Combined effect of ignition position and equivalence ratio on the characteristics of premixed hydrogen/air deflagrations

Premixed hydrogen/air deflagrations were performed in a 100 mm x 100 mm x 1000 mm square duct closed at one end and opened at the opposite end under ambient conditions, concerning with the combined effect of ignition position IP and equivalence ratio empty set. A wide range of empty set ranging from 0.4 to 5.0, as well as multiple IPs varying from 0 mm to 900 mm off the closed end of the duct were employed. It is indicated that IP and empty set exerted a great impact on the flame structure, and the corresponding pressure built-up. Except for IP0, the flame can propagate in two directions, i.e., leftward and rightward. A regime diagram for tulip flames formation on the left flame front (LFF) was given in a plane of empty set vs. IP. In certain cases (e.g. the combinations of empty set = 0.6 and IP500 or IP700), distorted tulip flames were also observed on the right flame front (RFF). Furthermore, the combinations of IP and empty set gave rise to various patterns of pressure profiles. The pressure profiles for ignition initiated at the right half part of the duct showed a weak dependence on equivalence ratio, and showed no dependence on ignition position. However, the pressure profiles for ignition initiated at the left half part of the duct were heavily dependent on the combination of IP and empty set. More specifically, in the leanest (empty set = 0.4) and the richest (empty set = 4.0-5.0) cases, intensive periodical oscillations were the prime feature of the pressure profiles. With the moderate equivalence ratios (empty set = 0.8-3.0), periodical pressure oscillations were only observed for IP900. The maximum pressure peaks P-max were reached at empty set = 1.25 rather than at the highest reactivity empty set = 1.75 irrespective of ignition position. The ignition positions that produced the worst conditions were different, implying a complex influence of the combination of IP and empty set. (C) 2018 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.