Flow Dynamics of a Dodecane Jet in Oxygen Crossflow at Supercritical Pressures

TL;DR

This study uses large-eddy simulation to analyze the flow dynamics of a supercritical dodecane jet in oxygen crossflow, revealing how pressure and momentum flux ratios influence stability and mixing efficiency.

Contribution

It provides new insights into jet stability and mixing behavior at supercritical conditions using combined simulation and stability analysis methods.

Findings

Upstream shear layer stability varies with pressure and momentum flux ratio.

Density stratification at supercritical pressures affects shear layer stability.

Higher momentum flux ratios enhance mixing efficiency.

Abstract

In advanced aero-propulsion engines, kerosene is often injected into the combustor at supercritical pressures, where flow dynamics is distinct from the subcritical counterpart. Large-eddy simulation combined with real-fluid thermodynamics and transport theories of a N-dodecane jet in oxygen crossflow at supercritical pressures is presented. Liquid dodecane at 600 K is injected into a supercritical oxygen environment at 700 K at different supercritical pressures and jet-to-crossflow momentum flux ratios (J). Various vortical structures are discussed in detail. The results shown that, with the same jet-to-crossflow velocity ratio of 0.75, the upstream shear layer (USL) is absolutely unstable at 6.0 MPa (J = 7.1) and convectively unstable at 3.0 MPa (J = 13.2). This trend is consistent with the empirical criterion for the stability characteristics of a jet in crossflow at subcritical pressures (Jcr = 10). While decreasing J to 7.1 at 3.0 MPa, however, the dominant Strouhal number of the USL varies along the upstream jet trajectory, and the USL becomes convectively unstable. Such abnormal change in stability behavior can be attributed to the real-fluid effect induced by strong density stratification at pressure of 3.0 MPa, under which a point of inflection in the upstream mixing layer renders large density gradient and tends to stabilize the USL. The stability behavior with varying pressure and J is further corroborated by linear stability analysis. The analysis of spatial mixing deficiencies reveals that the mixing efficiency is enhanced at a higher jet-to-crossflow momentum flux ratio.