Sentence examples for resulting ignition from inspiring English sources

The resulting ignition model was found to reproduce experimental mixture ignition delay times well.

The effects of particle size, milling time, and inclusion content on the resulting ignition delay, product particle size distributions, and microexplosion tendencies are reported.

At these conditions the fuel, oxidizer and intermediate species may exist in a supercritical state during combustion, requiring a real gas equation of state to incorporate non-ideal effects on thermodynamics, chemical kinetics, and the resulting ignition characteristics.

At higher pulse-repetition frequencies (⩾10 kHz), multiple pulses are all coupled into a single ignition kernel, thus the resulting ignition kernel size and the total energy deposition into the kernel are increased, resulting in a faster transition into a self-propagating flame.

At higher pressures, turbulent flows caused the ignition temperatures to continue to follow the second limit resulting in ignition temperatures higher than the laminar values.

Hydrogen-jet flames resulting from ignition of unintended releases can be extensive in length and pose hazards associated with radiation and impingement onto objects, combustible materials and people.

Hydrogen jet flames resulting from ignition of unintended releases can be extensive in length and pose significant radiation and impingement hazards.

The hot-surface temperature resulting in ignition is found to be weakly sensitive to equivalence ratio with a mean value of 980 K for mixtures with equivalence ratios between 0.75 and 3 at 100 kPa.

This transport is governed by the low velocities of the coflow and as a result, ignition delay times and the time until a steady state of combustion is attained are not solely related to jet time scales.

The nitrogen-filled ignition condition resulted in smooth ignition, while the oxygen-filled ignition condition induced two-step ignition following the sequence of ignition with high-pressure peak, temporary extinction, and re-ignition.

The project also developed methods for predicting scenario-based explosion frequencies, using frequencies of initiating events and conditional probabilities of immediate ignition and delayed ignition resulting in explosion.