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This study investigated the exhaust particle and unregulated emissions emanating from a heavy duty six-cylinder natural gas engine with CNG and HCNG fuels. Experiments were performed at different speeds (1000, 1500, 2000 and 2500 rpm) and load conditions (30%, 50%, 75% and 100%). Exhaust gas samples at each speed-load combination were analyzed for particle number concentration and particle size distribution using engine exhaust particle sizing spectrometer. Unregulated emissions were also measured using FTIR (Fourier Transform Infrared) analyzer. The results indicated that particle number (PN) concentration in exhaust is comparatively lower with HCNG fuel than CNG and it increases with increase in engine speed-load. At higher speed-load condition, engine emits high nucleation mode particles (NMP) and ultrafine particles (UFP). Total PN concentration in the NMP range is comparatively higher than UFP and accumulated mode particles (AMP) for both the test fuels.

This research quantifies the real-world emissions and fuel economy of a BS-VI motorcycle. The emissions estimation by standard driving cycles in the laboratory does not represent the emissions factors estimated in real-world driving experience on road. In real-world driving conditions, the emissions of motorcycles were influenced by vehicle driving patterns and traffic conditions. The time-speed data was collected during peak and non-peak hours on weekdays and weekends. The fuel economy and emissions factors were estimated for peak and non-peak hours by simulating the time-speed data on a chassis dynamometer interfaced with a gravimetric fuel consumption meter and a 5-gas analyzer. The average and maximum speeds of 29 km/h and 60 km/h in urban, 33 km/h and 72 km/h in rural, and 47 km/h and 79 km/h on highways respectively were observed. The CO and HC emissions were higher during peak hours on weekdays in urban traffic conditions compared to other traffic conditions.

In India, , as per mandate of hon'ble Supreme Court of India for reduction of emission due to vehicles, compressed natural gas (CNG) powered city buses and passengers cars are in use since 2000. Their usage is limited to metropolitan cities like Delhi, Mumbai, Bangalore etc. due to limitation of CNG storage and dispensing infrastructure along with low energy density storage. High energy density liquid form of natural gas storage (LNG) can overcome these difficulties and promising in near future. Simultaneously, there is a need for development of efficient fuel storage system, fuel supply system, engine optimization & calibration, engine lubricant etc. suitable for implementation of LNG for automotive application. In this background, the present work is aimed at the framework of engine testing facility, development of dedicated lubricant and performance of the engine for LNG application.

N-butanol is a promising alternative fuel which needs no engine modification when used as a blend with diesel. The miscibility of n-butanol with diesel is excellent in a wide range of blending ratios. N-butanol has high oxygen content and a comparable energy content, specific gravity and viscosity to that of diesel, which makes it attractive for diesel engines as an alternative fuel. An experimental investigation was conducted to assess the performance of a new generation passenger car with respect to power, fuel economy (FE) and mass emission using 5, 10 and 20 percent (by vol.) n-butanol blends with diesel (NB). Computer controlled DC motor driven chassis dynamometer, AVL AMA I60 mass emission measuring system and AVL FSN smoke meter were used for measuring wide open throttle (WOT) power, road load simulation (RLS) fuel economy, mass emissions and smoke in WOT and steady speed driving conditions.

This research evaluates the fuel economy and emissions of admixtures called gasoline multifunction additive (GMFA) and 10% ethanol blended gasoline against neat gasoline using newly developed Indian Motorcycle Driving Cycle with a BS VI motorcycle, also compared the performance of new cycle with the WMTC for the driving cycle parameters, fuel economy and emissions. The vehicles fuel economy and emissions factors are influenced by not only vehicle type, but also the road infrastructure and traffic patterns followed. The standard driving cycles do not replicate the real-world fuel economy and emissions as these cycles are very old and do not represent current traffic scenario. A real-world driving cycle was made based on micro-trips approach by analyzing the real-world time-speed data collected in four different pre-determined routes in Delhi-NCR region..

India's natural gas consumption reached 60.3 billion cubic meters (BCM) in the year 2022-23, with imports accounting for 44.2% of the total consumption. As India targets 15% of primary energy consumption from gas by 2030, the demand for natural gas is expected to grow significantly. In this context, CBG (bio-CNG) which can reduce dependence on imported natural gas, has emerged as a viable alternative to CNG. The government's SATAT (Sustainable Alternative Towards Affordable Transportation) initiative encourages entrepreneurs to establish CBG plants and supply CBG to Oil Marketing Companies (OMCs) for use as automotive and industrial fuels. As of June 2023, 50 CBG plants have been set up, and 128 retail outlets in India are selling CBG as a transportation fuel. The quality requirements of CBG are governed by IS 16087, aligning with the specifications for automotive CNG defined in IS 15958.

In a recent finding it was published that there are five (05) major cities across Delhi / NCR which falls under the World's most polluted cities (historical data 2017-2022) based on annual average PM2.5 concentration (μg/m3). The present study is entirely focused on Delhi / NCR and the measurement is done through the continuous type of air quality monitoring analyzers. Various activities like construction, manufacturing, trash burning, production units, burning of organic compounds, power plants, biomass burning, demolition, vehicular emission etc. are the key sources that contribute to poor air quality. As a result of these activities, numerous dangerous chemicals, pollutants with different ionic species (along with gases and aerosols) are released and pose serious threats to health and environment.

Net-Zero emission ambitions coupled with availability of oxygenated fuels like ethanol encouraged the Government towards commercial implementation of fuels like E20. In this background, a study was taken up to assess the impact of alcohol blended fuels on performance and emission characteristics of a BS-VI complaint motorbike. A single cylinder, 113-cc spark ignition, ECU based electronic fuel injection motorbike was used for conducting tests. Pure gasoline (E0), 10% ethanol-gasoline (E10), 20% ethanol-gasoline (E20) and 15% methanol-gasoline (M15) blends meeting respective IS standards were used as test fuels. The oxygen content of E10, E20 and M15 fuels were 3.7%, 7.4% and 8.35% by weight respectively. Experiments were conducted following worldwide motorcycle test cycle (WMTC) as per AIS 137 standard and wide-open-throttle (WOT) test cycle, using chassis dynamometer.