Experimental Study of Hydrogen Combustion in Argon-Oxygen Mixture Using an Optical Engine

The Argon Power Cycle (APC) is an emerging high-efficiency combustion technology for internal combustion engines. In APC, the conventional air-based working fluid is replaced with an inert argon gas. This substitution inherently increases engine efficiency through thermodynamic properties of argon, in particular a high adiabatic factor ?? ~1.67. A hydrogen-fueled APC engine offers the potential for highly efficient zero emission combustion by also eliminating nitrogen oxide (NOx) formation. In the present paper, hydrogen combustion is studied in an optical heavy-duty research engine, with the objective of providing the first visualization of H₂ combustion in an argon–oxygen mixture. A comparative analysis of high-speed optical imaging and in-cylinder pressure measurements is conducted for two different modes: 1) conventional air operation and 2) argon-oxygen mixture operation. The high-speed images reveal a distinctly different combustion process between the two operating modes. The main results of the study are as follows: 1) The cylinder peak temperature during compression, estimated from cylinder pressure, increases from approximately 800K (air) to 1200K (argon-oxygen). 2) Abrupt hydrogen pre-ignition was observed for the argon-oxygen mixture, leading to strong pressure oscillations. In contrast, for hydrogen-air combustion, the mixture was ignited by the spark without pre-ignition. 3) The initial heat release was significantly higher in the argon-oxygen mixture yielding a pressure rise in a few crank angle degrees (CAD) in contrast to 5-10 CAD for the air mixtures. 4) Extremely lean hydrogen combustion was observed for the argon-oxygen case.