设计和制造灵敏度更高的金属电阻应变传感器

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2024-09-13 DOI:10.1109/LSENS.2024.3460399

Roberto S. Aga;Lemuel Duncan;Laura Davidson;Fahima Ouchen;Rachel Aga;Emily M. Heckman;Carrie M. Bartsch

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引用次数: 0

摘要

这封信报告了电阻应变传感器的新型设计及其制造方法。该传感器由印刷银（Ag）制成，但其灵敏度（通过量规系数（GF）测量）超过了大多数商用金属箔应变片（COTS）。这些 COTS 的 GF 值（∼2）很低，因为它们的压阻效应很弱。因此，它们的灵敏度主要受几何效应的影响。在这种设计中，GF 不受 Ag 中弱压阻效应的限制。其更高的灵敏度（GF∼55）源于在印刷的银垫上激光烧结导电交叉图案时产生的结点。交叉图案由一条低电阻率垂直轨迹和一条高电阻率水平轨迹组成。电阻率的差异是通过改变激光烧结功率来实现的。连接高电阻率和低电阻率轨迹的交界处是具有界面电阻的边界。这种界面电阻对应变的敏感度很高，因此需要设计和制造不同的电阻应变传感器。

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Design and Fabrication of a Metal Resistance Strain Sensor With Enhanced Sensitivity

This letter reports a novel design of a resistance strain sensor and its method of fabrication. The sensor is made of printed silver (Ag), but its sensitivity, which is measured by the gauge factor (GF), surpasses most commercial metal foil strain gauges (COTS). These COTS have a low GF (∼2) because they exhibit a weak piezoresistive effect. As a result, their sensitivity is dominated by the geometric effect. In this design, the GF is not limited by the weak piezoresistive effect in Ag. Its enhanced sensitivity (GF∼55) originates from the junctions that are created when a conductive cross-pattern is laser sintered on a printed Ag pad. The cross-pattern consists of a low-resistivity vertical trace and a high-resistivity horizontal trace. The difference in resistivity is achieved by changing the laser sintering power. The junction that joins the high and the low resistivity traces is a boundary with interfacial resistance. This interfacial resistance exhibits high sensitivity to strain leading to a different design and fabrication of a resistance strain sensor.

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194