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用于在线密度-粘度测量的具有压电驱动的3D打印液体细胞谐振器

3D-Printed Liquid Cell Resonator with Piezoelectric Actuation for In-Line Density-Viscosity Measurements.

作者信息

Toledo Javier, Ruiz-Díez Víctor, Velasco Jaime, Hernando-García Jorge, Sánchez-Rojas José Luis

机构信息

Microsystems, Actuators and Sensors Lab, Universidad de Castilla-La Mancha, 13071 Ciudad Real, Spain.

出版信息

Sensors (Basel). 2021 Nov 18;21(22):7654. doi: 10.3390/s21227654.

DOI:10.3390/s21227654
PMID:34833730
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8624904/
Abstract

The in-line monitoring of liquid properties, such as density and viscosity, is a key process in many industrial areas such as agro-food, automotive or biotechnology, requiring real-time automation, low-cost and miniaturization, while maintaining a level of accuracy and resolution comparable to benchtop instruments. In this paper, 3D-printed cuboid-shaped liquid cells featuring a rectangular vibrating plate in one of the sides, actuated by PZT piezoelectric layers, were designed, fabricated and tested. The device was resonantly excited in the 3rd-order roof tile-shaped vibration mode of the plate and validated as a density-viscosity sensor. Furthermore, conditioning circuits were designed to adapt the impedance of the resonator and to cancel parasitic effects. This allowed us to implement a phase-locked loop-based oscillator circuit whose oscillation frequency and voltage amplitude could be calibrated against density and viscosity of the liquid flowing through the cell. To demonstrate the performance, the sensor was calibrated with a set of artificial model solutions of grape must, representing stages of a wine fermentation process. Our results demonstrate the high potential of the low-cost sensor to detect the decrease in sugar and the increase in ethanol concentrations during a grape must fermentation, with a resolution of 10 µg/mL and 3 µPa·s as upper limits for the density and viscosity, respectively.

摘要

在线监测液体性质,如密度和粘度,是许多工业领域(如农业食品、汽车或生物技术)中的关键过程,需要实时自动化、低成本和小型化,同时保持与台式仪器相当的精度和分辨率水平。在本文中,设计、制造并测试了一种3D打印的长方体形液体池,其一侧具有由PZT压电层驱动的矩形振动板。该装置在板的三阶屋顶瓦形振动模式下被共振激发,并被验证为密度-粘度传感器。此外,设计了调节电路以调整谐振器的阻抗并消除寄生效应。这使我们能够实现基于锁相环的振荡器电路,其振荡频率和电压幅度可以根据流过液体池的液体的密度和粘度进行校准。为了展示其性能,该传感器用一组葡萄汁人工模型溶液进行了校准,这些溶液代表了葡萄酒发酵过程的各个阶段。我们的结果表明,这种低成本传感器具有很高的潜力,能够在葡萄汁发酵过程中检测糖含量的降低和乙醇浓度的增加,密度和粘度的分辨率分别为10 µg/mL和3 µPa·s作为上限。

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2
3D printed deformable sensors.3D打印可变形传感器。
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3
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Sci Rep. 2019 Dec 27;9(1):20177. doi: 10.1038/s41598-019-56350-w.
4
3D Printed Sensors for Biomedical Applications: A Review.3D 打印传感器在生物医学中的应用:综述。
Sensors (Basel). 2019 Apr 10;19(7):1706. doi: 10.3390/s19071706.
5
3D Printing Technologies for Flexible Tactile Sensors toward Wearable Electronics and Electronic Skin.面向可穿戴电子设备和电子皮肤的柔性触觉传感器的3D打印技术
Polymers (Basel). 2018 Jun 7;10(6):629. doi: 10.3390/polym10060629.
6
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7
Three-dimensional printing of piezoelectric materials with designed anisotropy and directional response.具有设计的各向异性和定向响应的压电材料的三维打印。
Nat Mater. 2019 Mar;18(3):234-241. doi: 10.1038/s41563-018-0268-1. Epub 2019 Jan 21.
8
Low-Cost and Lightweight 3D-Printed Split-Ring Resonator for Chemical Sensing Applications.低成本、轻量化的 3D 打印分裂环谐振器用于化学传感应用。
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9
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10
Adding Biomolecular Recognition Capability to 3D Printed Objects.为 3D 打印物体添加生物分子识别能力。
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