| 应用领域 |
其他 |
| 检测样本 |
其他 |
| 检测项目 |
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| 参考标准 |
暂无 |
The ignition characteristics of a premixed bluff-body burner under lean conditions were
investigated experimentally and numerically with a physical model focusing on ignition
probability. Visualisation of the flame with a 5 kHz OH* chemiluminescence camera
confirmed that successful ignitions were those associated with the movement of the
kernel upstream, consistent with previous work on non-premixed systems. Performing
many separate ignition trials at the same spark position and flow conditions resulted
in a quantification of the ignition probability Pign, which was found to decrease with
increasing distance downstream of the bluff body and a decrease in equivalence ratio.
Flows corresponding to flames close to the blow-off limit could not be ignited, although
such flames were stable if reached from a richer already ignited condition. A detailed
comparison with the local Karlovitz number and the mean velocity showed that regions
of high Pign are associated with low Ka and negative bulk velocity (i.e. towards the
bluff body), although a direct correlation was not possible. A modelling effort that
takes convection and localised flame quenching into account by tracking stochastic
virtual flame particles, previously validated for non-premixed and spray ignition, was
used to estimate the ignition probability. The applicability of this approach to premixed
flows was first evaluated by investigating the model’s flame propagation mechanism
in a uniform turbulence field, which showed that the model reproduces the bending
behaviour of the ST-versus-u� curve. Then ignition simulations of the bluff-body burner
were carried out. The ignition probability map was computed and it was found that the
model reproduces all main trends found in the experimental study.
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