Modeling Analysis of Thermal Efficiency Improvement up to 45% of a
Turbocharged Gasoline Engine 2022-01-7051
Numerical analysis of thermal efficiency improvement up to 45% of an 1.8-liter
turbocharged direct-injection (DI) gasoline engine was conducted in this study
in response to the need of improving vehicle fuel economy. 1D thermodynamics
simulations and 3D computational fluid dynamics (CFD) modeling were carried out
to investigate the technical approaches for improving engine thermal efficiency.
Effects of various technologies on the improvement in the engine performance
were evaluated, and then the technical routes to achieve 41% and 45% brake
thermal efficiency were summarized, respectively. It is concluded that 41%
thermal efficiency can be reached under stoichiometric combustion conditions,
while it is expected lean burn technology is needed for the target of 45%
thermal efficiency. The effects of high tumble intake flow on accelerating
burning speed and of high compression ratio on intensifying knocking were
analyzed. A novel concept of targeted fuel injection to mitigate knock was
evaluated under high compression ratio conditions. The results justified the
effectiveness of the proposed concept in suppressing knock combustion.
Citation: Meng, S., Wu, Z., Han, Z., Wang, Y. et al., "Modeling Analysis of Thermal Efficiency Improvement up to 45% of a Turbocharged Gasoline Engine," SAE Technical Paper 2022-01-7051, 2022, https://doi.org/10.4271/2022-01-7051. Download Citation