Multi-point micro-flame ignited hybrid lean-burn combustion of gasoline with direct injection dimethyl ether

Abstract: Lean-burn combustion is effective in reducing fuel consumption of gasoline engines because of the higher specific heat ratio of the fuel lean mixture and reduced heat loss from lower combustion temperature. However, its application to real engines is hampered by the unstable ignition, high cyclic variability, and partial-burn due to slower combustion, as well as the restricted maximum lean-burn air/fuel ratio limit and the insufficiently low nitrogen oxides emission. Multi-point micro-flame-ignited hybrid comb… Show more

“…Firstly, it has higher viscosity and lower vapor pressure when made comparison to DME and DMM, due to the large size of its structures. 17,18 This in turn averts vapor lock, 16 a trait that is crucial for fuel injection and eliminates the need for a pressurized tank. Secondly, it has a high CN of above 63, 19 which can substantially reduce ignition delay.…”

Enabling robust simulation of polyoxymethylene dimethyl ether 3 (PODE₃) combustion in engines

“…Firstly, it has higher viscosity and lower vapor pressure when made comparison to DME and DMM, due to the large size of its structures. 17,18 This in turn averts vapor lock, 16 a trait that is crucial for fuel injection and eliminates the need for a pressurized tank. Secondly, it has a high CN of above 63, 19 which can substantially reduce ignition delay.…”

Enabling robust simulation of polyoxymethylene dimethyl ether 3 (PODE₃) combustion in engines

Combustion and emission characteristics of an ultra-lean burn gasoline engine with dimethyl ether auto-ignition

Study on micro-flame ignited (MFI) hybrid combustion characteristics of a dual-fuel optical engine at different lambdas