A PZT-driven atomizer based on a vibrating flexible membrane and a micro-machined trumpet-shaped nozzle array

Jeng, Yeau-Ren; Su, Chien-Chan; Feng, Guo-Hua; Peng, Yu-Yin; Chien, Ghin-Pin

doi:10.1007/s00542-009-0844-z

Cited by 8 publications

(1 citation statement)

References 16 publications

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“…The power transfer from the piezoelectric transducer to the fluid was more efficient at lower frequencies near the fundamental cavity resonant mode. Jeng et al devised a PZT-driven atomizer consisting of a flexible membrane and a micromachined trumpet-shaped nozzle array [58]. The atomizer employed a PZT bimorph plate attached to a liquid-proof HDPE (high density polyethylene) membrane with a low Young's modulus to generate a pressure wave in the liquid reservoir.…”

Section: Active and Passive Meshmentioning

confidence: 99%

On the Development of Focused Ultrasound Liquid Atomizers

Al‐Jumaily

Meshkinzar

2017

Advances in Acoustics and Vibration

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This paper reviews the evolution of focused ultrasonic transducers of various kinds for fluid atomization and vaporization. Ultrasonic transducers used for atomization purposes in biomedical, pharmaceutical, or industrial applications, such as surface acoustic wave (SAW) transducers, array of micromachined nozzles, and Fourier horn micromachined nozzles with or without a central channel, are all presented and compared. For simplicity of manufacturing and low cost, we focus on plates and curved and corrugated structures for biomedical humidification.

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Section: Active and Passive Meshmentioning

confidence: 99%

On the Development of Focused Ultrasound Liquid Atomizers

Al‐Jumaily

Meshkinzar

2017

Advances in Acoustics and Vibration

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

Collignon

Manor

Friend

2017

Adv Funct Materials

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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.

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Effect of water microdroplet size on the removal of indoor particulate matter

Lee

2020

Building and Environment

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A PZT-driven atomizer based on a vibrating flexible membrane and a micro-machined trumpet-shaped nozzle array

Cited by 8 publications

References 16 publications

On the Development of Focused Ultrasound Liquid Atomizers

On the Development of Focused Ultrasound Liquid Atomizers

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

Effect of water microdroplet size on the removal of indoor particulate matter

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