Stochastic end-gas autoignition in spark ignition (SI) engines, commonly called
“knock,” limits attainable engine efficiencies. Multiple pathways to extend SI
engine operation into knock-limited regions have been studied, including direct
water injection (DWI). This study employs single-cylinder engine experiments
with a centrally mounted water injector to investigate the knock resistance
offered by compression stroke water injections, which, through incomplete
mixing, can thermally stratify the cylinder. In SI, thermally stratifying
injections are expected to forcibly widen the cylinder temperature distribution
by preferentially cooling the cylinder periphery. The end-gas is in the cylinder
periphery. A cooler end-gas would result in longer ignition delays, thus
providing knock resistance.
The difference between intake temperature required to match knock-limited CA50
and a baseline intake temperature at the load of 8 bar IMEPg (gross
indicated mean effective pressure) was used to quantify the “effective charge
cooling” for the injection timings studied. A higher positive value for the
effective charge cooling implies higher knock resistance. Effective charge
cooling values for early compression stroke injection timings (−180° to −120°
aTDC) were observed in the range of ~35−45 K. Later compression stroke and
intake stroke injection timings displayed effective charge cooling values in the
range of ~5−35 K and ~0−20 K. A compression stroke injection timing sweep was
performed at a load of 6 bar IMEPg while holding the spark timing,
intake temperature, and water mass constant to study the effect of injection
timing on the combustion process. Although CA50 advanced while delaying the
injection timing (−180° to −80° aTDC), post-CA50 burn durations stayed nearly
constant, a behavior consistent with the presence of thermal stratification.
Thus, it was concluded that injection timings that heterogeneously cool the
cylinder provide higher knock resistance compared to bulk cooling.
