A methodology for the estimation of ignition delay times in forest fire modelling

“…The FPA has been previously used to study ignition of natural fuels such as peat (Hadden et al 2013) and pine needles (Schemel et al 2008). Ignition by exposure to non-constant heat fluxes has previously been studied by Reszka et al (2012) for application to polymeric materials.…”

An experimental assessment of the ignition of forest fuels by the thermal pulse generated by the Cretaceous–Palaeogene impact at Chicxulub

“…The FPA has been previously used to study ignition of natural fuels such as peat (Hadden et al 2013) and pine needles (Schemel et al 2008). Ignition by exposure to non-constant heat fluxes has previously been studied by Reszka et al (2012) for application to polymeric materials.…”

An experimental assessment of the ignition of forest fuels by the thermal pulse generated by the Cretaceous–Palaeogene impact at Chicxulub

“…This section recalls the work of [1,2,3,4,11], using a particular formalism which provides a simple expression for the target temperature response to a Fourier decomposition of the incoming heat flux, and suggesting a slight difference for low thermal inertia solids. Indeed, the study of [11] considers series expansion around t → ∞ whereas this study considers a higher series expansion (in comparison with the high thermal inertia case) around t → 0.…”

“…For high thermal inertia solids, the associated surface heat loss can be neglected as shown in [4,11] whereas it is taken into account for low thermal inertia solids. Hence, kernel K is provided by the classical solution suggested in [2,11] for high thermal inertia solids.…”

“…Application of this simplified kernel to a linear time-dependent heat flux does not strictly allow recovering the series expansion result of [4] since the series expansion has been made before calculating the convolution. The solution suggested here is nevertheless more accurate regarding the exact solution than the solution proposed in [4] which has been experimentally validated, thus validating the simplified kernel. Indeed, in most practical cases, the ignition time is lower than the kernel characteristic time and the series expansion provides an efficient approximation.…”

“…Ignition is thus modeled as a one-dimensional heat conduction problem as proposed by [2] for thermally thick surfaces and as a zerodimension heat transfer problem for thermally thin particles as suggested in [3]. In order to mimic more realistic fire scenarios, an improvement of this theory is proposed in [4], where the radiant heat flux is suggested to be linearly time depending, as suggested by [5] to take into account the time-varying heat flux on a stationary target exposed to a spreading fire front. Using this approach, the global trend of the incoming radiant heat flux can be taken into account.…”

Quantification of ignition time uncertainty based on the classical ignition theory and Fourier analysis

Review of Pathways for Building Fire Spread in the Wildland Urban Interface Part I: Exposure Conditions