Transient conjugate cooling in a confined cylindrical cavity with annular multi-jet impingement

The purpose of this study is to investigate the start-up (0–3 s) transient conjugate cooling behavior in a confined cylindrical cavity driven by annular-plenum multi-jet impingement. Although jet impingement cooling has been extensively studied under steady-state conditions, existing research has primarily focused on single-jet configurations or simplified open domains, with limited attention paid to the start-up thermal response of confined multi-jet systems. In practical high heat-flux applications, however, the transient cooling capacity during the initial operating stage is often critical for preventing local overheating and thermal failure. To address this gap, a normalized cooling index (NCI) is induced to transient cooling for evaluating both mean cooling and hot-spot suppression.

A three-dimensional transient conjugate heat-transfer model is developed using unsteady Reynolds-averaged Navier–Stokes (URANS) simulation with the SST$k-ω$ turbulence model. An initial-temperature treatment is introduced for the solid domain to effectively capture the start-up thermal evolution of the coupled fluid–solid system. Grid independence and model reliability are validated against a benchmark case of a circular impinging jet. The influence of Reynolds number (⁠$Re$⁠),), inlet temperature (⁠$Tin$⁠) and geometric height ratio (⁠$H/D$⁠) are systematically investigated. The proposed NCI is defined by combining the average solid temperature $T¯s$ and the maximum local temperature (⁠$Tm$⁠), allowing simultaneous evaluation of mean cooling performance and local thermal non-uniformity.

The start-up cooling process exhibits a two-stage behavior. The early stage is convection-dominated and characterized by stagnation impingement, wall-jet development and cavity recirculation, whereas the later stage is increasingly limited by solid thermal capacitance and internal conduction. Increasing $Re$ improves both mean cooling and hot-spot suppression; however, the enhancement becomes progressively weaker due to confinement effects, jet interaction and crossflow interference. Variations in $Tin$ mainly affect the absolute temperature level and show little influence on NCI within the range of 283–303 K. A moderate geometric height ratio (⁠$H/D$$≈$ 0.5) provides the best overall cooling performance by balancing jet impingement intensity and flow recirculation. The optimal operating condition is identified as $Uin$ = 40 m/s, $Tin$ = 283 K and $H/D$ = 0.5.

This study extends conventional impingement-cooling research from steady-state analysis to start-up transient conjugate cooling in a confined cylindrical cavity with annular multi-jet impingement. It clarifies the stage-dependent cooling mechanisms governing transient thermal evolution and introduces NCI as a unified dimensionless metric for assessing overall cooling performance and hot-spot mitigation. The results provide theoretical support and design guidance for thermal management in confined high heat-flux systems requiring rapid and reliable start-up cooling.