Capacitive strain gauges on flexible polymer substrates for wireless, intelligent systems

Zeiser, R.; Fellner, Thomas; Wilde, Jürgen

doi:10.5194/jsss-3-77-2014

Cited by 34 publications

(21 citation statements)

References 7 publications

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“…These sensors are especially useful for measuring stresses in applications with high elasticity. They consume about ten times less energy than resistive sensors, which is very important in case of wireless systems [4]. Thus, capacitive strain sensors can be applied in the measurement of skin or tire strain [4,5,6].…”

Section: Introductionmentioning

confidence: 99%

“…The parallel-plate strain sensor is assembled by sandwiching a dielectric layer between two electrodes [6]. Whereas, the second type has in-plane electrodes parallel to their substrate [4,5]. Sensors with in-plane electrodes proved higher sensitivity, sensing linearity and lower hysteresis than parallel-plate-type capacitive strain sensors [5].…”

Section: Introductionmentioning

confidence: 99%

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Microstrip Patch Strain Sensor Miniaturization Using Sierpinski Curve Fractal Geometry

Herbko

Łopato

2019

Sensors

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In this paper miniaturization of a microstrip patch strain sensor (MPSS) using fractal geometry was proposed and analyzed. For this purpose, the transducer of Sierpinski curve geometry was utilized and compared with the most commonly utilized rectangular resonator-based one. Both sensors were designed for the same resonant frequency value (2.725 GHz). This fact allows analysis of the influence of the patch (resonator) shape and size on the resonant frequency shift. This is very important as the sensors with the same resonator shape but designed on various operating frequencies have various resonant frequency shifts. Simulation and experimental analysis for all sensors were carried out. A good convergence between results of simulation and measurements was achieved. The obtained results proved the possibility of microstrip strain sensor dimensions reduction using Sierpinski curve fractal geometry. Additionally, an influence of microstrip line deformation for proposed sensors was studied.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Microstrip Patch Strain Sensor Miniaturization Using Sierpinski Curve Fractal Geometry

Herbko

Łopato

2019

Sensors

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“…Along with the advantages of these sensors described above in terms of their fabrication and processed materials, these sensors exhibited a reasonably high G.F. The G.F. value was higher than other strain sensors that were polyimide-based [53,54], silicon-based [55] and fabric-based [56] used for biomedical applications. Figure 11 shows the change in the relative resistance of the sensors with respect to the induced strain in the vertical direction.…”

Section: Resultsmentioning

confidence: 97%

Gold/Polyimide-Based Resistive Strain Sensors

et al. 2019

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This paper presents the fabrication and implementation of novel resistive sensors that were implemented for strain-sensing applications. Some of the critical factors for the development of resistive sensors are addressed in this paper, such as the cost of fabrication, the steps of the fabrication process which make it time-consuming to complete each prototype, and the inability to achieve optimised electrical and mechanical characteristics. The sensors were fabricated via magnetron sputtering of thin-film chromium and gold layer on the thin-film substrates at defined thicknesses. Sticky copper tapes were attached on the two sides of the sensor patches to form the electrodes. The operating principle of the fabricated sensors was based on the change in their responses with respect to the corresponding changes in their relative resistance as a function of the applied strain. The strain-induced characteristics of the patches were studied with different kinds of experiments, such as consecutive bending and pressure application. The sensors with 400 nm thickness of gold layer obtained a sensitivity of 0.0086 Ω/ppm for the pressure ranging between 0 and 400 kPa. The gauge factor of these sensors was between 4.9–6.6 for temperatures ranging between 25 °C and 55 °C. They were also used for tactile sensing to determine their potential as thin-film sensors for industrial applications, like in robotic and pressure-mapping applications. The results were promising in regards to the sensors’ controllable film thickness, easy operation, purity of the films and mechanically sound nature. These sensors can provide a podium to enhance the usage of resistive sensors on a higher scale to develop thin-film sensors for industrial applications.

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“…Currently, commercial CSGs are available, and typically consist of a parallel plate design restricting strain measurements to those that are perpendicular to the gauge direction, are limited in the geometries they can monitor, or require bulky electromechanical devices for mechanical attachment 2,12 . These issues can be overcome by using CSGs having an interdigitated electrode design 13,24 . Interdigitated electrodes preserve the advantages associated with CSGs vs RSGs in harsh environments, while also providing a vehicle by which CSGs can integrate directly onto structural components.…”

Section: Introductionmentioning

confidence: 99%

Aerosol jet printed capacitive strain gauge for soft structural materials

et al. 2020

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Soft structural textiles, or softgoods, are used within the space industry for inflatable habitats, parachutes and decelerator systems. Evaluating the safety and structural integrity of these systems occurs through structural health monitoring systems (SHM), which integrate non-invasive/non-destructive testing methods to detect, diagnose, and locate damage. Strain/load monitoring of these systems is limited while utilizing traditional strain gauges as these gauges are typically stiff, operate at low temperatures, and fail when subjected to high strain that is a result of high loading classifying them as unsuitable for SHM of soft structural textiles. For this work, a capacitance based strain gauge (CSG) was fabricated via aerosol jet printing (AJP) using silver nanoparticle ink on a flexible polymer substrate. Printed strain gauges were then compared to a commercially available high elongation resistance-based strain gauge (HE-RSG) for their ability to monitor strained Kevlar straps having a 26.7 kN (6 klbf) load. Dynamic, static and cyclic loads were used to characterize both types of strain monitoring devices. Printed CSGs demonstrated superior performance for high elongation strain measurements when compared to commonly used HE-RSGs, and were observed to operate with a gauge factor of 5.2 when the electrode arrangement was perpendicular to the direction of strain.

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Capacitive strain gauges on flexible polymer substrates for wireless, intelligent systems

Cited by 34 publications

References 7 publications

Microstrip Patch Strain Sensor Miniaturization Using Sierpinski Curve Fractal Geometry

Microstrip Patch Strain Sensor Miniaturization Using Sierpinski Curve Fractal Geometry

Gold/Polyimide-Based Resistive Strain Sensors

Aerosol jet printed capacitive strain gauge for soft structural materials

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