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Compressed Natural Gas (CNG) is regarded as a promising fuel for spark-ignited (SI) internal combustion engines (ICE) to improve engine thermal efficiency and reduce both carbon dioxide and pollutant emissions. Significant advantages of CNG are higher-octane number, higher hydrogen to carbon ratio, and lower energy-specific CO2 emissions compared with gasoline. More, it can be produced in renewable ways, and is more widespread and cheaper than conventional liquid fossil fuels. In this regard, the direct injection of CNG engines can be considered a promising technology for highly efficient and low-emission future engines. This work reports an experimental and numerical characterization of high-pressure methane jets from a multi-hole injector for direct injection engines.

A customised version of FIRE™ code is chosen to simulate the spray injected into a controlled environment by means of a Common Rail system driven via a Programmable Electronic Control Unit. Numerical results are compared to experimental data collected under various operating conditions, namely varying the injection pressure up to 120 MPa, and the gas back-pressure between 0.1 and 5.0 MPa. Non-evaporating conditions are considered. The employed optically accessible test chamber allows to light the spray with a flash lamp or a pulsed laser sheet, generated on the second harmonic of a Nd-YAG laser (532 nm, 12 ns in duration). Images are collected at different instants of time after the start of injection by means of a CCD camera. A digital image processing software is used to evaluate the major characteristics of the spray, as the penetration length and the cone angle. The injection flow rate is properly measured on a rate-of-injection flow bench for different injection strategies.