Foil Strain Gauges Using Piezoresistive Carbon Nanotube Yarn: Fabrication and Calibration

Abot, Jandro L.; Gongora-Rubio, Mário Ricardo; Anike, Jude C.; Kiyono, César Y.; Mello, Luiz Guilherme Marchesi; Cardoso, Valtemar Fernandes; Rosa, R. L. S.; Kuebler, Derek A.; Brodeur, Grace E.; Alotaibi, Amani H.; Coene, Marisa P.; Coene, Lauren M.; Jean, Elizabeth; Santiago, Rafael; Oliveira, Francisco H. A.; Rangel, Ricardo C.; Thomas, Gilles P.; Belay, Kalayu; Silva, Luciana W. da; Moura, Rafael Traldi; Seabra, Antônio Carlos; Silva, Emilío Carlos Nelli

doi:10.3390/s18020464

Cited by 19 publications

(9 citation statements)

References 60 publications

(115 reference statements)

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“…Toward these applications, the fiber structure and mechanical, electrical, and thermal properties are of fundamental importance. For example, a strain sensor requires high stretchability and easy‐adjustable electrical conductivity for a CNT fiber, and for next‐generation integrated electronic devices and high‐power cables, a wire with high current‐carrying capacity and thermal conductivity is of great importance . Clearly, to improve the device performance and develop the new‐type fiber devices, it is necessary to review recent progresses on these fundamental properties.…”

Section: Structure and Fundamental Propertiesmentioning

confidence: 99%

Understanding the Mechanical and Conductive Properties of Carbon Nanotube Fibers for Smart Electronics

et al. 2019

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The development of fiber‐based smart electronics has provoked increasing demand for high‐performance and multifunctional fiber materials. Carbon nanotube (CNT) fibers, the 1D macroassembly of CNTs, have extensively been utilized to construct wearable electronics due to their unique integration of high porosity/surface area, desirable mechanical/physical properties, and extraordinary structural flexibility, as well as their novel corrosion/oxidation resistivity. To take full advantage of CNT fibers, it is essential to understand their mechanical and conductive properties. Herein, the recent progress regarding the intrinsic structure–property relationship of CNT fibers, as well as the strategies of enhancing their mechanical and conductive properties are briefly summarized, providing helpful guidance for scouting ideally structured CNT fibers for specific flexible electronic applications.

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Section: Structure and Fundamental Propertiesmentioning

confidence: 99%

Understanding the Mechanical and Conductive Properties of Carbon Nanotube Fibers for Smart Electronics

et al. 2019

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“…Furthermore, strain gauges were distributed over FRP structures to monitor mechanical loads [7,17]. A sensor as a part of a fibre grid fabric was realized by e.g., glass fibres with an electrically conductive sizing of carbon nano tubes (CNT) [18], piezoelectric fibres of polyvinylidene fluoride [19], strain-sensitive carbon fibres [20] and CNT yarns [21,22].…”

Section: Current State Of Researchmentioning

confidence: 99%

Product Integration of Established Crash Sensors for Safety Applications in Lightweight Vehicles

Klein

Joseph

Kröger

2021

Sensors

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The functionality of products increases when more sensors are used. This trend also affects future automobiles and becomes even more relevant in connected and autonomous applications. Concerning automotive lightweight design, carbon fibre-reinforced polymers (CFRP) are suitable materials. However, their drawbacks include the relatively high manufacturing costs of CFRP components in addition to the difficulty of recycling. To compensate for the increased expenditure, the integration of automotive sensors in CFRP vehicle structures provides added value. As a new approach, established sensors are integrated into fibre-reinforced polymer (FRP) structures. The sensors are usually mounted to the vehicle. The integration of sensors into the structure saves weight and space. Many other approaches specifically develop new sensors for integration into FRP structures. With the new approach, there is no need for elaborate development of new sensors since established sensors are used. The present research also showed that the range of applications of the sensors can be extended by the integration. The present paper outlines the functional behaviour of the integrated sensor utilized for crashing sensing. First of all, the integration quality of the sensor is relevant. Different requirements apply to the usual mounting of the sensor. The self-sensing structure must fulfil those requirements. Moreover, unfamiliar characteristics of the new surrounding structure might affect the sensing behaviour. Thus, the sensing behaviour of the self-sensing composite was analyzed in detail. The overarching objective is the general integration of sensors in products with reasonable effort.

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“…Comparable applications did the sensing by glass fibers with an electrically conductive sizing of carbon nano tubes (CNT) [19], piezoelectric fibers made from polyvinylidene fluoride (PVDF) [20], or strain-sensitive carbon fibers [21], and CNT yarns [22]. For another application foil strain gauges were developed, which consist of piezoresistive CNT yarn [23]. Fiber Bragg gratings (FBG) (e.g., [24,25]) and phase array ultrasonic sensors [24] were used as well.…”

Section: Structure Integrated Sensorsmentioning

confidence: 99%

Sensor Systems for FRP Lightweight Structures: Automotive Features Based on Serial Sensor Products

Klein

2019

Sensors

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To achieve resource efficiency and an increased performance, as well as a higher safety and more features for vehicles, lightweight composites are a central sphere of activity for automotive innovations. This becomes particularly striking if the focus is not only a reduced vehicle weight but also an efficient overall concept. In addition to compatible material technologies and component design, new electronic solutions are of interest. A research contribution at the Robert Bosch Company deals with the direct integration of a current automotive acceleration sensor in fiber-reinforced polymer (FRP) parts. The sensor is part of the passive vehicle safety. Primarily, the principal application of the currently mounted sensor as an integrated part of the vehicle structure was proven. Sensor-integrated parts were evaluated on their sensing functionality as well as their structural performance. The present research is done to use the integrated sensor for a secondary feature. The study shows that the sensor can also be an indicator for the condition of its surrounding FRP structure. Hence, the sensor integration makes it possible to derive a secondary feature for automobiles by using the current sensor for future functionalized lightweight structures.

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Foil Strain Gauges Using Piezoresistive Carbon Nanotube Yarn: Fabrication and Calibration

Cited by 19 publications

References 60 publications

Understanding the Mechanical and Conductive Properties of Carbon Nanotube Fibers for Smart Electronics

Understanding the Mechanical and Conductive Properties of Carbon Nanotube Fibers for Smart Electronics

Product Integration of Established Crash Sensors for Safety Applications in Lightweight Vehicles

Sensor Systems for FRP Lightweight Structures: Automotive Features Based on Serial Sensor Products

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