Scramjet: Unblocker

This research was supported by the Hypersonic Air-breathing Propulsion Consortium (HAPC).

[1] Curran, E. T. (2001). Scramjet engines: the first forty years. Journal of Propulsion and Power , 17(6), 1138-1148. [2] Matsuo, K., et al. (2009). Unstart phenomena in scramjet inlets. Progress in Aerospace Sciences , 45(8), 285-310. [3] Do, H., et al. (2011). Plasma-assisted flame stabilization in a scramjet. Combustion and Flame , 158(4), 755-763. [4] Reed, A. J. (2024). Fast-acting bleed systems for hypersonic inlet control. AIAA Journal , 62(1), 112-125.

| Parameter | Value | |--------------------------|--------------| | Freestream Mach number | 6.0 | | Inlet capture height | 0.15 m | | Combustor length | 0.8 m | | Equivalence ratio (nom.) | 0.9 | | Unblocker slot width | 2 mm | scramjet unblocker

A. J. Reed, M. Takahashi Laboratory for Advanced Propulsion Dynamics, Institute for Hypersonic Systems

Scramjet, unstart, thermal choking, hypersonic propulsion, unblocker mechanism 1. Introduction This research was supported by the Hypersonic Air-breathing

A 2D Reynolds-Averaged Navier-Stokes (RANS) simulation with a shear stress transport (SST) turbulence model was conducted for a Mach 6 flight condition with a hydrogen-fueled scramjet.

The current design assumes a single unstart event per flight. Repeated cycling may lead to fatigue of the hatch mechanism. Furthermore, the plasma actuator's power draw (≈1 kW) may be prohibitive for small-scale scramjets. (2001)

Development and Simulation of a Dynamic Scramjet Unblocker Mechanism for Hypersonic Inlet Unstart Mitigation