What question did this study set out to answer?

This research aims to understand how chamber pressure and oxidizer port velocity influence combustion modes in hybrid rockets.

March 26, 2026Open Access

Effects of Chamber Pressure and Oxidizer Port Velocity on the Combustion Mode of a Liquid Oxygen - Solid Fuel Tube

Key Points

This research aims to understand how chamber pressure and oxidizer port velocity influence combustion modes in hybrid rockets.
Conducted combustion experiments with a solid fuel tube using liquid oxygen as the oxidizer.
Vary chamber pressure and oxidizer port velocity during testing.
Measured the effects on regression mode, flame spread, quenching distance, and heat flux.
High chamber pressure leads to flame spread due to increased heat flux and reduced quenching distance.
Low oxidizer port velocity also contributes to flame spread by decreasing quenching distance and affecting heat transfer.
Combined effects of chamber pressure and oxidizer port velocity promote flame spread onset.

Abstract

To identify the cause of backfiring in an axial-injection end-burning hybrid rocket using liquid oxygen, combustion experiments were conducted with a solid fuel tube of 2.0 mm port diameter and liquid oxygen as oxidizer. Results showed that under high chamber pressure or low oxidizer port velocity, the regression mode could not be maintained, and flame spread occurred. This is attributed to a reduction in quenching distance and increased heat flux to the fuel surface due to increased chamber pressure. Additionally, decreased oxidizer port velocity shortens the quenching distance, increases heat flux to the fuel, and reduces heat transfer to liquid oxygen. These effects are believed to promote flame spread onset.

Effects of Chamber Pressure and Oxidizer Port Velocity on the Combustion Mode of a Liquid Oxygen - Solid Fuel Tube

Key Points

Abstract

Cite This Study