Improving and Predicting Fluid Atomization via Hysteresis‐Free Thickness Vibration of Lithium Niobate

Abstract

Acoustically driven atomization from the broad perspective of materials choice, vibration mode, and fluid characteristics is considered to identify a simple method for improving both the understanding of the atomization phenomena and the overall efficiency of atomization. Whether by the definition of a “figure of merit” (a function of the transducer quality factor and electromechanical coupling coefficient), its output vibration displacement at a given input power, or the fluid flow rate during atomization, it is found that the combination of single‐crystal 127.86° Y‐rotated lithium niobate and thickness‐mode vibration produces an order of magnitude greater atomization flow rate and efficiency in comparison to all known atomizers, including classic lead zirconate‐based devices and newer, Rayleigh wave or Rayleigh/Lamb spurious‐mode‐based devices alike. By using this improved approach, for the first time, fluids with viscosities up to 48 cP are reported to be atomized, and an atomization Reynolds number ReA is defined which can be used to both predict the atomization flow rate for ReA ≳ 40 and the inability to atomize a given fluid at a particular vibration amplitude when ReA ≲ 40.

Document Details

Document Type

Pub Defense Publication

Publication Date

Dec 07, 2017

Source ID

10.1002/adfm.201704359

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