We give representative results for our detonation model and summarize the one-dimensional stability behaviour in parameter space.
The gas ahead of the detonation wave is assumed to be at rest with a constant velocity of sound.
By contrast, the reaction zone remains closely coupled to the shock wave in figure 4(b), indicating the successful initiation of a quasi-steady detonation.
Laboratory experiments were conducted in a water tank to investigate the rise through the atmosphere of thermals generated by the detonation of surplus military munitions.
For practical application of the critical energy equation (6.3) in real gas detonations, various parameters need to be determined.
No piston or cylinder damage has been reported, suggesting that no pre-ignition or detonation occurred and that the compression ratio was correct for the fuel.
Several papers have been published with regard to detonation wave propagation.
This is true for all particles before detonation failure, that is, all in figure 7 except particle path 10.