A novel approach on range prediction of a hydrogen fuel cell electric truck C.Venkatesh - Manager - Product Development, Sustainable Mobility & Advanced Technologies Abstract: A novel approach on range prediction of a hydrogen fuel cell electric vehicle Abstract: Today's growing commercial vehicle population creates a demand for fossil fuel surplus requirement and develops highly polluted urban cities in the world. Hence addressing both factors are very much essential. Battery electric vehicles are with limited vehicle range and higher charging time. So it is not suitable for the long-haul application. Hence the hydrogen fuel cell based electric vehicles are the future of the commercial electric vehicle to achieve long range, zero emission and alternate for reducing fossil fuels requirement. The hydrogen fuel-cell electric vehicle range, it means the total distance covered by the vehicle in a single filling of hydrogen into the onboard cylinders.
Research and/or Engineering Questions/Objective Plastic automotive fuel tanks made up of blow molded, multi-layered, high-density polyethylene (HDPE) material can take complex shapes with varying thickness. Accidental drop of fuel tank from a height during handling can lead to development of cracks. Damage can also occur due to an impact during a crash. This can be catastrophic due to flammability of the fuel. The objective of this work is to characterize and develop a failure model for the fuel tank material to simulate damage and enhance predictive capability of CAE for chassis and safety load cases. Methodology Different aspects were considered to develop a characterization and modelling strategy for the HDPE fuel tank. Material properties can be influenced by factors such as, service temperature, rate of deformation, state of stress etc.
Objective : Objective of the paper is to acquaint the audience with the concept of electric vehicles, Powertrain components used in an electric bus, Siemens contribution to the field of Electromobility, Typical configurations used in an electric bus, challenges and current limitations, emerging Technologies, future, how to address the future charging infra requirement. Methodology : The subject shall be discussed with the audience through a presentation coupled with Explanation by the presenter. The topic shall be opened with the concept of electromobility followed By history of electromobility at Siemens, contribution to the field of electro mobility, typical configurations of electric vehicles, Advantages of electric vehicles vis a vis conventional diesel buses, typical configurations of an electric bus, feasibility of electric buses for various transport services. Comparison of induction motor Vs.
An experimental investigation was conducted to explore the possibility of using the Thumba oil (Citrullus Colocyntis) and Argemone Mexicana (non-edible and adulterer to mustard oil) as a dual fuel blend with diesel as an alternative of using pure diesel for its performance and emission characteristics. The work was carried on a single cylinder, four strokes, In-line overhead valve, direct injection compression ignition engine. The argemone and thumba biodiesel were produced using the transesterification process and thereafter the important physio-chemical properties of produced blends were investigated. Four dual biodiesel blends like ATB10 (5% Argemone, 5% Thumba and 90% Diesel), ATB20, ATB30 and ATB40 were prepared for investigation process. The operating conditions adopted for the study was the entire range of engine loads and speed (1000-1500 r/min) keeping the injection pressure and injection timing at the OEM settings.
Indian automotive industry has witnessed never-seen-before push towards Green mobility from the Government of India (GOI). GOI has maintained a firm stature while leap-frogging from BS-IV to BS-VI and has backed up its intent with equally firm actions of providing the facilities, infrastructure and necessary support to industry. After a lot of initial resistance, the Auto manufacturers have taken up the challenge and are well paced towards meeting the target of 1st April, 2020. Due to many aspects such as commercial viability, wide range of expectation from different type of customer segments e.g. 2-wheeler, 3-wheelers, SCV, Light & MHCV and passenger car segments etc. the overall landscape of market in terms of product segmentation, Diesel-Petrol share pattern is poised to change. Parallel to this development, a wave of electric vehicle enthusiasts has hit the world which boasts of being the ultimate solution towards Green mobility.
Engine performance significantly depends on the effective exhaust of the combustion gases from the muffler. With stricter BSVI norms more efficient measures has to be adopted to reduce the levels of exhaust emissions from the exhaust to the atmosphere. Muffler along with reducing the engine noise, is intended to control the back pressure as well. Back pressure change has significant effect on muffler temperature distribution which affects the NOx emission from the exhaust. Many research communications have been made to reduce the exhaust emissions like HC, CO and CO2 from the exhaust by using different generation biofuels as alternate fuel, yet they have confronted challenges in controlling the NOx content from exhaust. This work presents the combined effect of Muffler geometry modifications and blended microalgal fuel on exhaust performance with an aim to reduce NOx emission from the exhaust of a four-stroke engine.
The diesel engine is widely used for its high thermal efficiency and better fuel conversion efficiency. However, increasing usage of petroleum fuel and environmental degradation motivates to use renewable biofuels as a replacement to conventional diesel. Biofuels produced from non-edible sources can be used as a partial substitute of diesel for the significant growth of fuel economy and reduction of environmental pollution. Methanol can be implemented as a blended fuel in the diesel without affecting engine design. In this study, the effect of diesel methanol blends and injection parameters such as fuel injection pressure (FIP)and start of injection (SOI) on a common rail direct injection (CRDI) diesel engine performance and emission were investigated. Four blends were prepared by mixing diesel with methanol (5%, 10%, 15% and 20% by mass) and adding a certain amount of oleic acid and iso-butanol to get a stable blend.
The need of Diesel as fuel has greatly pressurized the now scarcely available natural resources and is likely to become a luxury for the future generations. This paper aims at finding an alternate for diesel that can hopefully reduce the pressure on its existing demand. This paper presents a comparative study on use of different blends of Jatropha Oil (J) and Ethanol (E) as fuel in a diesel engine to observe its performance and emission characteristics. The findings are later compared with corresponding values of neat Diesel as fuel. Since Jatropha oil is more viscous and has polyunsaturated characteristics in its natural form, its ethyl ester was produced by transesterification process and later blended with Ethanol in different proportions like 90% J 10%E, 80J-20E, 70J-30E and 60J-40E.
A major challenge for combustion development is to optimize the engine for improved fuel economy, reduce greenhouse gases. Stringent CAFÉ and emission norms require the customer to pay higher capital on vehicles. To offset the cost of ownership- cheaper and alternative energy sources are being explored. Ethanol blend with regular Gasoline and CNG are such alternative fuels. The study was carried on turbo-charged gasoline direct injection engine. The effect of ethanol on engine and vehicle performance is estimated and simulated numerically. The work is split into three stages: first the base 1D engine performance model was calibrated to match the experimental data. In parallel, vehicle level Simulink model was built and calibrated to match the NEDC cycle performance. Second, the thermal efficiency of the ethanol blend is calculated as a linear function of theoretical Otto cycle efficiency.
Currently Automotive industry is looking for sustainable alternate of Conventional fuels. Bio diesel is an alternative fuel similar to conventional or ‘fossil’ diesel. It is produced from vegetable oil, animal fats, tallow and waste cooking oil. Bio diesel is one of the most promising fuel which can not only replace the conventional fuels but also environment friendly in terms of Greenhouse gases emission. Bio diesel can be produced from various sources and can be sustainable fuel for automotive vehicles. In this paper, efforts have been taken to convert existing Diesel engine into Bio diesel compliant engine. For making suitable for Biodiesel operation, modification in Engine Fuel system, filter and Sealing were carried out. Further Engine performance and emission testing were done and results were compared with performance and emission of same configuration Diesel engine.
Butanol is an attractive alternative fuel to fuel diesel engine. Waste engine oil is causing land pollution and contamination to groundwater a lot. This experimental study is to investigate the performance of treated waste engine oil and butanol as fuel to diesel engine operated under optimal engine operating parameters. This study was conducted in four stages: Treating the waste engine oil; Preparation of blends and testing the properties; Arriving at an optimal injection timing, nozzle opening pressure, compression ratio, and intake air temperature to suit the possible blend of treated waste engine oil and butanol; Testing the possible blend under optimal operating parameters under various load conditions. The properties test indicated that 35% of butanol can be blended with treated engine oil with respect to the essential properties for fueling diesel engine. To optimize the parameters L16 orthogonal array with the Taguchi method was used.
Diesel Ethanol (Diesohol) blends are one of the suitable alternative fuel to replace diesel for fueling the compression ignition engines. This experimental study is to utilize optimal fuel blend that contains a higher volume of ethanol in diesel with treated waste engine oil as co-solvent for preventing the phase separation. This study includes three stages: Treating the waste engine oil, preparation of diesel ethanol blends with treated waste engine oil as co-solvent, testing the blends for solubility, properties and performance in a compression ignition engines. Treatment of waste engine oil was conducted in five steps including the acid-clay treatment, in which acetic acid and fuller earth were used as treating materials. Solubility test was conducted for various proportions of diesel-ethanol blends (from 0% to 50% of ethanol by volume) and treated waste engine oil (from 5% to 25%). The stable blends were tested for essential properties as per the ASTM standards.
Research Objectives. In this modern era increase in Pollution became a huge impact in the lives of all living creatures, in this automobile tends to be one of the major contributors in terms of air pollution thanks to their exhaust emissions. The objective of the present study is to reduce the amount of harmful pollutants emitted from the automobiles by the utilization of a biofuel further influenced by two additives (liquid and a Nano additive). Methodology In this study, first the bio oil is extracted, Then the biofuel is mixed with diesel fuel at different proportions of 20%, 40% by volume. Experiments are carried out in a direct injection compression ignition engine, which is a stationary test engine manufactured by Kirloskar, connected to a computer setup. The emission values in the exhaust gases are obtained using AVL exhaust gas analyzer.
Blending of primary alcohol in gasoline surges the vapour pressure significantly and exhibits azeotrope behaviour that effect severely on the atmospheric distillation yields. In this experiment, primary alcohol (Ethanol) were blended in varied volumetric proportion (5%, 10%, 15%, 20%, 25%) with hydrocracked gasoline, influence on volatility behaviour and distillation properties were investigated. Physical properties of this blends were investigated for vapour pressure (VP), VLI, DI and distillation which were selected to evaluate the influence of alcohol in azeotrope behaviour of the fuel mix reflected through pattern of distillation curve (temperature vs % recovery range). This fuel mix exhibited rise in recovery at 700C (E70), VP, VLI and area of azeotrope with increase in % of alcohol volume in gasoline blend.
Authors: Udit Kaul, Mahendarpal and Madhusudan Joshi Organization: International Centre for Automotive Technology, Manesar Introduction: In this paper, a study concerning multi-point CNG injectors (MPCI) or commonly known as injector rail would be presented. Here we would make a detailed analysis regarding the performance of MPCIs due to variation in physical and electrical parameters. In this case multiple MPCIs would be considered and there electrical and dimension parameters would be compared with respect to their performance. The performance comparison would be done based on the common compliance standard under standard laboratory conditions. We would also like to propose the optimal combination of electrical and dimension parameters for better performance. The variables to be considered for the proposed study are: injector valve open/shut timing, injector dimension, voltage levels, solenoid types etc. Key words : multi-point CNG injectors, injector valve, solenoid
India has gone through a lot of transformation over the last decade. Today it is the 6th largest and one of the fastest growing economies in the world. Rising income level, increased consumerism, rapid growth in urbanization and digitization have attributed to this change. Government focus on “Make in India” for promoting trade and investment in India have ensured that India emerge as one of the largest growing economies in the world. The automotive industry played a pivotal role in the manufacturing sector to boost economic activities in India. The passenger car market has increased 3 times over the last decade and it has led to increased mobility options for many people across India. However, this has put concerns on the country’s energy security and emission levels. According to IEA’s recent report on global CO2 emission, 32.31 Gt of CO2 emissions were from fuel combustion in 2016, out of which transport sector contributed ~25%.
Bio diesel is one of the most promising fuel which can not only replace the conventional fuels but also environment friendly in terms of Greenhouse gases emission. Adaptation of Bio diesel comes with reduced maintainability and high maintenance cost. Blends of biodiesel and conventional diesel are most commonly used in automotive diesel engines. Biodiesel is most popular choice as an alternate fuel of fossil diesel due to its easy availability, eco-friendly nature and minimum change in existing diesel engine for retro fitment. In this paper efforts have been taken to optimize the life of Fuel filter for bio diesel application. For improving Fuel filter life, modifications carried out in Fuel filter media, size and configuration. Further, Fuel filter tested on Engine test bed and Vehicle to establish the life of filter in real world usage condition. Testing Results were compared with existing diesel fuel filter.