Nano- And Microfiber-Based Fully Fabric Triboelectric Nanogenerator For Wearable Devices

Bae, Jong Hyuk; Oh, Hyun Ju; Song, Jin‐Kyu; Kim, Do Kun; Yeang, Byeong Jin; Ko, Jae Hoon; Kim, Seong Hun; Lee, Woosung; Lim, Seung Ju

doi:10.3390/polym12030658

Cited by 30 publications

(13 citation statements)

References 51 publications

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“…As of now, within the biomedical field, TENG‐generated electricity has been utilized to power wearable devices, enable the sensing of physiological functions such as heart rate, and treat various diseases and conditions through therapeutic ES. [ 124–136 ] There are many different types of TENG working modes including vertical contact separation, [ 137,138 ] in‐plane sliding, [ 139,140 ] single electrode, [ 141–144 ] and freestanding, [ 145–148 ] which give further leeway to utilizing TENG devices for IOB therapeutic applications due to the ability of TENG devices to harness electricity from a wide variety of biomechanical motions. TENGs’ versatility renders them optimal self‐powered biomedical sensors, [ 149–155 ] providing sensing insight via means of signal‐to‐function association.…”

Section: Introductionmentioning

confidence: 99%

Triboelectric Nanogenerators for Therapeutic Electrical Stimulation

et al. 2021

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Current solutions developed for the purpose of in and on body (IOB) electrical stimulation (ES) lack autonomous qualities necessary for comfortable, practical, and self‐dependent use. Consequently, recent focus has been placed on developing self‐powered IOB therapeutic devices capable of generating therapeutic ES for human use. With the recent invention of the triboelectric nanogenerator (TENG), harnessing passive human biomechanical energy to develop self‐powered systems has allowed for the introduction of novel therapeutic ES solutions. TENGs are especially effective at providing ES for IOB therapeutic systems given their bioconformability, low cost, simple manufacturability, and self‐powering capabilities. Due to the key role of naturally induced electrical signals in many physiological functions, TENG‐induced ES holds promise to provide a novel paradigm in therapeutic interventions. The aim here is to detail research on IOB TENG devices applied for ES‐based therapy in the fields of regenerative medicine, neurology, rehabilitation, and pharmaceutical engineering. Furthermore, considering TENG‐produced ES can be measured for sensing applications, this technology is paving the way to provide a fully autonomous personalized healthcare system, capable of IOB energy generation, sensing, and therapeutic intervention. Considering these grounds, it seems highly relevant to review TENG‐ES research and applications, as they could constitute the foundation and future of personalized healthcare.

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Section: Introductionmentioning

confidence: 99%

Triboelectric Nanogenerators for Therapeutic Electrical Stimulation

et al. 2021

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“…Greater conformity with the countersurface is likely to generate increased contact area. The higher dielectric constant and contact area can confer enhanced electrical performance for nanofiber-based TENGs. , However, electrospun nanofibers do have lower mechanical properties as compared to microfibers. , Therefore, we deposit the electrospun layer onto a conventional woven fabric to provide the required mechanical strength and stability. In this work, nylon 66 electrospun nanofibers are deposited on a silk woven fabric to form the tribo-positive layer.…”

Section: Introductionmentioning

confidence: 99%

High-Performance Triboelectric Nanogenerators Based on Commercial Textiles: Electrospun Nylon 66 Nanofibers on Silk and PVDF on Polyester

Bairagi

Khandelwal

Karagiorgis

et al. 2022

ACS Appl. Mater. Interfaces

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A high-performance textile triboelectric nanogenerator is developed based on the common commercial fabrics silk and polyester (PET). Electrospun nylon 66 nanofibers were used to boost the tribo-positive performance of silk, and a poly(vinylidene difluoride) (PVDF) coating was deployed to increase the tribo-negativity of PET. The modifications confer a very significant boost in performance: output voltage and short-circuit current density increased ∼17 times (5.85 to 100 V) and ∼16 times (1.6 to 24.5 mA/m2), respectively, compared with the Silk/PET baseline. The maximum power density was 280 mW/m2 at a 4 MΩ resistance. The performance boost likely results from enhancing the tribo-positivity (and tribo-negativity) of the contact layers and from increased contact area facilitated by the electrospun nanofibers. Excellent stability and durability were demonstrated: the nylon nanofibers and PVDF coating provide high output, while the silk and PET substrate fabrics confer strength and flexibility. Rapid capacitor charging rates of 0.045 V/s (2 μF), 0.031 V/s (10 μF), and 0.011 V/s (22 μF) were demonstrated. Advantages include high output, a fully textile structure with excellent flexibility, and construction based on cost-effective commercial fabrics. The device is ideal as a power source for wearable electronic devices, and the approach can easily be deployed for other textiles.

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“…[ 45,54,55 ] Quite recently, few reports emerged to focus on meltblown nonwoven fabrics, highlighting the relationship between structural features and their energy‐generating capabilities. [ 56–58 ] Meltblown nonwoven refers to a group of nonwoven fabrics produced by melt‐blowing process, which is a conventional one‐step nonwoven production technique. [ 59 ] This solvent‐free process is able to provide cost‐effective and high‐quality tribolayers in different chemical compositions and with relatively good mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

“…The open‐circuit voltage ( V OC ) is enhanced from 1.55 to 3.54 V when basis weight of PP meltblown nonwoven increases from 15 to 50 g m −2 . [ 56 ] Peng et al. reported that the triboelectric output ( V OC ) carries a maximum at a specific basis weight of PP nonwoven.…”

Section: Introductionmentioning

confidence: 99%

Modeling the Triboelectric Behaviors of Elastomeric Nonwoven Fabrics

Wang

Shim

et al. 2021

Advanced Materials

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TENGs), on the other hand, are promising alternatives to batteries and ultracapacitors, since they can power portable/ wearable devices by harvesting biomechanical energy from the environment. [2] In addition, they can be integrated with energy-storage units as sustainable power sources for electronics [3,4] or contribute to a hybridized system which can scavenge the coexisted energies from surroundings including mechanical, solar, and thermal inputs simultaneously. [5] Compared to other energy harvesters (i.e., piezoelectric, [6] thermoelectric, [7] and electromagnetic [8] ), TENGs offer higher output voltage, lower cost, superior energy conversion efficiency at low operation frequencies [9,10] with a wide range of feasible materials, and promise to harvest the overlooked forms of mechanical energy. [11][12][13] In a typical TENG, a tribolayer covered on the surface of an electrode is the most critical component. Initially, metallic and polymeric films became the most popular tribolayer options. Progress has been made on material selection, [14] structure design, [15][16][17][18][19][20] and chemical & topographic modifications. [21][22][23][24] Moreover, theoretical models for different working modes and structures of film-based TENGs, including conductor-to-dielectric contact-mode TENGs, [25] dielectric-todielectric contact-mode TENGs, [25] sliding-mode TENGs, [26] single-electrode-mode TENGs, [27] freestanding-mode TENGs, [28] grating-structured TENGs, [29] and nonplanar-compound-geometries TENGs [30,31] have been developed.However, in terms of real applications, most reported systems carry their own limitations, such as complex fabrication process, high cost, low scalability, as well as inferior flexibility and discomfort in wearable scenarios. [32] For example, most existing tribolayers exhibit low permeability to air and moisture, as well as poor stretchiness. In this context, textile-based TENGs have emerged, with an increasing effort on integration of various textile fabrics into TENGs while retaining their high triboelectric output. [33][34][35][36][37][38][39] Textile fabrics are highly promising candidates for wearable applications, which can either serve as substrates [33,[40][41][42][43] or functional components [44][45][46][47] owing to their decent flexibility, light weight, low cost, and superior breathability. [48] Up until now, most researchers have focused on TENG textiles fabricated by weaving, [49,50] knitting, [36,51,52] sewing, [53] or electrospinning techniques. [45,54,55] Quite recently, few reports emerged to focus on meltblown nonwoven fabrics, highlighting Theoretical modeling of triboelectric nanogenerators (TENGs) is fundamental to their performance optimization, since it can provide useful guidance on the material selection, structure design, and parameter control of relevant systems. Built on the theoretical model of film-based TENGs, here, an analytical model is introduced for conductor-to-dielectric contact-mode nonwoven-based TENGs, which copes with the unique hierarchical stru...

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Nano- And Microfiber-Based Fully Fabric Triboelectric Nanogenerator For Wearable Devices

Cited by 30 publications

References 51 publications

Triboelectric Nanogenerators for Therapeutic Electrical Stimulation

Triboelectric Nanogenerators for Therapeutic Electrical Stimulation

High-Performance Triboelectric Nanogenerators Based on Commercial Textiles: Electrospun Nylon 66 Nanofibers on Silk and PVDF on Polyester

Modeling the Triboelectric Behaviors of Elastomeric Nonwoven Fabrics

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