Textile-Based Mechanical Sensors: A Review

Zhou, Zaiwei; Zhong, Hongchuan; Zhang, Wanli; Zhang, Yue; Yin, Xiangyu; He, Bingwei

doi:10.3390/ma14206073

Cited by 19 publications

(23 citation statements)

References 111 publications

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“…Textiles are a more ideal substrate, with their large surface area, breathability and flexibility making them suitable for functionalizing materials over conventional strain sensor materials 9,24 . They can also be more cost effective and lightweight 25–27 …”

Section: Introductionmentioning

confidence: 99%

“…9,24 They can also be more cost effective and lightweight. [25][26][27] Various carbon materials, conductive polymers and metals have been used to coat fabrics to fabricate sensors. [28][29][30][31] Among various conductive materials, graphene has outstanding electrical, mechanical, and thermal properties, which exhibits great potential as a conductive substrate in textile strain sensors.…”

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confidence: 99%

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Multifunctional and stretchable graphene/textile composite sensor for human motion monitoring

Myant

Stewart

2022

J of Applied Polymer Sci

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Sensors based on electronic textiles (e‐textiles) have become increasingly prominent in the field of biomechanical monitoring technology due to multiple properties such as being lightweight, flexible, and comfortable, with increasing potential in incorporating into long‐term monitoring devices. Previous research has been conducted into textile strain sensors based on graphene for human motion monitoring, however most graphene e‐textile strain sensors exhibit poor sensitivity and stretchability. To our knowledge, no previous research has looked at knitted graphene‐based fabrics in regards to the fabric composition of the substrate. In this paper, we propose a graphene/fabric composite sensor using a cost‐effective dip coating method of an acrylic/Spandex knit fabric, and further explores its mechanical, electrical, and sensing properties. The developed graphene/textile composite sensor has a wide sensing range (up to 344%) and exhibits a good sensitivity with a high gauge factor of up to 16. As a wearable sensor, our sensing fabric can detect both large and subtle human motions and is able to distinguish between various ranges of joint movements, demonstrating its ability to function as a human motion monitoring system. Our sensor further exhibits the ability to be used as a supercapacitor or capacitive pressure sensor.

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Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

Multifunctional and stretchable graphene/textile composite sensor for human motion monitoring

Myant

Stewart

2022

J of Applied Polymer Sci

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“…They are low-cost, comfortable, and flexible. They can be used remotely to observe the physiological parameters of the human body [ 64 ]. The development of textile-based energy storage devices are outstanding research works that can be used in wearable technology to address the power consumption issues [ 65 ].…”

Section: Wban Technical Issuesmentioning

confidence: 99%

A Survey on Wireless Wearable Body Area Networks: A Perspective of Technology and Economy

Bhatti

Saleem

Imran

et al. 2022

Sensors

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The deployment of wearable or body-worn devices is increasing rapidly, and thus researchers’ interests mainly include technical and economical issues, such as networking, interoperability, security, power optimization, business growth and regulation. To address these issues properly, previous survey papers usually focused on describing the wireless body area network architecture and network protocols. This implies that deployment issues and awareness issues of wearable and BAN devices are not emphasized in previous work. To defeat this problem, in this study, we have focused on feasibility, limitations, and security concerns in wireless body area networks. In the aspect of the economy, we have focused on the compound annual growth rate of these devices in the global market, different regulations of wearable/wireless body area network devices in different regions and countries of the world and feasible research projects for wireless body area networks. In addition, this study focuses on the domain of devices that are equally important to physicians, sportsmen, trainers and coaches, computer scientists, engineers, and investors. The outcomes of this study relating to physicians, fitness trainers and coaches indicate that the use of these devices means they would be able to treat their clients in a more effective way. The study also converges the focus of businessmen on the Annual Growth Rate (CAGR) and provides manufacturers and vendors with information about different regulatory bodies that are monitoring and regulating WBAN devices. Therefore, by providing deployment issues in the aspects of technology and economy at the same time, we believe that this survey can serve as a preliminary material that will lead to more advancements and improvements in deployment in the area of wearable wireless body area networks. Finally, we present open issues and further research direction in the area of wireless body area networks.

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“…1−3 Highly conductive yarns are ultimate candidates for wearable electronics because of their flexibility, fiber-shaped, wearability, and conformability characteristics. 4,5 The potential applications of wearable electronic systems were developed, for example, in strain sensor-based yarns, 6,7 stretchable circuits, 8,9 human motion detection, 10,11 and selfpowered electronic fabrics. 12,13 Different methods have been employed to enhance the conductivity of fibers including metal nanowires, coating the fibers with conductive films, and conductive polymers for highly stretchable electronics in the field of wearable energy devices 14−16 and wearable sensors.…”

Section: Introductionmentioning

confidence: 99%

“…With the advantages of being affordable and extensively accessible, fabrics have recently attracted the wearable electronics field. − Highly conductive yarns are ultimate candidates for wearable electronics because of their flexibility, fiber-shaped, wearability, and conformability characteristics. , The potential applications of wearable electronic systems were developed, for example, in strain sensor-based yarns, , stretchable circuits, , human motion detection, , and self-powered electronic fabrics. , Different methods have been employed to enhance the conductivity of fibers including metal nanowires, coating the fibers with conductive films, and conductive polymers for highly stretchable electronics in the field of wearable energy devices − and wearable sensors. − A conductive polymer yarn, comprising a polymer and conductive materials, is counted as a promising candidate to diminish the defect of the earliest rigidity and difficult to bend or stretch fiber-based sensors because of its good flexibility and restorability of electrical conductivity. − Even though a conductive polymer yarn fabricated by the coating technique exhibits electrical conductivity and great stretchability, the durability and repeatability cannot satisfy the working conditions over a lengthy operating period because of the weak adhesion among the polymer surface and the conductive material. − Under repetitive stretch and release cycles, the conductive material from the surface of the fibers gets debonded and peeled gradually, and degradation of sensing response occurs. Therefore, manufacturing high-performance yarn-based devices with high strength and large stretchability with a simple, cost-effective, and scalable method remains a great challenge for wearable electronics.…”

Section: Introductionmentioning

confidence: 99%

High-Strength and Extensible Electrospun Yarn for Wearable Electronics

Uzabakiriho

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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Stretchable conductive yarns have received significant consideration in the direction of wearable and flexible electronics. Wearable electronic structures need strong materials to assure stability, durability, and an extensive range of strain to develop their applications. Therefore, manufacturing high-performance yarn-based devices with ultrarobustness and great stretchability with a simple, cost-effective, and scalable method remains a great challenge for wearable electronics. Here, a highly stretchable yarn with high performance is fabricated, which comprises a core TPU nanoyarn, successively decorated with a liquid metal (LM) layer, and a protective outer nanofiber layer. The ultrarobust (40 MPa) and high-strain (548%) conducting yarn presents potential applications in assembling strain sensors. Moreover, such a unique conductive yarn can be used as a highly deformable, stretchable conductor to charge a mobile phone or for data transfer, a sensor to monitor human activities, and as an effective control for a hand robot as well as for smart thermal management textile application. This research gives promising applications in the field of flexible and wearable electronics.

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Textile-Based Mechanical Sensors: A Review

Cited by 19 publications

References 111 publications

Multifunctional and stretchable graphene/textile composite sensor for human motion monitoring

Multifunctional and stretchable graphene/textile composite sensor for human motion monitoring

A Survey on Wireless Wearable Body Area Networks: A Perspective of Technology and Economy

High-Strength and Extensible Electrospun Yarn for Wearable Electronics

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