process advancement in CNG Exhaust Valve to prevent seat wear issue2026-26-0278To be published on 01/16/2026
Exhaust Valve CNG market share increased in India in recent years demanding for more durable and reliable CNG Engine. While in current scenario durability is one of the major concerns for CNG engine. Major issue faced in CNG powertrain is high wear at Exhaust valve CNG face due to excessive wear. In Current practice T400 Sintered material layer is deposited at Valve face which is very critical to achieve less wear at valve face. Due to manufacturing variability high level of variation is found mechanical properties of T400 deposit which is very critical for Exhaust Valve CNG performance. In this paper all important process parameters are discussed for achieving consistent Exhaust Valve CNG T400 deposit quality. Each process parameter detail impact on T400 material is studied and explained to achieve consistent quality of T400 deposit leading to robust design of Exhaust Valve CNG.
Poonia, SanjayKumar, ChandanKundu, SoumenKumar, PrabhakarVats, RajeshKhan, PrasenjitSharma, Shailender
Numerical study of a hydrogen ejector with regulated inlet for extended PEMFC operating range in automotive application2026-26-0249To be published on 01/16/2026
Hydrogen recirculation is a key requirement for enhancing fuel efficiency and anode stability in Proton Exchange Membrane Fuel Cell (PEMFC) systems, particularly in automotive applications. Effective hydrogen recirculation is critical for maintaining high efficiency and fuel utilization. A hydrogen recirculation ejector equipped with a regulated pressure inlet, aimed at eliminating the need for mechanical pumps while maintaining optimal hydrogen utilization. The passive operation of the ejector eliminating the need for rotary components which significantly improves system reliability and reduces failure modes commonly associated with moving parts. This work presents a numerical investigation of a hydrogen recirculation ejector featuring a regulated pressure inlet, with the objective of extending its operating range across varying fuel cell power levels. A combination of 1D system-level modelling and 2D multi-species Computational Fluid Dynamics (CFD) simulations was employed to
Khot, Ranjit UttreshwarT P, MuhammadChougule, AbhijeetAchanur, Mallappa
Nexifi11D: A Comprehensive Multidimensional Framework for Futuristic Manufacturing Ecosystems2026-26-0282To be published on 01/16/2026
The manufacturing sector is undergoing a paradigm shift driven by hyper-connectivity, sustainability imperatives, and accelerated digital transformation. Conventional systems, however, remain constrained by their focus on isolated optimizations—such as predictive analytics, IoT-enabled sensing, or workforce scheduling—without providing an integrated operational perspective. To address this fragmentation, Nexifi11D is introduced as a comprehensive, multidimensional framework that consolidates 11 critical dimensions of manufacturing into a unified ecosystem. Nexifi11D advances beyond traditional Industry 4.0 architectures by seamlessly integrating intelligent algorithms, immersive simulation technologies, IoT infrastructure, and predictive systems within a scalable, interoperable mesh. The framework breaks down silos across key manufacturing domains—such as sustainability, cost, operations, and workforce—enabling holistic, data-driven, and proactive decision-making. Each integrated
Kumar, RahulSingh, Randhir
Effect of the Flow Forming Process on the Mechanical properties and Microstructure of GDC & LPDC cast aluminum alloy wheels.2026-26-0298To be published on 01/16/2026
Aluminum alloy wheels have become the preferred choice over steel wheels due to their lightweight nature, enhanced aesthetics, and contribution to improved fuel efficiency. Traditionally, these wheels are manufactured using methods such as Gravity Die Casting (GDC) [1] or Low Pressure Die Casting (LPDC) [2]. As vehicle dynamics engineers continue to increase tire sizes to optimize handling performance, the corresponding increase in wheel rim size and weight poses a challenge for maintaining low unsprung mass, which is critical for ride quality. To address this, weight reduction has become a priority. Flow forming [3,4], an advanced wheel production technique, offers a solution for reducing rim weight. This process employs high-pressure rollers to shape a metal disc into a wheel, specifically deforming the rim section while leaving the spoke and hub regions unaffected. By decreasing rim thickness, flow forming not only reduces overall wheel weight but also enhances strength and
Singh, Ram KrishnanMedaboyina, HarshaVardhanG K, BalajiGopalan, VijaysankarSundaram, RaghupathiPaua, Ketan
Key Parameters for Turbocharger selection & experimental validation for Off-Highway Applications2026-26-0104To be published on 01/16/2026
Customers in off-highway industry are increasingly seeking high-performance capabilities for their tractors due to increasing penetration of mechanisation and labour scarcity. One effective solution to achieve enhanced performance is turbocharging of engines, while meeting emission and highly dynamic transient response of tractor field applications. The process of selecting and validating a suitable turbocharger for tractor field application suitability is significantly time and resources consuming activity due to extensive testbed and field trials. This study focuses on the selection of turbocharger for tractor engines through analytical calculations to freeze key parameters like lambda, boost pressure ratio & temperature within boundaries of exhaust temperature and turbo efficiency maps to deliver best field transient performance and fuel consumption. The selected parameters are further validated under real-world transient operating conditions, involving tractors and their implements
Kumar, Harish KumarRawat, SaurabhDogra, DaljitSinghSingh, SachleenSingh, Amarinder
Development of a CNG-Diesel Dual Fuel Tractor with Mechanical Fuel Injection System2026-26-0114To be published on 01/16/2026
Identification of renewable and sustainable energy solutions remains a key focus area for the engine designers of the modern world. An avenue of research and development is being vastly dedicated to propelling engines using alternate fuels. The chemistry of these alternate fuels is in general much simpler than fossil fuels, like diesel and gasoline. One such promising and easily available alternate fuel is compressed natural gas (CNG). In this work, a 3-cylinder, 3-liter naturally aspirated air-cooled diesel engine from the off-highway tractor application is converted into a CNG Diesel Dual fuel (CNG-DDF) engine. A comparative performance shows that the thermal efficiency is up to 5% lower with CNG-DDF with respect to diesel. However, it has shown the benefit of 44% in Particulate Matter (PM), while retaining the same NOx + NMHC levels as baseline diesel engine. The cycle average CO emission was found to increase by 40% simultaneously, which has been controlled by an oxidation catalyst
Choudhary, VasuMukherjee, NaliniKumar, SanjeevTripathi, AyushNene, Devendra
Enhancing Range Prediction Accuracy for the BEV: Bridging the Gap Between Simulation and Real-World Testing2026-26-0521To be published on 01/16/2026
Accurate range estimation in battery electric vehicles (BEVs) is essential for optimizing performance, energy efficiency, and customer expectations. This study investigates the discrepancies between physical test data and simulation predictions for the Jeep Wagoneer model. A detailed range delta analysis identifies key contributors to the observed deviations, including regenerative braking inefficiencies, increased propulsion demand, auxiliary loads, and estimated drivetrain losses within the Electric Drive Module (EDM) during traction and regen. Results indicate that the test vehicle exhibits lower regenerative braking efficiency and higher traction and lower regen consumption than predicted by simulations, primarily due to EDM inefficiencies and friction brake usage during regeneration. The study underscores the importance of refining simulation methodologies by integrating real-world, test based EDM loss maps to improve accuracy and better align predictive models with actual vehicle
Mahajan, PrasadKesarkar, SidheshAli, Shoaib
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