Abstract
The paper presents the experimental research findings for the integral characteristics of processes developing when two-phase liquid droplets collide in a heated gas medium. The experiments were conducted in a closed heat exchange chamber space filled with air. The gas medium was heated to 400–500 °C by an induction system. In the experiments, the size of initial droplets, their velocities and impact angles were varied in the ranges typical of industrial applications. The main varied parameter was the percentage of vapor (volume of bubbles) in the droplet (up to 90% of the liquid volume). The droplet collision regimes (coalescence, bounce, breakup, disruption), size and number of secondary fragments, as well as the relative volume fraction of vapor bubbles in them were recorded. Differences in the collision regimes and in the distribution of secondary fragments by size were identified. The areas of liquid surface before and after the initial droplet breakup were determined. Conditions were outlined in which vapor bubbles had a significant and, on the contrary, fairly weak effect on the interaction regimes of two-phase droplets.
Highlights
IntroductionTwo-phase gas-vapor-droplet flows are extensively used in power supply systems due to their high integral characteristics of heat transfer as compared with single-phase flows [1,2,3]
The second type of droplets with a low relative volume fraction of vapor is typical of cases when water is superheated when moving through a copper tube and nozzle (Video S(B): Water droplet and two-phase droplet with 30% of vapor)
Specific aspects of the disruption of four two-phase droplet types were described when they collide with water droplets without bubbles
Summary
Two-phase gas-vapor-droplet flows are extensively used in power supply systems due to their high integral characteristics of heat transfer as compared with single-phase flows [1,2,3]. The processes developing from the collisions of droplets [4,5] containing gas or vapor bubbles are comparable to the micro-explosive destruction of liquid [6,7]. In that case, the second phase in a water droplet emerges as a result of fast boiling liquid passing through a pipeline [8] and continuing its movement in a high-temperature gas medium [9]. Gas bubbles can end up in liquid droplets when they collide during spraying [10]. Similar processes occur when vapor bubbles leave a liquid droplet. The research [12] was conducted for two cases:
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