H. H. Xiao, Z. L. Mao, W. G. An and J. H. Sun (2014) Experimental and LES investigation of flame propagation in a hydrogen/air mixture in a combustion vessel. Journal/Chinese Science Bulletin 59 2496-2504. [In English]
Web link: http://dx.doi.org/10.1007/s11434-014-0281-y
Keywords: Hydrogen/air mixture; Premixed flame; LES; Tulip flame; Propagation; speed; Pressure rise; Oscillation; LARGE-EDDY SIMULATION; IGNITION DELAY TIMES; PREMIXED FLAMES; TULIP; FLAME; CLOSED TUBES; AIR FLAMES; ACCELERATION; VELOCITY; DEFLAGRATIONS; INSTABILITY

Abstract: This work presents an experimental and numerical investigation of premixed flame propagation in a hydrogen/air mixture in a closed combustion vessel. In the experiment, high-speed schlieren video photography and pressure sensor are used to examine the flame dynamics and pressure transient. In the numerical study, a large eddy simulation (LES) based on a RNG sub-grid approach and a LES combustion model is applied to reproduce experimental observations. The effects of four physical phenomena on the burning velocity are considered in the combustion model, and the impact of grid type on the combustion dynamics is examined in the LES calculations. The flame experiences four stages both in experiment and LES calculations with structured and unstructured grids, i.e., spherical flame, finger-shaped flame, flame with its skirt in contact with the sidewalls, and tulip-shaped flame. The flame speed and pressure in the vessel develop with periodical oscillations in both the experiment and LES simulations due to the interaction of flame front with pressure wave. The numerical simulations compare well with the detailed experimental measurements, especially in term of the flame shape and position, pressure build-up, and periodical oscillation behaviors. The LES combustion model is successfully validated against the bench-scale experiment. It is put into evidence that mesh type has an impact to a certain extent on the numerical combustion dynamics, and the LES calculation on structured grid can predict the flame dynamics and pressure rise more accurately than that on unstructured grid with the same mesh resolution. The flame shape is more asymmetrical in the LES on an unstructured grid than that on a structured grid, and both the flame speed and the pressure rise at the later flame stage are underestimated in the LES on the unstructured grid.