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Climate change and global warming are one of the major challenges faced by the world today. A significant number of Indian cities rank among the most polluted globally, with vehicular emissions being the primary contributor. To address this issue, the Government of India is actively advocating for the adoption of zero-emission vehicles such as electric vehicles through policies and initiatives like FAME II [1], PMP and the National Mission for Transformative Mobility and Storage. The acceptance of electric vehicles is growing in the Indian market seeing more than 200% increase in sales in the year 2022 compared to 2021 with a large share of 2-wheelers, 3-wheelers and compact cars getting electrified. Further adoption of electrification on a much larger scale currently faces the major challenge of high overall vehicle cost compared to conventional vehicles, with the major contribution coming from the HV battery which is the costliest system on the electric vehicles.

Climate change is a global phenomenon now and countries across the globe are working towards reducing emissions by bringing in stricter legislations on emissions and CO2. India is also facing huge challenges on pollutions in large cities. Reports suggest that 7 of the 10 most polluted cities of the world lie in India. The growing public opinion towards cleaner air and reduced greenhouse gaseous emissions has sensitized the matter and has led to drafting of strict emission legislations in India during the past few years. The leap frogging from BS 4 to BS 6 in 2020 by skipping BS 5 norms showed the intent of the GOI towards emission reduction. The BS 6 legislation is not limiting to meeting norms with legislative emission cycle but will also focus from year 2023 onto real driving emissions on actual roads. GOI is also proposing to implement fleet CO2 emission norms (CAFÉ) by 2022 to regulate the CO2 emissions.

In a world increasingly concerned with environmental sustainability and traffic congestion, the need for innovative solutions to address daily commuting challenges has become paramount. This paper presents an innovative concept for an application/system that seeks to revolutionize the way corporate employees commute to work. By harnessing the power of data and technology, this application aims to reduce pollution, traffic, and fuel consumption while promoting shared transportation solutions among employees. The paper discusses the key features and benefits of this proposed application and its potential to create a greener and more efficient corporate commuting ecosystem.

With the increasing focus on reducing CO2 emissions to combat global warming and climate change, the automotive industry is exploring near zero-emission alternative fuels to replace traditional fossil-based fuels like diesel, gasoline, and CNG. Methanol is a promising alternative fuel that is being evaluated in India due to its easy transportation and storage, as well as its production scalability and availability potential. This study focuses on the retro-fitment solution of M100 (pure methanol) SI port-fuel injection (PFI) mode of combustion. A heavy duty single-cylinder engine test setup was used to assess methanol SI combustion characteristic. Lean operation strategy has been investigated. At lean mixture conditions a significant drop in NOX and CO emissions was achieved. The fuel injection techniques and the impact of exhaust gas recirculation (EGR) on the conventional stoichiometric combustion process is highlighted.

Reducing vehicular noise has become a crucial step in product development to meet stringent legislation and improve passenger experience. Smaller vehicles like three-wheelers and compact cars are often powered by a single cylinder engine due to product cost, packaging and weight constraints. Unlike a multi-cylinder engine where cylinders fire one after another which helps to reduce noise levels by destructive interference of pressure waves, a single cylinder engine produces higher noise levels due to firing of a single cylinder. Intake and exhaust flow noise is one of the dominant sources of vehicular noise. This study focuses on using CAE tools to reduce intake and exhaust flow noise levels to meet target noise requirements. One dimensional (1-D) gas dynamics simulation provides a good trade-off between accuracy and run-time, allowing for evaluation of multiple design iterations with acceptable accuracy in a relatively short time frame.

The emission legislations are becoming increasingly strict all over the world and India too has taken a big leap in this direction by signaling the migration from Bharat Stage 4 (BS 4) to BS 6 in the year 2020. This decision by the Indian government has provided the Indian automotive industry a new challenge to find the most optimal solution for this migration, with the existing BS 4 engines available in their portfolio. Indian market for the LCV segment is highly competitive and cost sensitive where the overall vehicle operation cost (vehicle cost + fluid consumption cost) is the most critical factor. The engine and after-treatment technology for BS 6 emission levels should consider the factors of minimizing the additional hardware cost as well as improving the fuel efficiency. Often both of which are inversely proportional. The presented study involves the optimization of after treatment component size, layout and various systems for NOx and PM reduction.

With the rising pollutant emission level in Indian cities, the focus on pure BEVs is also increasing in India. Therefore, the Indian Government is currently preparing suitable policies to promote the acceptance of BEVs (e.g., FAME-2) [1]. The goal is to provide subsidies and develop the required infrastructure for battery charging. The environmental conditions in India differ significantly from those in other developed countries in Europe or China. The maximum temperatures can rise to 55 °C in the summertime [2]. In winter, temperatures in the northern Himalayan regions can fall below -25 °C [3]. Within this wide range of environmental conditions, all components, such as the electric motor and battery, must be conditioned by the thermal system of the vehicle. On the one hand, HV battery packs are one of the main cost drivers. On the other hand, currently, the battery size must be maximized to improve the driving range and ensure customer acceptance.