Thermal nonequilibrium and mechanical forces induced breakup and droplet formation of superheated liquid jets under depressurized release

Superheated liquid jets disintegrate into numerous droplets when released into the ambient with lower saturated pressure, driven by thermal nonequilibrium induced flashing and the accompanying mechanical forces. Such a phenomenon facilitates fuel atomization in energy utilization while posing a serious threat during accidental releases. In this work, the breakup and droplet formation of superheated liquid jets under depressurized releases were investigated with an experimental 20 L tank. A high-speed camera was utilized to characterize breakup behaviors. The interaction between thermodynamic and mechanical effects during depressurization was dis-cussed based on linear stability analysis and bubble dynamics. Furthermore, the quantitative relationship be-tween the two driving effects under different conditions was established using dimensionless and multiple regression analyses. Results show that the thermodynamic effect increases with the decreased mechanical effect during depressurization because of the increased energy of bubble burst, regardless of the external or internal flashing regime. Non-flashing, partially flashing, and fully flashing breakup modes are identified. The dimen-sionless and multiple regression analyses show that in addition to thermodynamic (Ja, rho v/rho l, Rp, and rip) and mechanical (Wev and Oh) effects, the inhibition induced by the cooling effect (Pr and Ec) should not be over-looked. The quantitative expression among them agrees well with experimental data with R2 = 0.976.

Automated summary

Superheated liquid jets disintegrate into droplets due to thermal nonequilibrium induced flashing and mechanical forces during depressurization. This study investigates the breakup and droplet formation of superheated liquid jets under depressurized releases using an experimental tank. The interaction between thermodynamic and mechanical effects is discussed and a quantitative relationship is established. The results show different breakup modes and highlight the importance of considering the cooling effect in addition to thermodynamic and mechanical effects.