Qingming Liu

Explosion and flame characteristics of methane/air mixtures in a large-scale vessel

In this study, experiments of explosions and flame characteristics in methane/air mixtures are performed in a 10‐m3 vessel. Pressure gauges and a high‐speed camera are utilized to record the pressure trajectories and the flame propagation process of ignition growth. The experimental results show that the maximum value of overpressure and the maximum rate of the explosion pressure rise are 0.596 MPa and 1.82 MPa/s for the methane (9.5% in volume)/air mixture at atmospheric conditions, respectively. Both values are higher than for other mixtures with different compositions. The results also indicate that the overpressure from the large‐scale vessel in this study is lower than that of a smaller apparatus (e.g., 5‐L closed cylindrical vessel). This difference occurs due to the cooling effect and because the reflected sonic disturbances by the vessel wall affect the explosion process and weaken the energy during the pressure attenuation stage, thus rendering the value of overpressure in the large‐scale apparatus lower than in the tiny cylindrical vessels. The maximum overpressure is observed at 0.75 m for C = 7% (“C” means the methane concentration) and 9.5% but at 1.3 m for C = 5%, 6.5%, 11.2%, and 13%. These results indicate that methane/air is an easier means to generate overpressure and that the overpressure is higher near the stoichiometric condition. Based on the analysis of the flame propagation process, the mean value of the flame speed of methane (C = 9.5%)/air is calculated to be approximately 2.43 m/s because the nonuniformity of the chemical reaction at the flame front results in a maximum fluctuation of flame speed of approximately 28.5%. The flame thickness (θ) of methane (C = 9.5%)/air fluctuates between 9.84 and 10.95 mm, with a mean value of 10.53 mm.

Deflagration-to-detonation transition in isopropyl nitrate mist/air mixtures

The characteristics and stages of the deflagration-to-detonation transition (DDT) in isopropyl nitrate (IPN) mist/air mixtures are studied and analyzed. A self-sustained detonation wave forms, as is observed from the existence of a transverse wave and a spinning wave structure. The run-up distance of the DDT process and the pitch size of the self-sustained spinning detonation wave in IPN/air mixtures are analyzed. Moreover, a retonation wave forms during the DDT process. Two propagation modes, the high-speed deflagration mode and the self-sustained detonation mode, of the shock-reaction complex (SRC) in IPN mist/air mixtures are found and analyzed. The influence of the mist concentration on the SRC propagation mechanism is studied. The minimum and the optimum IPN mist concentrations for DDT occurrence in IPN mist/air mixtures are determined. The propagation velocity and overpressure of the self-sustained detonation wave in IPN mist/air mixtures are measured and calculated.