Dumitru Oancea scite author profile

The flame propagation during the deflagration of the propane−air mixtures with variable initial concentration, pressure, and temperature ([C 3 H 8 ] = 2.60−6.20 vol %, p 0 = 30−200 kPa, and T 0 = 298−433 K) in a spherical closed vessel with central ignition was monitored by means of pressure measurements. Using an improved relationship for the burnt mass fraction, the burning velocities were calculated from pressure−time records over an extended duration of spherical propagation. A very good agreement was found between the burning velocities of atmospheric laminar C 3 H 8 /air flames and literature data. Computed burning velocities, obtained from numerical modeling of one-dimensional laminar flames using two detailed chemical kinetic schemes (Warnatz mechanism and GRI Mech 3.0, respectively) are discussed in comparison to experimental burning velocities. The measured burning velocities are correlated with pressure and temperature using a power law; the baric and thermal exponents, ν and μ, lie within the usual range characteristic to alkane−air laminar flames.

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Dumitru Oancea

Inert gas influence on the laminar burning velocity of methane-air mixtures

Burning velocity evaluation from pressure evolution during the early stage of closed-vessel explosions

Temperature and pressure influence on explosion pressures of closed vessel propane–air deflagrations

Normal burning velocity and propagation speed of ethane–air: Pressure and temperature dependence

Burning Velocity of Propane–Air Mixtures from Pressure–Time Records during Explosions in a Closed Spherical Vessel

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