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The demand for Compressed Biogas (CBG) as an alternative fuel to Compressed Natural Gas (CNG) is rapidly increasing due to its renewable nature and environmental benefits. However, CBG and H-CNG has variations in gas composition standards as compared to CNG, which may require hardware changes in fuel system to adapt to these variations while ensuring the same performance. Fuel delivery system of CNG vehicle comprises of fuel storage tank, fuel delivery circuit, pressure regulator, fuel rail and injector. Performance of a fuel injector and pressure regulator are critical factors in the efficient and effective delivery of gaseous fuel to engine. This paper theoretically examines fuel flow requirement of injectors with different gas compositions such as CNG, CBG, G25, G20, H-CNG and taking in consideration other factors impacting overall performance.

With the advent of upcoming stringent automobile emission norms globally, it is inevitable for original equipment manufacturers (OEMs) to shift towards greener alternatives. Use of compressed natural gas (CNG) is a preferred solution as it is a relatively clean burning fuel and it doesn’t have significant loss in vehicle efficiency and performance. Modern day customers are more aware and sensitive towards vehicle noise, vibration and harshness (NVH). Hence, OEMs must cater to this demand through optimized design and layout. In a passenger vehicle, CNG is stored at high pressure and delivered to injectors after pressure reduction at a regulator. During engine idling, the opening and closing motion of the CNG injector generates back pulsation and these pulsations cause vibrations which may propagate through other components in the delivery path and perceived as noise inside vehicle cabin.

With the increase in customer expectations related to engine performance and vehicle NVH, it has become the need of the hour for automotive industry to continuously use state of-the-art designs. These dynamic concepts require innovative simulation techniques correlated with testing to value engineer the optimal design and further validations. Compact engine room packaging and futuristic aesthetics changes in styling have further magnified these challenges. Packaging air intake system and positioning air intake snorkel are among such challenges that play a critical role for improving engine performance and life. The objective of this paper is to propose an approach for optimizing design and position of air intake snorkel to meet desired intake air temperature, noise targets with no water entry in to engine. Full vehicle computational fluid dynamics (CFD) simulation is performed for predicting air intake temperature, water wading and 1D simulation for suction flow noise.