Numerical analysis of heat flow in wall of detonation tube during pulse detonation cycle

The thermal ablation of the detonation tube is a key factor in pulse detonation engine (PDE) research. In this study, a symmetric two-phase detonation model and a cylinder heat conduction model are used for studying the features of transient heat transfer. The effects of the tube material and size on the heat transfer are analyzed using this model. To capture the shock wave simply and accurately, the space-time conservation element and solution element method and the finite-difference method are used for simulating the interior flow and the heat-transfer process of the detonation tube, respectively. The numerical results are consistent with the experimental results. The temperature of the PDE wall increases by 1.5 K per four detonation cycles at a frequency of 20 Hz. Then, the effects of the materials of the tube wall and the diameter and length of the tube are investigated. The inner flow greatly affects the inner-wall temperature, particularly the influence is obvious when the tube materials change. Increasing the diameter can improve the heat dissipation, and reducing the length smooths the temperature gradient along the axis. The results of this study provide guidance for the design of PDEs.

Automated summary

In this study, a symmetric two-phase detonation model and a cylinder heat conduction model were used to analyze the features of transient heat transfer in the detonation tube of a pulse detonation engine (PDE). The effects of tube material and size on heat transfer were investigated, with numerical results showing significant impact of inner flow and tube material on PDE wall temperature.