Volume and Frequency-Independent Spreading of Droplets Driven by Ultrasonic Surface Vibration

Trapuzzano, Matthew; Tejada-Martínez, Andrés; Guldiken, Rasim; Crane, Nathan B.

doi:10.3390/fluids5010018

Cited by 7 publications

(3 citation statements)

References 30 publications

(59 reference statements)

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“…This theory fits very well with the research of Trapuzzano [6] , [20] , who observed that by modifying the vibration amplitude, the contact angle can be modulated.…”

Section: Introductionsupporting

confidence: 90%

Energetic study of ultrasonic wettability enhancement

Sarasua

Ruiz‐Rubio

Aranzabe

et al. 2021

Ultrasonics Sonochemistry

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“…This theory fits very well with the research of Trapuzzano [6] , [20] , who observed that by modifying the vibration amplitude, the contact angle can be modulated.…”

Section: Introductionsupporting

confidence: 90%

Energetic study of ultrasonic wettability enhancement

Sarasua

Ruiz‐Rubio

Aranzabe

et al. 2021

Ultrasonics Sonochemistry

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“…It has been studied by many authors, including Lauterborn [13][14][15] and Mason [16], who conclude that the size, number and distribution of bubbles depend mainly on the ultrasonic parameters (amplitude and frequency) and the liquid itself (volume, surface tension, density and viscosity). However, another physical phenomenon has been described by several authors [17][18][19][20]: the contact angle is changed when liquids are exposed to low and high frequency vibration. Manor et al [21] describe a vibration driving force F [N] at megasonic frequency.…”

Section: Introductionmentioning

confidence: 99%

Ultrasound and Eco-Detergents for Sustainable Cleaning

Sarasua Miranda,

Ruiz Rubio,

Trinidad Cristobal

et al. 2023

Processes

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Green chemistry faces a major challenge imposed by the Sustainable Development Goals (6, 14 and 15) defined in the 2030 Agenda. In the case of cleaning products (detergents), the challenges often become a paradox: even if it is biodegradable, no surfactant is harmless to aquatic life. Compared to other studies in the field, this paper covers ultrasound–detergent interactions beyond the cavitation removal process. It also considers synergistic effects with regard to the initial wetting phase and final rinsing. It concludes that the best detergent–ultrasound combination is that which minimises receding and critical sliding angles. At the same time, detergent concentration should be reduced so as to just to capture grease in micelles and avoid reattachment during rinsing. In combination with ultrasound, the concentration of eco-detergents can thus be reduced by up to 10% of their nominal value while attaining the same results.

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“…Each liquid presents a different atomization threshold [26] that must be adjusted to avoid loss of mass. However, vibration can dramatically increase wettability between solid and liquid phases [27] owing to the vibration-induced force on the surface [28]. This phenomenon helps to form a stable capillary bridge between the vibrating surface and the dirty one.…”

Section: Introductionmentioning

confidence: 99%

Non-Immersion Ultrasonic Cleaning: An Efficient Green Process for Large Surfaces with Low Water Consumption

et al. 2021

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Ultrasonic cleaning is a developed and widespread technology used in the cleaning industry. The key to its success over other cleaning methods lies in its capacity to penetrate seemingly inaccessible, hard-to-reach corners, cleaning them successfully. However, its major drawback is the need to immerse the product into a tank, making it impossible to work with large or anchored elements. With the aim of revealing the scope of the technology, this paper will attempt to describe a more innovative approach to cleaning large area surfaces (walls, floors, façades, etc.) which involves applying ultrasonic cavitation onto a thin film of water, which is then deposited onto a dirty surface. Ultrasonic cleaning is an example of the proliferation of green technology, requiring 15 times less water and 115 times less power than conventional high-pressurized waterjet cleaning mechanisms. This paper will account for the physical phenomena that govern this new cleaning mechanism and the competition it poses towards more conventional pressurized waterjet technology. Being easy to use as a measure of success, specular surface cleaning has been selected to measure the degree of cleanliness (reflectance) as a function of the process’s parameters. A design of experiments has been developed in line with the main process parameters: amplitude, gap, and sweeping speed. Regression models have also been used to interpret the results for different degrees of soiling. The work concludes with the finding that the proposed new cleaning technology and process can reach up to 98% total cleanliness, without the use of any chemical product and with very low water and power consumption.

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Volume and Frequency-Independent Spreading of Droplets Driven by Ultrasonic Surface Vibration

Cited by 7 publications

References 30 publications

Energetic study of ultrasonic wettability enhancement

Energetic study of ultrasonic wettability enhancement

Ultrasound and Eco-Detergents for Sustainable Cleaning

Non-Immersion Ultrasonic Cleaning: An Efficient Green Process for Large Surfaces with Low Water Consumption

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