Advances in Liquid Atomization via Flash Boiling—A Global Overview

Tali Bar-Kohany*, Merav Arogeti, Avihai Malka, Eran Sher

*Corresponding author for this work

Research output: Contribution to journalReview articlepeer-review

Abstract

A wide range of recent applications require high-quality sprays that are characterized by extremely small-sized droplets, a narrow droplet size distribution, and a short breakup length. Fuel injection systems in propulsion units, energy storage, medical implementations, printings, and coatings are just a few examples. Flash-boiling atomization is a unique method that was extensively developed during the past two to three decades and has been proven to generate high-quality demanded sprays. In flash-boiling atomization, the liquid is forced to reach a metastable superheated state by either rapid heating or rapid pressure drop, where vapor bubbles nucleate, become fast-growing, and subsequently break down the liquid into a fine spray in a very short time. This present article focuses on flash-boiling atomization via rapid depressurization, which is presently more relevant to energy systems. The field of flash-boiling atomization has seen rapid growth and popularity in the past two decades. The aim of this article is to quantitatively portray the landscape and evolutionary trajectory of flash-boiling atomization research and applications and to detect new research frontiers and emerging trends in the literature on flash-boiling atomization. We briefly review the basic theories of the flash-boiling atomization mechanism present a comprehensive overview of the field, from its birth in approximately the 1970s to the present, and provide a database comprising 386 articles published on the topic of flash-boiling atomization. We visualize the intellectual structure of flash-boiling atomization research and applications and track its evolvement over the past five decades, thus providing a global overview and a comprehensive understanding of the development of flash-boiling atomization research and emerging applications.

Original languageEnglish
Article number6763
JournalEnergies
Volume16
Issue number19
DOIs
StatePublished - Oct 2023

Funding

FundersFunder number
Minerva Research Center
Max-Planck-GesellschaftAZ5746940764

    Keywords

    • atomization
    • cavitation
    • depressurization
    • flash boiling
    • fuel injection
    • spray

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