The burning number of a graph is the minimal number of steps that are needed to burn all of its vertices, with the following procedure: at each step, one can choose a point to set on fire, and the fire propagates constantly at unit speed along the edges of the graph. In joint work with Alice Contat, we consider two natural random burning procedures in the discrete Euclidean torus with side-length n, in which the points that we set on fire at each step are random variables. Our main result deals with the case where at each step, the law of the new point that we set on fire conditionally on the past is the uniform distribution on the complement of the set of vertices burned by the previous points. In this case, we prove that as n tends to infinity, the corresponding random burning number (i.e, the first step at which the whole torus is burned) is asymptotic to T times n^{d/(d+1)} in probability, where T is the explosion time of a so-called generalised Blasius equation.