MULTIFUNCTIONAL MICROPILLAR-ENABLED ACOUSTIC WAVE VISCOMETER

Organization Name

Northeastern University

Inventor(s)

Hongwei Sun of Lexington MA (US)

Ilia Chiniforooshan Esfahani of Boston MA (US)

MULTIFUNCTIONAL MICROPILLAR-ENABLED ACOUSTIC WAVE VISCOMETER - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240011881 titled 'MULTIFUNCTIONAL MICROPILLAR-ENABLED ACOUSTIC WAVE VISCOMETER

Simplified Explanation

The abstract describes a micropillar-enabled acoustic wave viscometer that includes a quartz crystal microbalance substrate, at least one micropillar, and a film. The micropillar is positioned on the substrate and extends perpendicular to it, with a defined height between its first and second ends. The film is located between the micropillar and the substrate.

• The patent application describes a viscometer device that utilizes micropillars and a quartz crystal microbalance substrate.
• The micropillar is placed on the substrate and extends vertically, creating a defined height.
• A film is present between the micropillar and the substrate.

Potential Applications:

• This technology can be used in various industries that require accurate viscosity measurements, such as pharmaceuticals, food and beverage, and chemical manufacturing.
• It can be utilized in research laboratories for studying fluid dynamics and rheology.

Problems Solved:

• The micropillar-enabled acoustic wave viscometer provides a more precise and sensitive method for measuring viscosity compared to traditional viscometers.
• It allows for real-time monitoring of viscosity changes, enabling better control and optimization of manufacturing processes.

Benefits:

• The use of micropillars and a quartz crystal microbalance substrate enhances the sensitivity and accuracy of viscosity measurements.
• The device offers a non-invasive and non-destructive method for viscosity analysis.
• Real-time monitoring capability allows for immediate adjustments and optimization of processes, leading to improved product quality and efficiency.

Original Abstract Submitted

a micropillar-enabled acoustic wave (�paw) viscometer including a quartz crystal microbalance (qcm) substrate; at least one micropillar having a first end and a second end, defining a height therebetween, the at least one micropillar disposed on to the qcm substrate at the first end and extending perpendicular to the qcm substrate; and a film disposed between the at least one micropillar and the qcm substrate.