Linear flexible capacitive sensor with double helix structure based on multi-needle water-bath electrospinning technology

Han, Xiao; Fan, Mengjing; Yue, Xinyan; Zhao, Xiaoman; Liu, Yongkun; Hong, Jing; Liu, Leigen

doi:10.1088/1361-665x/acb40d

Cited by 5 publications

(4 citation statements)

References 40 publications

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“…Some researchers have made innovative designs on flat plate structures to enhance the performance of capacitive strain sensors to monitor knee activity more effectively. Han X. et al [61] used a novel multi-needle water bath electrostatic spinning method to coat polyamide 6 (PA6) nanofibers on the surface of silver-plated nylon (thiocyanate) core yarn. SCN/PA6 nanofiber corespun yarns were prepared, and linear flexible capacitive sensors with double helix structures (Dual helix structure of linear flexible capacitive sensors, DHSCSs) were prepared by putting two different elastic rubber wires.…”

Section: Measurement Of Knee Anglementioning

confidence: 99%

Flexible Strain Sensors for Walking Gait Monitoring

Feng,

Shi,

Zhu

et al. 2024

Preprint

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This review delves into the growing field of flexible and stretchable strain sensors utilized in human gait analysis, focusing on determining knee bending angle and muscle activities when a human subject walks. Recent advancements have enabled these sensors to accurately capture biomechanical parameters while accommodating the body's natural movements. We examine the principles underlying these sensors' design and fabrication techniques, emphasizing their flexibility, stretchability, and biocompatibility for seamless integration into wearable systems. Through critical evaluation of existing methodologies, we assess the reliability and validity of these sensors in quantifying gait parameters. Furthermore, we discuss this technology's clinical and research implications, highlighting its potential in personalized rehabilitation and sports performance optimization. We provide an overview of flexible strain sensors and their application for analyzing human walking gait, especially for observing walking gait in rehabilitation programs. First, we present the basic working principles of various flexible strain sensors. Second, by the application of flexible strain sensors as walking gait monitoring. Finally, current challenges and future opportunities in this research area are discussed. By synthesizing current knowledge and outlining future directions, this review aims to provide insights for researchers and practitioners seeking to leverage flexible and stretchable strain sensors for comprehensive human gait analysis.

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Section: Measurement Of Knee Anglementioning

confidence: 99%

Flexible Strain Sensors for Walking Gait Monitoring

Feng,

Shi,

Zhu

et al. 2024

Preprint

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“…Electrospun yarn and textile have been applied in the development of flexible biomechanical sensors recently. , Yarns and textiles are attractive options as carriers for flexible electronics because of the high flexibility, good abrasion resistance, and superior conformability, which are usually achieved by means of special electrospinning devices or equipment. − Tang et al prepared highly ductile CNT/TPU composite nanofibers with elongation at break up to 476% by evenly dispersing CNT into a flexible TPU matrix through a multineedle water-bath electrospinning device. In this study, a conductive yarn (CTY) is developed from processing nanofibers via a twisted collection device, which is further prepared as a smart sports bandage.…”

Section: Optimization Strategies Of Electrospun Flexible Biomechanica...mentioning

confidence: 99%

Electrospun Micro/Nanofiber-Based Biomechanical Sensors

Li,

Zhang,

et al. 2023

ACS Appl. Polym. Mater.

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Electrospun micro/nanofibers have gained popularity recently for flexible biomechanical sensors because of their advantages of lightness, compatibility, breathability, mechanical deformability, and function integrability, etc., offering them unprecedented sensitivities and versatilities. With increasing advances in the digital era, existing electrospun flexible sensors are not capable of catering to the demands of multiscenario applications including wearable electronics, interactive interfaces, and real-time continuous health monitoring. To ease and expedite their developments, we thoroughly reviewed their latest progress regarding design, preparation, and optimization. First, a brief overview of the design approaches of electrospun flexible biomechanical sensors based on the working mechanism is highlighted. Then, two kinds of preparation strategies including direct electrospinning and post-treatment-assisted electrospinning are discussed in detail. Further, four means for optimizing the performance and endowing multifunctions to electrospun flexible biomechanical sensors are demonstrated in terms of processing. Accordingly, the challenges and the potential solutions related to this topic are addressed, providing a future direction for the next generation of electrospun flexible biomechanical sensors.

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“…The water bath twisting yarn method has a high utilization rate of nanofibers, but it needs to rely on the continuous flow of the water bath and the formation of a whirlpool to complete the wrapping of nanofibers on the surface of the core yarn; therefore, its controllability is poor. In our previous work, we designed an improved water bath electrospinning method to fabricate micro/nanofiber composite yarns that do not require continuous flow and the formation of a whirlpool [14][15][16][17]. By using rotation and continuous movement of the core yarn, nanofibers sprayed on the surface of the water bath were rolled on the surface of the core yarn, and various kinds of micro/nanofiber composite yarns with skin-core structures were successfully prepared.…”

Section: Introductionmentioning

confidence: 99%

“…In our previous study, micro/nanofiber composite yarns were prepared by electrospinning on the surface of silvercoated nylon (SCN) coated with polyamide 6 (PA6) nanofibers, and were used to develop the one-dimensional doublehelix flexible capacitance sensor [14], in which SCN served as the electrode and the PA6 nanofibers served as an insulating dielectric layer. The structure of the dielectric layer, such as thickness and porosity, has an impact on the performance of the capacitance sensor [27,28], but the nanofiber structure was not analyzed in this work.…”

Section: Introductionmentioning

confidence: 99%

Electric field simulation of multi-needle water bath electrospinning and the structural properties of SCN/PAN micro/nanofiber composite yarns

Fan,

Yue,

Wang

et al. 2023

Nanotechnology

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Multi-needle water bath electrospinning is one of the most efficient methods to prepare micro-nano fiber composite yarns. The nanofiber structure can be targeted regulated to obtain high performance composite yarns. In order to explore the effect of receiving distance on the structure and properties of micro-nano fiber composite yarns, polyacrylonitrile nanofibers were uniformly coated on silver-coated nylon yarn by four-needle continuous water bath electrospinning method. The electric field distribution at different receiving distances was simulated by ANSYS finite element analysis software, and the effect of electric field distribution on the structure and properties of micro-nano fiber composite yarns were studied. The results indicated that the peak electric field intensity appeared at the tip of the needles and decreased with the increase of receiving distance. The receiving distance was constant, the field intensity was lower when the direction of the centerline of the needle tip was farther away from the tip, but the field intensity at the conductive core yarn was higher than that in the surrounding area (small spikes). The average field intensity of small spikes at 180 mm was only 1/4 of that at 80 mm. When the receiving distance increased within a certain range (100~140 mm), the nanofibers had smooth surface and good separation, nanofibers diameter decreased continuously, and the porosity changed inversely. With the further increase of the receiving distance, the nanofibers gradually bonded, the nanofibers diameter increased, and the porosity changed oppositely. The coating rate of nanofibers showed a decreasing trend, and the mechanical properties of micro-nano composite yarns were improved. When the receiving distance was 100 mm, the porosity reached 38.94%, the breaking force, breaking elongation and breaking strength were 13.71±1.36 cN, 22.76±6.62% and 0.15±0.02 cN·dtex-1, respectively. Considering all factors, the receiving distance of 100 mm is appropriate.

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Linear flexible capacitive sensor with double helix structure based on multi-needle water-bath electrospinning technology

Cited by 5 publications

References 40 publications

Flexible Strain Sensors for Walking Gait Monitoring

Flexible Strain Sensors for Walking Gait Monitoring

Electrospun Micro/Nanofiber-Based Biomechanical Sensors

Electric field simulation of multi-needle water bath electrospinning and the structural properties of SCN/PAN micro/nanofiber composite yarns

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