Your search keyword '"STRAIN sensors"' showing total 6,931 results

101. Self-healing, piezoresistive and temperature responsive behaviour of chitosan/polyacrylic acid dynamic hydrogels.

Author

Conejo-Cuevas, Guillermo, Lopes, Ana Catarina, Badillo, Inari, del Campo, Francisco Javier, Ruiz-Rubio, Leire, and Pérez-Álvarez, Leyre

Subjects

*FLEXIBLE electronics, *STRAIN sensors, *POLYACRYLIC acid, *PIEZORESISTANCE, *ELECTRONIC materials, *SELF-healing materials

Abstract

[Display omitted] Flexible electronics have introduced new challenges for efficient human–machine interactions. Hydrogels have emerged as prominent materials for electronic wearable applications due to their exceptional mechanical deformability and lightweight characteristics combined in some cases with conductive properties, and softness. Additionally, bio-interphases require multisensory response to stress, strain, temperature, and self-healing capacity. To mimic these properties, this work developed interpenetrated hydrogel networks composed of chitosan (CHI) and polyacrylic acid (PAA), combined with Fe (III) ions and varying amounts of NMBA (0–0.25 %), to achieve tailored conductivity (0.8–2.5 mS/cm), self-healing, self-standing and mechanical properties (E = 11.7–110 Pa and fracture strain = 64.9–1923 %) suitable for strain sensor applications. The results revealed a significant influence of the restrictive effect on the mobility of uncrosslinked chain segments, caused by Fe ions and NMBA, on the piezoresistance (GF 2.1–1.3) and self-healing capability of the gels. Interestingly, a transparent/turbid transition, driven by microphase separation that is characteristic of systems with high dynamic interactions, was encountered for the first time in these hydrogels. This transition was analyzed in relation to external temperature, water content, pH, and the influence of Fe ions and NMBA. The simultaneous sensitivity of these materials to temperature and pH, along with their piezoresistive and self-healing behaviour, can be highly valuable for multifunctional sensors in a wide range of applications. [ABSTRACT FROM AUTHOR]

Published

2025

102. Self-powered strain sensing devices with wireless transmission: DIW-printed conductive hydrogel electrodes featuring stretchable and self-healing properties.

Author

Cong, Chenhao, Wang, Rong, Zhu, Wenhu, Zheng, Xianbin, Sun, Fenglin, Wang, Xuhao, Jiang, Fuhao, Joo, Sang Woo, Lim, Sooman, Kim, Se Hyun, and Li, Xinlin

Subjects

*STRAIN sensors, *CONDUCTIVE ink, *JOINTS (Anatomy), *RHEOLOGY, *POWER resources

Abstract

[Display omitted] • Achieve high-precision DIW printing using conductive hydrogel ink. • Conductive hydrogel electrodes have remarkable stretchability and self-healing capabilities. • Develop a self-powered strain sensing system employing conductive hydrogel electrodes. • Construct a complex internal structure within the electrode. • Remote human motion detection based on hydrogel strain sensors. With rapid advancements in health and human–computer interaction, wearable electronic skins (e-skins) designed for application on the human body provide a platform for real-time detection of physiological signals. Wearable strain sensors, integral functional units within e-skins, can be integrated with Internet of Things (IoT) technology to broaden the applications for human body monitoring. A significant challenge lies in the reliance of most existing wearable strain sensors on rigid external power supplies, limiting their practical flexibility. In this study, we present an innovative strategy to fabricate glutaraldehyde (GA)-poly(vinyl alcohol) (PVA)/cellulose nanocrystals (CNC)/Poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) conductive hydrogels through multiple hydrogen bonding systems. Combining the advantageous rheological properties of the precursor solution and the high specific surface area after freeze–thaw cycling, we have created a self-powered sensing system prepared by large-area printing using direct ink writing (DIW) printing. The resulting conductive hydrogel exhibits commendable mechanical properties (411 KPa), impressive stretchability (580 %), and robust self-healing capabilities (>98.3 %). The strain sensor, derived from the conductive hydrogel, demonstrates a gauge factor (GF) of 2.5 within a stretching range of 0–580 %. Additionally, the resultant supercapacitor displays a peak energy density of 0.131 mWh/cm3 at a power density of 3.6 mW/cm3. Benefiting from its elevated strain response and remarkable power density features, this self-powered strain sensing system enables the real-time monitoring of human joint motion. The incorporation of a 5G transmission module enhances its capabilities for remote data monitoring, thereby contributing to the progress of wireless tracking technologies for self-powered electronic skin. [ABSTRACT FROM AUTHOR]

Published

2025

103. Construction of gradient ionogels by self-floatable hyperbranched organosilicon crosslinkers for multi-sensing and wirelessly monitoring physiological signals.

Author

Li, Xuechun, Gao, Yanjing, Nie, Jun, and Sun, Fang

Subjects

*FLEXIBLE electronics, *MORSE code, *HUMAN mechanics, *STRAIN sensors, *ELECTRONIC materials

Abstract

Thanks to the self-floating nature, hyperbranched-polysiloxane crosslinkers HPSis endows ionogels with gradient composition variation along the vertical direction, facilitating the prepared ionogels with gradient structures and properties. Gradient ionogels not only renders flexible sensors with dual-mode responses, but also enhances the sensitivity. The electrical signal of gradient-ionogel-based dual-mode flexible sensors can be wireless transmitted to a computer. [Display omitted] Monitoring complex human movements requires the simultaneous detection of strain and pressure, which poses a challenge due to the difficulty in integrating high stretchability and compressive ability into a single material. Herein, a series of hyperbranched polysiloxane crosslinkers (HPSis) with self-floating abilities are designed and synthesized. Taking advantage of the self-floating capabilities of HPSis, ionogels with gradient composition distribution and conductivities are constructed by in situ one-step photopolymerization, and possess satisfactory stretchability, high compressibility and excellent resilience. The gradient-ionogel-based strain sensor exhibits extraordinary pressure sensitivity (19.33 kPa−1), high strain sensitivity (GF reaches 2.5) and temperature sensing ability, enabling the monitoring of the angles and direction of joint movements, transmitting Morse code and wirelessly detecting bioelectrical signals. This study may inspire the design of development of multi-function flexible electronics. [ABSTRACT FROM AUTHOR]

Published

2025

104. Smart sensing hydrogel actuators conferred by MXene gradient arrangement.

Author

Zeng, Jiazhou, Jing, Xin, Lin, Liya, Wang, Gangrong, Zhang, Yaoxun, and Feng, Peiyong

Subjects

*SMART materials, *ELECTRIC conductivity, *STRAIN sensors, *FACIAL expression, *PATIENT monitoring

Abstract

[Display omitted] • The effect of ordered arrangement of MXene in hydrogel on its conductivity of hydrogel was investigated in detail. • The gradient structure in synergy with the thermal sensitive MXene nanolayer contributed to the excellent actuation ability of the hydrogel. • The hydrogel was able to rival commercial electrodes to detect Pulse and ECG signals. Smart sensing and excellent actuation abilities of natural organisms have driven scientists to develop bionic soft-bodied robots. However, most conventional robots suffer from poor electrical conductivity, limiting their application in real-time sensing and actuation. Here, we report a novel strategy to enhance the electrical conductivity of hydrogels that integrated actuation and strain-sensing functions for bioinspired self-sensing soft actuators. Conductive hydrogels were synthesized in situ by copolymerizing MXene nanosheets with thermosensitive N -isopropylacrylamide and acrylamide under a direct current electric field. The resulting hydrogels exhibited high electrical conductivity (2.11 mS/cm), good sensitivity with a gauge factor of 4.79 and long-term stability. The developed hydrogels demonstrated remarkable capabilities in detecting human motions at subtle strains such as facial expressions and large strains such as knee bending. Additionally, the hydrogel electrode patch was capable of monitoring physiological signals. Furthermore, the developed hydrogel showed good thermally induced actuation effects when the temperature was higher than 30 °C. Overall, this work provided new insights for the design of sensory materials with integrated self-sensing and actuation capabilities, which would pave the way for the development of high-performance conductive soft materials for intelligent soft robots and automated machinery. [ABSTRACT FROM AUTHOR]

Published

2025

105. An adhesive, stretchable, and freeze-resistant conductive hydrogel strain sensor for handwriting recognition and depth motion monitoring.

Author

Cui, Liangliang, Hu, Chunyan, Wang, Wei, Zheng, Jian, Zhu, Zhijia, and Liu, Baojiang

Subjects

*ENGLISH letters, *FLEXIBLE electronics, *STRAIN sensors, *ELECTRONIC equipment, *SOFT robotics

Abstract

In this study, an adhesive, stretchable and freeze-resistant conductive hydrogel was prepared using a glycerol-water binary solvent combined with charged polar end groups. With the full convolutional network (FCN) algorithm, the hydrogel sensor achieves 96.4 % accuracy in recognizing handwritten English letters, demonstrating potential applications in flexible electronics and handwriting recognition. [Display omitted] Wearable electronics based on conductive hydrogels (CHs) offer remarkable flexibility, conductivity, and versatility. However, the flexibility, adhesiveness, and conductivity of traditional CHs deteriorate when they freeze, thereby limiting their utility in challenging environments. In this work, we introduce a PHEA-NaSS/G hydrogel that can be conveniently fabricated into a freeze-resistant conductive hydrogel by weakening the hydrogen bonds between water molecules. This is achieved through the synergistic interaction between the charged polar end group (−SO 3 −) and the glycerol-water binary solvent system. The conductive hydrogel is simultaneously endowed with tunable mechanical properties and conductive pathways by the modulation caused by varying material compositions. Due to the uniform interconnectivity of the network structure resulting from strong intermolecular interactions and the enhancement effect of charged polar end-groups, the resulting hydrogel exhibits 174 kPa tensile strength, 2105 % tensile strain, and excellent sensing ability (GF = 2.86, response time: 121 ms), and the sensor is well suited for repeatable and stable monitoring of human motion. Additionally, using the Full Convolutional Network (FCN) algorithm, the sensor can be used to recognize English letter handwriting with an accuracy of 96.4 %. This hydrogel strain sensor provides a simple method for creating multi-functional electronic devices, with significant potential in the fields of multifunctional electronics such as soft robotics, health monitoring, and human-computer interaction. [ABSTRACT FROM AUTHOR]

Published

2025

106. Damage identification in cable-stayed bridges based on the behavior of neutral axis under traffic loading.

Author

Aloupis, Christos, Shenton III, Harry W., and Chajes, Michael J.

Subjects

*GEOMETRIC distribution, *AXIAL loads, *NEUTRAL beams, *STRAIN sensors, *VEHICLE detectors, *CABLE-stayed bridges

Abstract

A beam's Neutral Axis (NA) is a parameter that has been utilized to detect damage. Its position depends on the geometry of the cross-section and also a member's axial loads. Shifts in its position can indicate changes in either load distribution or geometric characteristics. When considering structures such as cable-stayed bridges where the inclined cables induce significant axial forces, the effect of axial loads on NA position is significant. In this research, a simplified analytical model was developed consisting of the key elements of a cable-stayed bridge (beam, cable, and bearing). The model was loaded with a vertical point load representing a vehicle load. The NA position was calculated beneath the load as it moves over the length of the beam. By changing element properties, one can observe how the NA position behaves in different locations of the beam, due to simulated damage in the beam, cable, or bearing. It was found that changes in NA position can capture not only whether damage has occurred, but also in which component of the structure the damage is located (beam, cable, or bearing). This ability to use NA position for damage identification renders it an excellent parameter for monitoring cable-stayed bridges. [ABSTRACT FROM AUTHOR]

Published

2024

107. Thermal and light-driven soft actuators based on a conductive polypyrrole nanofibers integrated poly(N-isopropylacrylamide) hydrogel with intelligent response.

Author

Liu, Lingke, Li, Yueqin, Lu, Zichun, Miao, Ruantian, and Zhang, Ning

Subjects

*POLY(ISOPROPYLACRYLAMIDE), *SMART materials, *BIOMIMETIC materials, *STRAIN sensors, *POLYETHYLENE glycol, *POLYPYRROLE

Abstract

[Display omitted] The development of soft hydrogel actuators with outstanding mechanical properties, fast actuation speed, and available quantification of self-sensing actuation remains a challenging endeavor. In this work, dopamine-decorated polypyrrole nanofibers (DAPPy) were introduced into the polyethylene glycol diacrylate (PEGDA)-crosslinked poly(N-isopropyl acrylamide) network to generate a stretchable, NIR-responsive, and strain sensitive DAPPy/PNIPAM hydrogel layer. Besides, this active layer was combined with the passive ligninsulfonate sodium/polyacrylamide (LS/PAAM) to give DAPPy/PNIPAM//LS/PAAM bilayer hydrogel actuator, which exhibits ultrafast thermo-responsive actuation (19°/s) and underwater grasping and lifting performance. Moreover, the DAPPy/PNIPAM layer has excellent electrical conductivity (0.29 S/m) and thermal conversion ability (10.8 °C/min), which enable such a conductive hydrogel to act as a highly sensitive strain and temperature sensor with real-time resistance change in response to tensile strain (gauge factor up to 3.4), applied pressure, temperature, and remote NIR light irradiation. More importantly, the bilayer hydrogel actuator can integrate both actuation and self-sensing functions through the bending angle-surface temperature-relative resistance change relationship of the photothermal process. With excellent mechanical actuation and self-sensing ability, the resulting bilayer hydrogel showed a promising application potential as soft biomimetic actuating materials and soft intelligent actuators. [ABSTRACT FROM AUTHOR]

Published

2024

108. Investigation of real-time strain responses of the insulating system of superconducting magnets by using fiber Bragg grating sensors.

Author

Zhao, Wanyin, Xin, Jijun, Zhang, Hengcheng, Wang, Wei, Fang, Zhichun, Lyu, Bingkun, Wu, Longfeng, Wang, Chundong, Shen, Fuzhi, Shan, Xinran, Huang, Chuanjun, Sun, Wentao, Zhou, Yuan, and Li, Laifeng

Subjects

*FIBER Bragg gratings, *SUPERCONDUCTING magnets, *GLASS-reinforced plastics, *SUPERCONDUCTING coils, *EPOXY resins, *STRAIN sensors

Abstract

The normal operation of various superconducting magnets is greatly influenced by the thermal stress of the insulating system, commonly made of epoxy resins with vacuum pressure impregnation (VPI) technology, throughout the curing and cooling processes. In this work, we developed a Fiber Bragg Grating (FBG) strain measurement method to monitor the real-time strain responses of an epoxy resin IR-3 and its glass fiber-reinforced composite during both curing and cooling processes. Then, we also monitored the same process of a Nb–Ti superconducting magnet coil prepared by VPI technology. With the help of FBG strain sensors, the residual strains of the coil at various positions and directions were investigated. The results show that the large residual strain occurred near the end of the coil in the axial direction. In addition, the interlaminar shear stress properties were measured at both room temperature and liquid nitrogen temperature. The strain characteristics of the epoxy resin IR-3 and the insulating system can provide useful guidance for the design and construction of high-field Nb–Ti superconducting magnets. [ABSTRACT FROM AUTHOR]

Published

2023

109. 3D Printing of Ultrastretchable and Tough Double‐Network Hydrogel for Strain Sensor.

Author

Tiston, Karl Albright, Tipachan, Chuenkhwan, Yimnoi, Tawanrat, Cheacharoen, Rongrong, Hoven, Voravee P., and Narupai, Benjaporn

Subjects

*STRAIN sensors, *IONIC conductivity, *SOFT robotics, *THREE-dimensional printing, *ENERGY dissipation

Abstract

Stretchable conductive hydrogels have garnered considerable recognition due to their uses in strain sensors, electronic skins, soft robotics, and actuators. However, many hydrogels have poor mechanical properties limiting widespread implementation. While the development of ultrastretchable and mechanically robust hydrogels remains a challenge, the fabrication of these materials with customized designs is also highly desirable. Herein, a direct‐ink write 3D printable double‐network (DN) hydrogel is reported by integrating a physically cross‐linked κ‐carrageenan and a chemically cross‐linked poly(acrylamide‐co‐hydroxyethyl acrylate‐co‐Pluronic F127‐bisurethane methacrylate) with an ionically cross‐linked coordination between κ‐carrageenan and Fe3+ ions in water–glycerol binary solvent. The DN hydrogel demonstrates excellent stretchability (1770% strain), remarkable toughness (6.24 MJ m−3), high ionic conductivity (1.55 S m−1), biocompatibility, and nondrying behavior. A variety of 3D printed constructs including auxetic structures are fabricated and used as a strain sensor. The sensor exhibited real‐time electrical response to strain to detect human motions demonstrating the practicality of this system. These 3D printable DN hydrogels show great potential for on‐demand fabrication of flexible health‐monitoring devices. [ABSTRACT FROM AUTHOR]

Published

2024

110. Three-dimensional micro strain gauges as flexible, modular tactile sensors for versatile integration with micro-and macroelectronics.

Author

Chen Xu, Yiran Wang, Jingyan Zhang, Ji Wan, Zehua Xiang, Zhongyi Nie, Jie Xu, Xiang Lin, Pengcheng Zhao, Yaozheng Wang, Shaotong Zhang, Jing Zhang, Chunxiu Liu, Ning Xue, Wei Zhao, and Mengdi Han

Subjects

*TACTILE sensors, *STRAIN sensors, *STRAIN gages, *FLEXIBLE printed circuits, *ELECTRONIC systems, *ALLOYS, *SHEARING force

Abstract

Flexible tactile sensors play important roles in many areas, like human-machine interface, robotic manipulation, and biomedicine. However, their flexible form factor poses challenges in their integration with wafer-based devices, commercial chips, or circuit boards. Here, we introduce manufacturing approaches, device designs, integration strategies, and biomedical applications of a set of flexible, modular tactile sensors, which overcome the above challenges and achieve cooperation with commercial electronics. The sensors exploit lithographically defined thin wires of metal or alloy as the sensing elements. Arranging these elements across three-dimensional space enables accurate, hysteresis-free, and decoupled measurements of temperature, normal force, and shear force. Assembly of such sensors on flexible printed circuit boards together with commercial electronics forms various flexible electronic systems with capabilities in wireless measurements at the skin interface, continuous monitoring of biomechanical signals, and spatial mapping of tactile information. The flexible, modular tactile sensors expand the portfolio of functional components in both microelectronics and macroelectronics. [ABSTRACT FROM AUTHOR]

Published

2024

111. Durable TPU/PDA/MXene Fiber‐Based Strain Sensors with High Strain Range and Sensitivity.

Author

Cheng, Hengyi, Zhang, Xun, Zhang, Tao, Chen, Yixiang, Yu, Dan, and Wang, Wei

Subjects

*STRAIN sensors, *HUMAN activity recognition, *CHEMICAL resistance, *ARTIFICIAL intelligence, *CHEMICAL stability, *WEARABLE technology, *POCKET computers, *WRIST, *KNEE

Abstract

With the development of the ageing society, wearable strain sensors have great application prospects in the fields of health detection, artificial intelligence, and motion recognition. However, traditional forms of film‐like strain sensors suffer from low sensitivity, adhesion, and impermeability during use, which severely limit their practical applications. To overcome these problems, we propose a strategy to fabricate polyurethane/polydopamine/MXene (TPU/PDA/MXene) composite fibers by wet spinning. Furthermore, the outside is wrapped with (PDMS), giving mechanical strength and chemical resistance. Through a simple and low‐cost wet spinning process, TPU/PDA/MXene fibers are achieved in the preparation of flexible strain sensors, and they can be woven into various forms with good flexibility and comfort according to practical needs. The results indicated that the prepared flexible strain sensor exhibits a high gauge factor (GF) of 57.15 over a large strain range (300 %), which are superior to those of many fiber‐based sensors. Their application properties were also measured by attaching them to fingers, wrists and knees, showing high sensitivity, mechanical durability and chemical stability, and has great potential for wearable strain sensors and flexible strain sensors in complex environments. [ABSTRACT FROM AUTHOR]

Published

2024

112. Bioinspired Superstrong, Wet Adhesive Deep Eutectic Solvent‐Based Gels for Stain Sensing and ECG Monitoring.

Author

Yang, Jinxue, Zhang, Xuhang, Zhao, Zhenjie, Wang, Xue, Liang, Zhenhu, Liang, Yongri, and Dan Liu, Ying

Subjects

*STRAIN sensors, *HYDROGEN bonding interactions, *ELECTRONIC equipment, *HUMAN mechanics, *HYDROGEN bonding

Abstract

Low mechanical properties and easy detachment from the hydration layer at the wet interface of hydrogel limit its application as an adhesive‐flexible sensor. In this study, the composition and structure of mussel mucoprotein are replicated using sulfonyl betaine (SBMA) containing zwitterion and N‐hydroxyethyl acrylamide to be polymerized in deep eutectic solvents and integrated with a polydopamine network to create a bionic eutectic gel with exceptionally strong and wet adhesion. Water erosion is effectively inhibited by the extensive hydrogen bond and electrostatic interactions. These dynamic bonds also impart self‐healing properties to the gel, showing a self‐healing efficiency of 55.45% after 48 h healing at room temperature. The zwitterion in SBMA can preferentially react with water to form a hydrated shell to protect the hydrogen bonds and enhance the exceptional water resistance and adhesion of the gel. The peel strength of the gel on a wet substrate is up to 220.71 N m−1, and its tensile strength can reach 1.01 MPa. It also has good mass stability at both low and high temperatures. This eutectic gel has the potential to be used in flexible electronic devices and can detect human movement and bioelectrical impulses on wet skin with great sensitivity. [ABSTRACT FROM AUTHOR]

Published

2024

113. Automated manufacture and experimentation of composite overwrapped pressure vessel with embedded optical sensor.

Author

Oromiehie, Ebrahim, Nagulapally, Prashanth, Donough, Matthew J., and Prusty, B. Gangadhara

Subjects

*PRESSURE vessels, *OPTICAL sensors, *HYDROGEN storage, *STRUCTURAL health monitoring, *OPTICAL fiber detectors, *STRAIN sensors, *ENERGY consumption

Abstract

In recent years, the mobility (air/land) industry has been developing fuel-cell vehicles for mass adoption as hydrogen technology matures. Compared to conventional metallic design, the composite overwrapped pressure vessel without a metal or polymer liner results in a lightweight solution for gaseous hydrogen storage which further improves fuel efficiencies. Since the capabilities of automated fiber placement for making multi-stiffened structures are distinct from other automated manufacturing techniques, this study aimed to evaluate the feasibility of implementing AFP into the manufacture of a small scale COPV with a partially composite liner. The manufacturing related challenges are identified and discussed. During the manufacturing process, Distributed fiber optic sensor was embedded between the plies, as a structural health monitoring solution, to monitor the mechanical performance of the pressurized tank. In addition, finite element study was done to predict the internal strains for different pressure levels and the measured experimental strains at the sensor's location are found to be in close agreement with the finite element results. It is shown that such sensors can be integrated into automated fiber placement manufactured tanks for internal strain monitoring. [Display omitted] • Manufacture of composite overwrap pressure vessel using AFP featuring a novel partially composite liner. • Utilising VERICUT Composite Programming/Simulation (VCP/VCS) for fibre path generation and ensuring producibility with AFP. • Embedding distributed fibre optic sensor for in-situ performance monitoring during testing and operational service. • In-depth discussion of manufacturing challenges encountered during the process. • The tank was tested hydrostatically, and the strains measured using the embedded sensor were compared with FEA predictions. [ABSTRACT FROM AUTHOR]

Published

2024

114. Flexible Transparent Films of Oriented Silver Nanowires for a Stretchable Strain Sensor.

Author

Wang, Xiaoguang, Song, Chengjun, Wang, Yangyang, Feng, Shaoxuan, Xu, Dong, Hao, Tingting, and Xu, Hongbo

Subjects

*ELECTRIC conductivity, *ELECTROCHROMIC windows, *SANDWICH construction (Materials), *GENERALIZED spaces, *WEARABLE technology, *NANOWIRES, *STRAIN sensors

Abstract

The potential applications of stretchable strain sensors in wearable electronics have garnered significant attention. However, developing susceptible stretchable strain sensors for practical applications still poses a considerable challenge. The present study introduces a stretchable strain sensor that utilizes silver nanowires (AgNWs) embedded into a polydimethylsiloxane (PDMS) substrate. The AgNWs have high flexibility and electrical conductivity. A stretchable AgNW/Pat-PDMS conductive film was prepared by arranging nanowires on the surface of PDMS using a simple rod coating method. Depending on the orientation angle, the overlap area between nanowires varies, resulting in different levels of separation under a given strain. Due to the separation of the nanowire and the change in current path geometry, the variation in strain resistance of the sensor can be primarily attributed to these factors. Therefore, precision in strain regulation can be adjusted by altering the angle θ (0°, 60°, or 90°) of the nanowire. At the same time, the stability of the AgNW/Pattern-PDMS (AgNW/Pat-PDMS) conductive film application was verified by preparing a sandwich structure PDMS/AgNW/Pat-PDMS stretchable strain sensor. The sensor exhibited high sensitivity within the operating sensing range (gauge factor (GF) of 15 within ~120% strain), superior durability (20,000 bending cycles and 5000 stretching cycles), and excellent response toward bending. [ABSTRACT FROM AUTHOR]

Published

2024

115. Controllable synthesis of TiO2/graphene composites for human voice recognition in strain sensor.

Author

Cheng, Yan, Wang, Ke, and Zhang, Siyi

Subjects

*STRAIN sensors, *SULFATE pulping process, *ELECTRONIC equipment, *NANOCOMPOSITE materials, *CRYSTAL morphology

Abstract

Low-dimensional materials have demonstrated strong potential for use in diverse flexible strain sensors for wearable electronic device applications. However, the limited contact area in the sensing layer, caused by the low specific surface area of typical nanomaterials, hinders the pursuit of high-performance strain-sensor applications. Herein, we report an efficient method for synthesizing TiO2-based nanocomposite materials by directly using industrial raw materials with ultrahigh specific surface areas that can be used for strain sensors. A kinetic study of the self-seeded thermal hydrolysis sulfate process was conducted for the controllable synthesis of pure TiO2 and related TiO2/graphene composites. The hydrolysis readily modified the crystal form and morphology of the prepared TiO2 nanoparticles, and the prepared composite samples possessed a uniform nanoporous structure. Experiments demonstrated that the TiO2/graphene composite can be used in strain sensors with a maximum Gauge factor of 252. In addition, the TiO2/graphene composite-based strain sensor showed high stability by continuously operating over 1,000 loading cycles and aging tests over three months. It also shows that the fabricated strain sensors have the potential for human voice recognition by characterizing letters, words, and musical tones. [ABSTRACT FROM AUTHOR]

Published

2024

116. Dual Ion Regulated Eutectogels with High Elasticity and Adhesive Strength for Accurate Strain Sensors.

Author

Sun, Yaozhou, Cheng, Yin, Shi, Liangjing, Sun, Jing, Chen, Shuangjun, and Wang, Ranran

Subjects

*STRAIN sensors, *INTERFACIAL bonding, *LOADING & unloading, *DYNAMIC stability, *SIGNAL detection

Abstract

Eutectogels have attracted increasing attention from researchers due to their broad application potential, good environmental stability, biocompatibility, and low cost. Currently reported eutectogels generally show large residue strain and hysteresis, which will cause output signal inconsistency between the loading and unloading processes and is not conducive to accurate strain monitoring. Besides, the low adhesiveness of available eutectogels brings about difficulties in the installation of the sensors and dynamic interfacial stability between the sensors and human skin. Herein, a dual ion regulation strategy is proposed to obtain eutectogels with high resilience, high adhesiveness, ultralow residue strain, wide temperature adaptability (−20–60 °C) and good environmental stability. Strain sensors based on gradient eutectogels exhibit high sensitivity, a wide linear response range, and good cycling stability. The response curve shows negligible electrical hysteresis, providing consistent output signals at the fixed strain regardless of stretch or release. Accurate micrometry with a step as minute as 50 µm is realized. Moreover, the sensors demonstrate higher signal intensity and stability in human physiological signals and motion detection due to the strong interfacial bonding. [ABSTRACT FROM AUTHOR]

Published

2024

117. Anti‐Swelling Gel Wearable Sensor Based on Solvent Exchange Strategy for Underwater Communication.

Author

Jiang, Xinyu, Zhou, Xun, Ding, Kexin, Li, Xusheng, Huang, Bin, and Xu, Wenlong

Subjects

*FATIGUE limit, *STRAIN sensors, *WEARABLE technology, *SOLVENTS, *DETECTORS, *PHASE separation

Abstract

The application of gel wearable sensors in aquatic environments is very promising, however, the preparation of underwater gel sensors with excellent anti‐swelling properties and sensing performance remains a great challenge. In this paper, a solvent exchange strategy is proposed to fabricate an anti‐swelling gel, in which the hydrophobic segments are induced to gather and microphase separation occurs inside the gel. The prepared gel possesses excellent anti‐swelling performance (swelling ratio of 4.79%), good mechanical properties (tensile strain of 712%), high sensitivity (GF = 1.07), and high linearity (R2 = 0.998, 0 to 70% strain range). Moreover, it can achieve high stability (more than 90 days) and fatigue resistance (1000 cycles at 50% strain) as an underwater sensor. Therefore, the designed underwater gel strain sensors can be utilized for monitoring human motion information, underwater distress and smart alarms, revealing the great potential application in the field of underwater strain sensors. [ABSTRACT FROM AUTHOR]

Published

2024

118. A High‐Sensitive Rubber‐Based Sensor with Integrated Strain and Humidity Responses Enabled by Bionic Gradient Structure.

Author

Yang, Yunpeng, Kong, Lingli, Huang, Bai, Lin, Baofeng, Fu, Lihua, and Xu, Chuanhui

Subjects

*STRAIN sensors, *HYDROGEN bonding interactions, *POLYBUTADIENE, *ELECTRIC conductivity, *TISSUES

Abstract

Real‐time detection of different physiological characteristics is crucial for human physical and mental health. A detection system with multimodal sensing capability, high sensitivity, excellent mechanical properties, and environmental stability is highly desirable, but it is still a great challenge. Inspired by the structural gradient of biological tissues, a multifunctional sensor based on carboxylic styrene butadiene rubber (XSBR) and sodium polyacrylate (PAANa) non‐covalently modified MXenes is prepared in this study, in which the MXenes exhibit a gradient distribution and simultaneously formed an orientation arrangement at the bottom of the matrix through the formation of hydrogen bonding interactions with PAANa. The material shows a considerable stretchability of 244% and strength of 7.67 MPa, high electrical conductivity of 55.40 S m‒1, low percolation threshold of 2.48 wt%, and excellent response to strain (gauge factor of 906.7 within 98% strain) and humidity (relative resistance change of 530% within 11–93% relative humidity). Based on the superior performances of the XSBR/PAANa/MXene composite, an integrated detection system is designed to accurately detect respiration and body movements at various scales. This work provides a new perspective for the development of a novel biomimetic functional material for sensor applications. [ABSTRACT FROM AUTHOR]

Published

2024

119. A Strain‐Temperature Integrated Polymer‐Derived SiCN Ceramic High Temperature Sensor with Wide‐Range and Ultra‐Short Response Time.

Author

Yang, Mengmeng, Ma, Chao, Hu, Yibo, Wang, Kang, Zhao, Rui, Liang, Yi, Han, Daoyang, Wang, Hailong, Zhang, Rui, and Shao, Gang

Subjects

*STRAIN sensors, *HIGH temperatures, *TEMPERATURE sensors, *STRAIN rate, *EXTREME environments

Abstract

Fabricating strain sensors with high response in a wide temperature and strain range is still a challenge, especially in high temperature harsh environments. Herein, a dual‐functional sensor with cantilever beam structure is fabricated using polymer‐derived SiCN ceramics, which can be applied for temperature and stain monitor. The performance of the integrated sensor is evaluated from room temperature to 1000 °C and the related sensing mechanism is analyzed. The prepared strain sensor has ultrafast response of 60 ms in the strain range of 0–3500 µε and the maximum strain rate can reach 46 200 µε s−1. Moreover, the sensor has excellent stability and ultra‐high sensitivity under high temperature environments. Additionally, the temperature can be detected separately up to 1000 °C without any disturbance. This attractive integration sensor with competitive sensitivity, excellent stability, ultrafast response speed, and broad range, has great potential to detect temperature and strain signals for practical application in high temperature extreme environments. [ABSTRACT FROM AUTHOR]

Published

2024

120. Study of Large Strain OFDR Sensor Based on Inclined Transfer Structure.

Author

Tong, Zhengrong, Li, Sibo, and Li, Peng

Subjects

*STRUCTURAL health monitoring, *STRAIN sensors, *CIVIL engineering, *LASER ranging, *OPTICAL fibers

Abstract

In the fields of structural health monitoring, civil engineering safety monitoring, aerospace and other fields, the key challenge is to increase the range of strain measurements to solve with the information monitoring of large strains. Reducing the strain sensitivity of the sensor is an important way to solve the problem of small sensor ranges. In this paper, the inclined transfer structure is proposed to achieve large strain distributed optical fiber sensing. When the fiber is axially stretched directly to fracture, the inclined transfer structure is used to increase the strain measurement range of the system. The theoretical relationship between the strain monitored by single mode fiber sensors and the matrix strain is established. It is experimentally verified that the inclined transfer structure using polypropylene material as the matrix achieves the strain measurement from 36667μ휀 at sensing spatial resolution of 8mm, 10nm wavelength tuning range of the laser source and 45∘ inclined angle, obtaining a good linear fit of more than 0.99. One hour stability of less than 11pm is obtained, corresponding to the strain of 9μ휀. [ABSTRACT FROM AUTHOR]

Published

2024

121. A Semi‐Interpenetrating Poly(Ionic Liquid) Network‐Driven Low Hysteresis and Transparent Hydrogel as a Self‐Powered Multifunctional Sensor.

Author

Han, Shaowei, Hu, Yongkang, Wei, Jia, Li, Songwei, Yang, Peipei, Mi, Haoyang, Liu, Chuntai, and Shen, Changyu

Subjects

*NANOGENERATORS, *FLEXIBLE electronics, *MORSE code, *STRAIN sensors, *ELECTRONIC equipment, *TRIBOELECTRICITY

Abstract

Conductive hydrogels are gaining significant attention as promising candidates for the fabrication materials for flexible electronics. Nevertheless, improving the tensile properties, hysteresis, durability, adhesion, and electrochemical properties of these hydrogels remains challenging. This work reports the development of a novel semi‐interpenetrating network poly(ionic liquid) hydrogel named PATV, via the in situ polymerization of acrylamide, N‐[Tris(hydroxymethyl)methyl] acrylamide, and 1‐vinyl‐3‐butylimidazolium tetrafluoroborate. The density functional theory calculations reveal that the poly(ionic liquid) in the hydrogel network acts as physical cross–linking points to construct hydrogen‐bond networks. Furthermore, the hydrogen‐bond networks dissipate energy efficiently and quickly, and thus stress concentration and hysteresis are avoided. The prepared hydrogel has a low hysteresis (9%), high tensile properties (900%), fast response (180 ms), high sensitivity (gauge factor = 10.4, pressure sensitivity = 0.14 kPa−1), and wide sensing range (tensile range: 1–600%, compression range: 0.1–20 kPa). A multifunctional sensor designed based on the designed hydrogel enables real‐time, rapid, and stable response‐ability for the detection of human movement, facial expression recognition, pronunciation, pulse, handwriting, and Morse code encryption. Furthermore, the assembled triboelectric nanogenerator displays an excellent energy harvesting capability, thus highlighting its potential application in self‐powered flexible wearable electronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

122. 3D printing conductive hydrogel with low modulus and anti‐swelling for customized strain sensors.

Author

Chen, Chaojie, Cui, Guoqing, Li, Yuanlong, Liu, Li, and Wu, Guangfeng

Subjects

STRAIN sensors, THREE-dimensional printing, YOUNG'S modulus, FERRIC chloride, HYDROGELS, CHLORIDE ions

Abstract

Developing antiswelling hydrogel that retains their low modulus and has three‐dimensional (3D) printability to application in the biomedical field is a current critical issue. Here, we synthesized 3D printing ink consist of poly(acrylic acid‐acrylamide‐allyloxypolyethyleneglycol) (P(AA‐Am‐APEG)) and nanosilica (SiO2) by free radical polymerization, immersed the hydrogel precursor printed by ink in ferric chloride solution to prepare a low modulus, antiswelling, and conductive hydrogel. In the physical cross‐linking network, the coordination interaction and hydrogen bonds contributed to excellent mechanical properties and nSiO2 regulated rheological behavior of ink. Especially, P(AA‐Am‐APEG) molecular chain was a structure containing of APEG branch chain, which could endow antiswelling (the equilibrium swelling rate was only 7% in deionized water) and low modulus (Young's modulus was less than 100 kPa) to hydrogel. The tensile stress could still maintain 90% of the original value after soaking for 24 h. In addition, the existence of iron and chloride ions provided high sensitive deformation‐dependent conductivity to hydrogel. Therefore, the strategy of controlling the swelling and modulus by branch chains would expand the application of hydrogel in biosensors and other fields. [ABSTRACT FROM AUTHOR]

Published

2024

123. A Highly Sensitive and Stretchable Core–Shell Fiber Sensor for Gesture Recognition and Surface Pressure Distribution Monitoring.

Author

Yan, Weizhe, Liu, Andeng, Luo, Yingjin, Chen, Zhuomin, Wu, Guoxu, Chen, Jianfeng, Huang, Qiaoling, Yang, Yun, Ye, Meidan, and Guo, Wenxi

Subjects

*FLEXIBLE electronics, *STRAIN sensors, *SURFACE pressure, *CARBON fibers, *BALLS (Sporting goods), *CARBON nanotubes

Abstract

This work reports a highly‐strain flexible fiber sensor with a core–shell structure utilizes a unique swelling diffusion technique to infiltrate carbon nanotubes (CNTs) into the surface layer of Ecoflex fibers. Compared with traditional blended Ecoflex/CNTs fibers, this manufacturing process ensures that the sensor maintains the mechanical properties (923% strain) of the Ecoflex fiber while also improving sensitivity (gauge factor is up to 3716). By adjusting the penetration time during fabrication, the sensor can be customized for different uses. As an application demonstration, the fiber sensor is integrated into the glove to develop a wearable gesture language recognition system with high sensitivity and precision. Additionally, the authors successfully monitor the pressure distribution on the curved surface of a soccer ball by winding the fiber sensor along the ball's surface. [ABSTRACT FROM AUTHOR]

Published

2024

124. Smartphone‐based method for measuring maximum peak tensile and compressive strain.

Author

Chen, Xixian, Li, Huan, Zhao, Chenhao, Zhou, Guangyi, Li, Weijie, Zhang, Xue, and Zhao, Xuefeng

Subjects

*STRUCTURAL engineering, *SEISMIC response, *STRAIN sensors, *DYNAMIC testing, *SMARTPHONES, *POWER resources, *COMPRESSED sensing

Abstract

This paper proposes an innovative smartphone‐based strain sensing method (named MaxCpture) for measuring maximum peak tensile and compressive strains. The MaxCpture method is able to record the maximum peak strain of a structure without continuous power supply and real‐time monitoring. This method combines the maximum peak strain sensor, a smartphone, and the microimage sensing algorithm. Crucially, the novel clamping sensitive mechanism in the sensor preserves information about the maximum deformation of the structure. To validate the feasibility of the MaxCpture method, this study conducted a series of experiments, including static tests, the beam of constant strength tests, and dynamic tests. The results show that the MaxCpture method is able to measure the maximum peak tensile and compressive strain effectively. With its convenient acquisition, low cost, and multi‐user collaboration, the MaxCpture method provides a promising approach for seismic response detection of various engineering structures. [ABSTRACT FROM AUTHOR]

Published

2024

125. Molecular Ferroelastic Induced by Mono‐/Double‐Protonation Strategy.

Author

Luo, Jia‐Qi, Lun, Meng‐Meng, Jia, Qiang‐Qiang, Wang, Zhi‐Jie, Lu, Hai‐Feng, Zhang, Yi, and Fu, Da‐Wei

Subjects

*PHASE transitions, *STRAIN sensors, *PRESSURE sensors, *MOLECULAR crystals, *SCIENTIFIC community, *PROTON transfer reactions

Abstract

Comprehensive Summary: Molecular ferroelastics with the natural features of mechanical flexibility and switchable spontaneous strain have attracted widespread attention in the scientific community due to their potential applications in tunable gratings, flexible memorizers, strain sensors, and intelligent actuators. However, most designs of molecular ferroelastics remain in the stage of blind exploration, posing a challenge to achieve a functional ferroelastic more effectively. Herein, we have successfully obtained a molecular ferroelastic, [Me2NH(CH2)2NH3](ReO4)2 (Me2NH(CH2)2NH3 = N,N‐dimethylethylenediammonium), under the guidance of the mono‐/double‐protonation strategy. The double‐protonated [Me2NH(CH2)2NH3](ReO4)2 undergoes a paraelastic‐ferroelastic phase transition with the Aizu notation of 2/mF1¯ at 322 K. Meanwhile, the theoretical calculation and experimental measurement simultaneously show that [Me2NH(CH2)2NH3](ReO4)2 possesses good mechanical flexibility, because its elastic modulus (E) of 8.26 GPa and hardness (H) of 0.45 GPa are smaller than the average values of organic crystals (E of 12.05 GPa and H of 0.5 GPa), which makes it promising to apply in wearable pressure sensors, implantable medical sensors, high‐precision tuners, etc. This work further enriches the molecular ferroelastic family and demonstrates that mono‐/double‐protonation is one of the effective molecular modification strategies for designing ferroelastics. [ABSTRACT FROM AUTHOR]

Published

2024

126. Temperature insensitive distributed wide-dynamic-range strain sensing based on polarization-maintaining photonic crystal fiber.

Author

Xu, Zhenyuan, Geng, Youfu, Zhu, Xiaojian, Lu, Jing, Yi, Duo, Du, Yu, Wang, Jiaqi, Hong, Xueming, and Li, Xuejin

Subjects

*PHOTONIC crystal fibers, *STRUCTURAL health monitoring, *STRAIN sensors, *DISTRIBUTED sensors, *SPATIAL resolution, *OPTICAL resolution

Abstract

In this paper, a temperature insensitive wide-dynamic-range distributed strain sensor with centimeter-level spatial resolution based on optical frequency domain reflection technology is proposed. It adopts a polarization-maintaining photonic crystal fiber as the sensing fiber, and experimental results demonstrate that its temperature sensitivity is much smaller than that of the standard polarization-maintaining fiber. Benefited from the specially designed cross-correlation algorithm, the sensor achieves the maximum measurable strain reaches 7000 μϵ with spatial resolution of 1.66 cm. This provides a new approach to address current issues with special fiber sensors, such as single-point sensing and low spatial resolution, which shows great significance for structural health monitoring of buildings, bridges and tunnels with urgent requirement of large dynamic range. [ABSTRACT FROM AUTHOR]

Published

2024

127. A Multi-Sensing IoT System for MiC Module Monitoring during Logistics and Operation Phases.

Author

Arshad, Husnain and Zayed, Tarek

Subjects

*STRUCTURAL health monitoring, *SUPPLY chain disruptions, *MODULAR construction, *STRAIN sensors, *FIELD research, *GYROSCOPES

Abstract

Modular integrated construction (MiC) is now widely adopted by industry and governments. However, its fragile and delicate logistics are still a concern for impeding project performance. MiC logistic operations involve rigorous multimode transportation, loading-unloading, and stacking during storage. Such processes may induce latent and intrinsic damage to the module. This damage causes safety hazards during assembly and deteriorates the module's structural health during the building use phase. Also, additional inspection and repairs before assembly cause uncertainties and can delay the whole supply chain. Therefore, continuous monitoring of the module's structural response during MiC logistics and the building use phase is vital. An IoT-based multi-sensing system is developed, integrating an accelerometer, gyroscope, and strain sensors to measure the module's structural response. The compact, portable, wireless sensing devices are designed to be easily installed on modules during the logistics and building use phases. The system is tested and calibrated to ensure its accuracy and efficiency. Then, a detailed field experiment is demonstrated to assess the damage, safety, and structural health during MiC logistic operations. The demonstrated damage assessment methods highlight the application for decision-makers to identify the module's structural condition before it arrives on site and proactively avoid any supply chain disruption. The developed sensing system is directly helpful for the industry in monitoring MiC logistics and module structural health during the use phase. The system enables the researchers to investigate and improve logistic strategies and module design by accessing detailed insights into the dynamics of MiC logistic operations. [ABSTRACT FROM AUTHOR]

Published

2024

128. Strain Gauge Calibration for High Speed Weight-in-Motion Station.

Author

Socha, Agnieszka and Izydorczyk, Jacek

Subjects

*STRAIN gages, *STRAIN sensors, *TRAFFIC flow, *SPEED limits, *MASS measurement

Abstract

The development of systems for weighing vehicles in motion aims to introduce systems allowing automatic enforcement of regulations. HSWIM (high speed weight-in-motion) systems enable measurement of a mass of vehicles passing through a measurement station without disturbing the traffic flow. This article focuses on the calibration of a weighing station for moving vehicles, where strain gauge sensors are used to measure pressures. A solution was proposed to replace the calibration coefficients with calibration functions. The analysis was performed for two methods of determining wheel loads: based on the maximum of the signal from strain gauge sensors and on a method using the field under the signal and the vehicle's speed. Calibration functions were determined jointly for all test vehicles and separately for each of them. The use of a calibration function for a specific vehicle type made it possible to determine wheel pressure and gross weight with a level of accuracy that allowed the weigh-in-motion station to be classified as a direct enforcement system. The achieved improvement in the accuracy of weighing in motion did not require any interference with the measurement station. The proposed change in the method of calibration and, ultimately, determination of wheel loads required only a change in the algorithm for determining wheel loads. [ABSTRACT FROM AUTHOR]

Published

2024

129. Integrating High-Performance Flexible Wires with Strain Sensors for Wearable Human Motion Detection.

Author

Wu, Pucheng and He, Hu

Subjects

*CONDUCTIVE ink, *LIQUID metals, *FLEXIBLE electronics, *STRAIN sensors, *HUMAN mechanics

Abstract

Flexible electronics have revolutionized the field by overcoming the rigid limitations of traditional devices, offering superior flexibility and adaptability. Conductive ink performance is crucial, directly impacting the stability of flexible electronics. While metal filler-based inks exhibit excellent conductivity, they often lack mechanical stability. To address this challenge, we present a novel conductive ink utilizing a ternary composite filler system: liquid metal and two micron-sized silver morphologies (particles and flakes). We systematically investigated the influence of filler type, mass ratio, and sintering process parameters on the composite ink's conductivity and mechanical stability. Our results demonstrate that flexible wires fabricated with the liquid metal/micron silver particle/micron silver flake composite filler exhibit remarkable conductivity and exceptional bending stability. Interestingly, increasing the liquid metal content results in a trade-off, compromising conductivity while enhancing mechanical performance. After enduring 5000 bending cycles, the resistance change in wires formulated with a 4:1 mass ratio of micron silver particles to flakes is only half that of wires with a 1:1 ratio. This study further investigates the mechanism governing resistance variations during flexible wire bending. Additionally, we observed a positive correlation between sintering temperature and pressure with the conductivity of flexible wires. The significance of the sintering parameters on conductivity follows a descending order: sintering temperature, sintering pressure, and sintering time. Finally, we demonstrate the practical application of this technology by integrating the composite ink-based flexible wires with conductive polymer-based strain sensors. This combination successfully achieved the detection of human movements, including finger and wrist bending. [ABSTRACT FROM AUTHOR]

Published

2024

130. Flexible Strain Sensors Based on Thermoplastic Polyurethane Fabricated by Electrospinning: A Review.

Author

Zhou, Zhiyuan, Tang, Weirui, Xu, Teer, Zhao, Wuyang, Zhang, Jingjing, and Bai, Chuanwu

Subjects

*STRAIN sensors, *CARBON-based materials, *CONDUCTING polymers, *FILLER materials, *ELECTROSPINNING

Abstract

Over recent years, thermoplastic polyurethane (TPU) has been widely used as a substrate material for flexible strain sensors due to its remarkable mechanical flexibility and the ease of combining various conductive materials by electrospinning. Many research advances have been made in the preparation of flexible strain sensors with better ductility, higher sensitivity, and wider sensing range by using TPU in combination with various conductive materials through electrospinning. However, there is a lack of reviews that provide a systematic and comprehensive summary and outlook of recent research advances in this area. In this review paper, the working principles of strain sensors and electrospinning technology are initially described. Subsequently, recent advances in strain sensors based on electrospun TPU are tracked and discussed, with a focus on the incorporation of various conductive fillers such as carbonaceous materials, MXene, metallic materials, and conductive polymers. Moreover, the wide range of applications of electrospun TPU flexible strain sensors is thoroughly discussed. Finally, the future prospects and challenges of electrospun TPU flexible strain sensors in various fields are pointed out. [ABSTRACT FROM AUTHOR]

Published

2024

131. Heating and Strain Sensing Elements Based on Segregated Polyethylene/Carbon Black Composites in Polymer Welded Joints.

Author

Buinova, Yevheniia, Kobyliukh, Anastasiia, Mamunya, Yevgen, Maruzhenko, Oleksii, Korab, Mykola, Trzebicka, Barbara, Szeluga, Urszula, and Godzierz, Marcin

Subjects

*CONDUCTING polymer composites, *HIGH density polyethylene, *SURFACE analysis, *CARBON-black, *STRAIN sensors

Abstract

The development of easy and direct real-time monitoring of welded joint quality instead of surface damage analysis is crucial to improve the quality of industrial products. This work presents the results of high-density polyethylene (HDPE)-based composites with various carbon black (CB) content (from 20 to 30 vol.%) for use as a heating element and strain sensor in electrofusion-welded polymer joints. The pyroresistive heating process was used to determine the effect of generated Joule heat during welding on the structure and sensor properties of polymer–carbon composites. It is shown that the generation of Joule heat depends on the nanocarbon content and affects the crystallinity of the polymer matrix. The partial disruption of the conductive path of carbon black particles was observed and, as a result, a decrease in electrical conductivity for composites with lower CB content after welding was found. For the highest CB amount, conductivity increased, which is caused by smaller particle-to-particle distance for filler paths. Therefore, the best balance between pyroresistive and sensor properties was found. [ABSTRACT FROM AUTHOR]

Published

2024

132. Liquid Metal‐Based Sensor Skin Enabling Haptic Perception of Softness.

Author

Chen, Haotian, Furfaro, Ivan, Fernández Lavado, Emilio, and Lacour, Stéphanie P.

Subjects

*METALLIC films, *LIQUID metals, *LIQUID films, *STRAIN sensors, *PRESSURE sensors, *ROBOT hands

Abstract

Haptic perception of softness is a unique feature of the human skin that relies on the concurrent measurements of the lateral deformation and compression of the skin during object manipulation. This is challenging to implement in robotics because of combined requirements in sensing modalities, skin format, robotic structures, and synthetic materials. A soft sensory skin supporting distributed and bimodal mechanical sensing over large surface area and suitable for robotic hand manipulation is reported. Resistive pressure and strain sensors are prepared with spray‐coated liquid metal films embedded in a silicone matrix. Object softness is computed through a calibrated model based on both sensor response curves and the stiffness of the carrier robot. The soft sensory skin enables localization and discrimination of softness that promise interesting future implementation for robotic palpation or precise teleoperation. [ABSTRACT FROM AUTHOR]

Published

2024

133. Strain rate sensitive polyampholyte hydrogels via well-dispersed XLG sheets.

Author

Su, Esra, Yelemessova, Gaukhargul, and Toleutay, Gaukhar

Subjects

*STRAIN rate, *IONIC solutions, *DRUG delivery systems, *STRAIN sensors, *SILICATE minerals, *CATIONIC polymers

Abstract

The physical interactions between anionic and cationic monomers and the layered silicate clay mineral Laponite (XLG) have received great attention because of their potential for a variety of applications such as strain sensitive sensors, wearable electronics, drug delivery systems, and tissue engineering applications. A detailed investigation of the interaction between XLG and charged monomers is presented in this article. The study includes the observation of the changes in the viscosity of the solutions and the mechanical performance of the gels at various concentrations by adding XLG to the ionic monomer solution. The ionic interactions between XLG and the charged monomers, driven by electrostatic forces, play a crucial role in gelation and formation of a three-dimensional network, giving the structure strain rate sensitivity. In this way, the addition of XLG nanoparticles not only improves the mechanical properties of the gels, but also gives us information about the microstructure of the mechanical properties that change depending on the strain rate. [ABSTRACT FROM AUTHOR]

Published

2024

134. Flaw Detection by SHM with Static Sensors Approach: State of the Art and Perspectives.

Author

D'Amore, Alberto, Grassia, Luigi, and Iannone, Michele

Subjects

*STRUCTURAL health monitoring, *STRAIN gages, *STRAIN sensors, *FINITE element method, *AIRFRAMES

Abstract

Structural health monitoring (SHM) is a technology aimed to monitor the soundness of the structures. Applications for aircraft structures are largely investigated. The goal is to utilize the information acquired during the monitoring to save maintenance costs, improve flight safety, and design lighter structures. Different issues, like load monitoring and impact detection, are investigated by SHM research. The most largely investigated issue is damage detection, i.e., developing a system that utilizes sensors to detect the damage in the structure. Damage detection can be performed with two sensors: dynamic and static. Dynamic sensors work by transmission of waves through the structures. Defects are identified by deviation and reflection of the waves by damages. The SHM approach described in this work is based on static sensors, like strain gages or fiber optics. The strain fields under load in pristine and damaged conditions are compared; the evaluation of the change in the strain field identifies damages. Two different algorithms for damage detection have been developed and patented in Leonardo Aircraft and are described in this work; they are based on the reverse finite element model (FEM) and neural network. The issues related to the strain field measurement are also briefly described. [ABSTRACT FROM AUTHOR]

Published

2024

135. Architecture tailoring of smart knitted double face comfortable strain sensors for Intelligent (E-textiles) application.

Author

Abbas, Adeel and Anas, Muhammad Sohaib

Abstract

Textiles-oriented flexible strain sensors have been attractive in designing intelligent clothing materials to sense the human body postural changes. However, their efficacy towards sensing performance can be tailored through fabrication architectures variation. In this study knitted strain sensors have been engineered using novel double face fabric designs. Filament polyester, and conductive polyamide coated with silver colloidal particles were used to architect sensors. The sensors provide real-time electrical resistance variation as a sensing feature w.r.t mechanical changes happening in them. Two-dimensional strain testing and comfortability evaluations were carried out to ensure sensing performance and comfortable wearing longevity of sensors. Decreasing linking yarn accumulation per unit area increased the strain sensitivity i.e. changing knit stitches with tuck and miss the sensing capability increased 28% and 95%, respectively. Comfortability of sensors had a parabolic trend, decreasing yarn accumulation enhanced comfort up to tuck-linking courses. While increasing the percentage of conductive polyamide in the linking course improved strain sensitivity by 50%. The research presents such double-face intelligent strain sensors as a suitable solution to the long-term wearability of sensors with comfort. [ABSTRACT FROM AUTHOR]

Published

2024

136. Revolutionizing digital healthcare networks with wearable strain sensors using sustainable fibers.

Author

Zhang, Junze, Xu, Bingang, Chen, Kaili, Li, Yi, Li, Gang, and Liu, Zekun

Subjects

STRAIN sensors, WEARABLE technology, DIGITAL health, SMART structures, BODY area networks, FLEXIBLE electronics

Abstract

Wearable strain sensors have attracted research interest owing to their potential within digital healthcare, offering smarter tracking, efficient diagnostics, and lower costs. Unlike rigid sensors, fiber‐based ones compete with their flexibility, durability, adaptability to body structures as well as eco‐friendliness to environment. Here, the sustainable fiber‐based wearable strain sensors for digital health are reviewed, and material, fabrication, and practical healthcare aspects are explored. Typical strain sensors predicated on various sensing modalities, be it resistive, capacitive, piezoelectric, or triboelectric, are explained and analyzed according to their strengths and weaknesses toward fabrication and applications. The applications in digital healthcare spanning from body area sensing networks, intelligent health management, and medical rehabilitation to multifunctional healthcare systems are also evaluated. Moreover, to create a more complete digital health network, wired and wireless methods of data collection and examples of machine learning are elaborated in detail. Finally, the prevailing challenges and prospective insights into the advancement of novel fibers, enhancement of sensing precision and wearability, and the establishment of seamlessly integrated systems are critically summarized and offered. This endeavor not only encapsulates the present landscape but also lays the foundation for future breakthroughs in fiber‐based wearable strain sensor technology within the domain of digital health. [ABSTRACT FROM AUTHOR]

Published

2024

137. A Flexible Wearable Strain Sensor Based on Nano-Silver-Modified Laser-Induced Graphene for Monitoring Hand Movements.

Author

Zhong, Mian, Zou, Yao, Fan, Hongyun, Li, Shichen, Zhao, Yilin, Li, Bin, Li, Bo, Jiang, Yong, Xing, Xiaoqing, Shen, Jiaqing, and Zhou, Chao

Subjects

STRAIN sensors, SILVER nanoparticles, WEARABLE technology, REFERENCE values, GRAPHENE

Abstract

The advancement in performance in the domain of flexible wearable strain sensors has become increasingly significant due to extensive research on laser-induced graphene (LIG). An innovative doping modification technique is required owing to the limited progress achieved by adjusting the laser parameters to enhance the LIG's performance. By pre-treating with AgNO3, we successfully manufactured LIG with a uniform dispersion of silver nanoparticles across its surface. The experimental results for the flexible strain sensor exhibit exceptional characteristics, including low resistance (183.4 Ω), high sensitivity (426.8), a response time of approximately 150 ms, and a relaxation time of about 200 ms. Moreover, this sensor demonstrates excellent stability under various tensile strains and remarkable repeatability during cyclic tests lasting up to 8000 s. Additionally, this technique yields favorable results in finger bending and hand back stretching experiments, holding significant reference value for preserving the inherent characteristics of LIG preparation in a single-step and in situ manner. [ABSTRACT FROM AUTHOR]

Published

2024

138. Experimental Proof of Concept for Using Hybrid Paper Based on Silver Nanowires, Cellulose and Poly(dimethylsiloxane) in Systems Dynamic Analysis and Healthcare Applications.

Author

Dzido, Grzegorz, Piotrowski, Krzysztof, Sakiewicz, Piotr, Gołombek, Klaudiusz, Bańbuła, Sonia, Domagała, Natalia, Ratajczak, Martyna, Kunert, Mateusz, and Ignaszewska, Agnieszka

Subjects

FLEXIBLE electronics, MATERIALS testing, STRAIN sensors, DEFORMATIONS (Mechanics), SUBSTRATES (Materials science)

Abstract

The research results and evaluation of the applicability of the original composition of hybrid paper based on silver nanowires (AgNWs), cellulose pulp (CP), and carbon nanotubes (CNTs) are presented and discussed. The material tested was used to manufacture sensors for mechanical deformation resulting from external influences or related to human activity interactions. The sensors were fabricated using an AgNWs + CP suspension and additives by the vacuum filtration method. The substrate obtained was machined and then laminated with a layer of poly(dimethylsiloxane) (PDMS). The recorded responses to selected types of imposed mechanical interactions in the form of changes in the relative resistance of the sensor throughout the tests showed a close cause-and-effect relationship. The response of the tested systems when applying an alternating magnetic field was also observed. The results indicate that the proposed solutions can find application in the monitoring of mechanical interactions resulting from the dynamic behavior of physical objects, as well as derived from selected human vital functions. [ABSTRACT FROM AUTHOR]

Published

2024

139. Towards a 3D Printed Strain Sensor Employing Additive Manufacturing Technology for the Marine Industry.

Author

Kouvatsos, Theodoros, Pagonis, Dimitrios Nikolaos, Iakovidis, Isidoros, and Kaltsas, Grigoris

Subjects

SPARE parts, MARINE engineering, STRAIN gages, STRAIN sensors, CIRCULAR economy

Abstract

This study focuses on the successful fabrication of a cost-effective strain sensor using exclusively additive manufacturing Fused Deposition Modeling (FDM) technology, enabling fast on-site production, which is particularly advantageous in maritime settings, reducing downtime, and supporting a circular economy approach by minimizing inventory needs and environmental footprint. The principle of operation of the developed device is based on the piezoresistive characteristics of a carbon nanotube (CNT)-enriched building material, from which the main sensing element consists. The prototype exhibited reliable piezoresistive properties, and a clear correlation was observed between the thermal treatment of the printed piezoresistor and the resulting gauge factor, linearity, and hysteresis. Its robustness, simple design, and single-step manufacturing process, together with its ability to be integrated into the readout circuitry through standard soldering, enhance its reliability and durability. The key advantages of the proposed device include its low cost, simple design, and rapid remote production. [ABSTRACT FROM AUTHOR]

Published

2024

140. Evaluation of the Strengthening Effects on Prestressed Carbon-Fiber-Reinforced-Polymer-Strengthened Steel Beam Bridges Using Macro-Strain Influence Lines.

Author

Wu, Bitao, Xia, Qingquan, Gong, Yan, Fu, Sicheng, Wang, Haitao, and Guo, Zhongzhao

Subjects

FIBER Bragg gratings, LIVE loads, STRAIN sensors, EVALUATION methodology, STEEL

Abstract

Effectively evaluating the effectiveness of bridge strengthening is a necessary means to ensure the normal operation of existing strengthened bridges, especially when evaluating the effectiveness of bridge strengthening without interrupting normal traffic. Based on a distributed long-gauge Fiber Bragg Grating (FBG) sensor, this paper derived the macro-strain influence line (MSIL) formula for a simply supported beam bridge under a moving vehicle load, studied the changes in the MSIL at the bottom of the beam under the vehicle load before and after the prestressed CFRP plate strengthening, and proposed a rapid evaluation method for the strengthening effect based on the amplitude of the MSIL as the evaluation index for the strengthening effect. Finally, the prestressed CFRP-strengthened steel beam was tested under the moving vehicle load. The theoretical analysis and the experimental results confirm that under the load of moving vehicles, the macro-strain–time history amplitude of the strengthened steel beams under different prestressed tensioning conditions is different. The amplitude of the macro-strain time history of the strengthened bridge is reduced compared to before strengthening, and the local strengthening effect of the bridge can be monitored by the amplitude change in a single sensor. The change in global stiffness can be evaluated by monitoring the MSIL obtained from multiple long-gauge strain sensors. [ABSTRACT FROM AUTHOR]

Published

2024

141. Field Monitoring of Cross Frames in Composite Steel I-Girder Bridges.

Author

Reichenbach, Matthew C., White, Joshua B., Park, Sunghyun, Helwig, Todd A., Engelhardt, Michael D., Connor, Robert J., and Grubb, Michael A.

Subjects

IRON & steel bridges, STEEL framing, STRAIN gages, STRAIN sensors, SERVICE life, MATERIAL fatigue, SKEWNESS (Probability theory)

Abstract

Many of the current fatigue design specifications for cross frames, especially those in composite steel bridge systems, have primarily been based on computational studies and component-level laboratory experiments. To fully understand the behavior of cross frames when subjected to in-service truck traffic and to critically evaluate legacy design provisions, in-service field monitoring of cross frames in various composite systems is important. Therefore, select cross frames in three bridges in the greater Houston area were instrumented with strain gage sensors—one straight bridge with normal supports, one straight bridge with skewed supports, and one horizontally curved bridge with radial supports. For each bridge, rainflow counting techniques and other postprocessing procedures were implemented for a monitoring period of one month to compare the measured cross-frame response. Among other key observations, the measured data demonstrated that load-induced force effects in the cross frames of the skewed bridge system exceeded those in the bridges with normal or radial supports and that cross-frame response was highly sensitive to the longitudinal and transverse truck positions. In all cases, though, the measured damage accumulated on all instrumented cross-frame members during their respective monitoring periods, if extrapolated to the entire service life, would likely not cause significant load-induced cracking in the critical welded gusset-to-member connections. [ABSTRACT FROM AUTHOR]

Published

2024

142. STRAIN TRANSFER ANALYSIS OF A FOUR-LAYER EMBEDDED FIBER OPTIC SENSING MODEL IN AN ELASTIC STATE.

Author

XUEBING, ZHANG, ZHIZHOU, ZHENG, HUAPING, WANG, and PING, XIANG

Subjects

*STRUCTURAL health monitoring, *STRAIN sensors, *OPTICAL fibers, *FOURIER series, *ELASTIC modulus, *OPTICAL fiber detectors

Abstract

Optical fiber grating strain sensors are currently utilized in a variety of structural health monitoring applications. The encapsulated fiber optic sensor is unable to completely detect the strain of the structure, so the strain transfer theory should be established to maximize the strain sensing of fiber. It is required to explore the embedded four-layer fiber optic sensing model to create a more plausible strain transfer error hypothesis. Based on the three-layer fiber optic sensing model, the Goodman assumption and Fourier series approach were presented to study the strain transfer efficiency of the four-layer model in the elastic state. First, the physical quantity to be analyzed is determined, and finally the radius, interlayer bonding coefficient and elastic modulus are selected as the parameters affecting the strain transfer efficiency. The length range of efficiency evaluation is 0–2.5m, and the transfer efficiency under different radii is above 0.90 when the length L≥2.2m. The interlayer bonding coefficient kf between 1×1010N/m3 and 2×1011N/m3 has little impact on the transfer efficiency, and the same is true for ka, so it cannot be considered in practice. When kp is between 2.5×1010N/m3 and 1×1011N/m3 and the length L>2m, the strain transfer coefficient reaches 95%. The influence of elastic modulus on the transfer efficiency is very significant when L≤0.4m. The four-layer model performs similarly to the three-layer model within the paste length range of 1.0m, but has a superior strain transfer effect when the pasted length exceeds 1.0m. As the radius of the protective layer rises, the effect of strain transfer deteriorates. [ABSTRACT FROM AUTHOR]

Published

2024

143. Insights from dispersion in carbon nanotubes‐based poly(vinylidene fluoride‐co‐hexafluoropropylene) wearable sensors via solvent casting.

Author

Díaz‐Mena, V., Sánchez‐Romate, Xoan F., Sánchez, M., and Ureña, A.

Subjects

*WEARABLE technology, *STRAIN sensors, *CARBON nanotubes, *LOW temperatures, *ELECTRIC conductivity

Abstract

Highlights Flexible sensors, made of PVDF‐HFP reinforced with carbon nanotubes (CNTs), are manufactured by solvent casting. More specifically, the effect of evaporation temperature and sonication time is explored. It is seen that two effects govern the dispersion of CNT: the sedimentation half‐time, and the breakage induced by the ultrasonication process. In this regard, it is found that 60°C is an optimum evaporation temperature to reach the highest value of electrical conductivity, since it offers a good balance between these effects, leading to the creation of a more efficient electrical network. This is also confirmed by the AC analysis, where these samples show the highest characteristic frequencies. The electromechanical results show a greater dependency on evaporation temperature for low sonication times, as the breakage induced by an ultrasonic process is not so pronounced and, therefore, the sedimentation effect plays a more dominant role. In addition, cycling tests show robust electromechanical response with cycling, and creep tests prove good electrical response of the sensors, less than 200 ms in some cases. Finally, proof of concept testing of wrist, shoulder, and neck monitoring highlights the potential of the proposed materials for sensing applications. PVDF‐HFP/CNT nanocomposite strain sensors via solvent casting are proposed. The effect of evaporation temperature and sonication time is studied. DC and AC conductivities were analyzed and modeled via an equivalent circuit. An outstanding Gauge Factor of 86.30 × 104 is achieved at 95% of strain level. Two proof‐of‐concepts of medium and large movements are successfully achieved. [ABSTRACT FROM AUTHOR]

Published

2024

144. Anchoring Solvent Molecules onto Polymer Chains Through Dynamic Interactions for a Wide Temperature Range Adaptable and Ultra‐Fast Responsive Adhesive Organogels.

Author

Zheng, Xiuwen, Zhou, Xiangfu, Yang, Yaolong, Xiong, Wenjie, Ye, Shuling, Xu, Yiting, Zeng, Birong, Yuan, Conghui, and Dai, Lizong

Subjects

*POLYMERS, *STRAIN sensors, *IONIC conductivity, *MOLECULES, *HYDROGEN bonding interactions, *POLYMER networks

Abstract

Organogels are less explored toward on‐sink flexible and stretchable electronics compared to hydrogels, due to the challenges in simultaneously achieving biocompability, satisfactory mechanical properties, environmental‐adaptive adhesion capability, and fast stimuli‐response. Herein, it is shown that a boronate ester polymer organogel with dynamic covalent and hydrogen bonds formed between the polymer networks and organic solvents meets all the above requirements. This is achieved through the gelation of a polymer bearing with boronic acid, imidazolium salt, and amide groups (named QBAM) in ethylene glycol (EG). The strong interactions between the polymer chains and the EG not only improve the toughness of QBAMs, but also inhibit the volatilization of EG, leading to a wide temperature (−10 to 190 °C) adaptability. Due to the abundant hydrogen bonds and electrostatic interaction, QBAM organogels are highly adhesive to a variety of substrates. The presence of imidazolium salt endows QBAM organogels with promising ionic conductivity. Strain sensors fabricated with QBAM organogels fit well on human skin and exhibit the advantages of high strain sensitivity (GF = 9.049), fast response (≈60.4 ms), good cyclic stability, and broaden temperature adaptability. This work opens up a new avenue for the design of multifunctional and biocompatible organogels for on‐skin devices. [ABSTRACT FROM AUTHOR]

Published

2024

145. Elastic Janus Microarray Film Strain Sensors with Heterogeneous Modulus and Conductivity for Healthcare and Braille Identification.

Author

Shao, He‐Qing, Wei, Kai‐Dong, Gong, Tao, Jia, Jin, Tang, Chun‐Yan, Zha, Xiang‐Jun, Ke, Kai, Bao, Rui‐Ying, Zhang, Kai, Wang, Yu, and Yang, Wei

Subjects

*STRAIN sensors, *BRAILLE, *SIGNAL processing, *SILVER nanoparticles, *ELECTRIC conductivity, *RAMAN scattering, *ELECTRON transport, *POLYMER clay

Abstract

Most stretchable film strain sensors generally present nonlinear electrical responses to applied strain, leading to an inaccurate acquisition of sophisticated signals, difficult signal processing, and zero‐calibration, which hampers practical applications severely. Here, a Janus hetero‐structured microarray film sensor is developed by in‐situ growth of silver nanoparticles on the surface of micro‐patterned elastomer films fabricated via low‐temperature imprinting followed by scraping‐induced particle trapping. Heterogeneous property designs in both modulus and electrical conductivity via introducing polymer microarrays enable modulating the electron transport manner in the conductive layer of elastic Janus films upon stretching, allowing to tune signal linearity effectively. Therefore, such a hetero‐structured film sensor shows good signal linearity (fluctuation of gauge factor [GF] below ±0.02) and relatively high sensitivity (GF > 10) within 55% strain, a detection limit of 0.2% strain, and a response/recovery time of 16.3/46.9 ms, respectively. Correspondingly, it enables monitoring human respiration and body motion with higher resolution compared with the nonlinear one, meanwhile, it is capable of detecting tiny pressure to discriminate braille alphabets via touch identification. Overall, it unveils a simple strategy to fabricate film strain sensors for high‐resolution healthcare and body motion monitoring, as well as electronic skins toward tactile sensing and touch identification. [ABSTRACT FROM AUTHOR]

Published

2024

146. Preparation of a nanocellulose gelatin-based ion-conducting hydrogel for flexible strain sensors.

Author

Huang, Xinmin, Wang, Yaning, Tan, Xiaobin, and Yang, Lianhe

Subjects

*STRAIN sensors, *HYDROGELS, *WEARABLE technology, *POLYACRYLAMIDE, *ALUMINUM chloride

Abstract

In this study, to improve the anti-freezing performance without affecting the tensile properties and conductive properties, a free radical graft polymerization method is used. N,N-methylene acrylamide (MBA) was used as a cross-linking agent, and Irgacure 2959 was used as an initiator to graft acrylamide (AM) onto the gelatin skeleton to construct a gelatin/polyacrylamide/nanocellulose fibril/glycerol/aluminum chloride hydrogel (GACGA). The comprehensive performance of the hydrogel was evaluated. The GACGA hydrogel still maintained a high conductivity at −30 °C, and it still had a good morphology without significant loss of quality after dehydration at room temperature for 7 days. The GACGA hydrogel has excellent stretchability, conductivity, sensitivity, and anti-freeze properties, making it ideal for smart wearable devices and soft robots. [ABSTRACT FROM AUTHOR]

Published

2024

147. Attapulgite‐Reinforced Robust and Ionic Conductive Composite Hydrogels for Digital Light Processing 3D Printing.

Author

Guo, Yunlong, Feng, Shiwei, Gao, Weizi, Cui, Jingjing, Lu, Zhe, Liang, Chen, Liu, Fukang, Mao, Zhijie, Wang, Zhenxiang, Hu, Guang, and Zhang, Biao

Subjects

*THREE-dimensional printing, *CHEMICAL stability, *STRAIN sensors, *IONIC conductivity, *POLYVINYL alcohol

Abstract

Ionic conductive hydrogels are widely used in many applications such as electrochemical energy storage, flexible electronic devices, and catalyst transistors due to their excellent ionic conductivity as well as chemical stability. However, the fragile mechanical properties and the lack of shaping methods severely limit their further applications. Herein, an ionic conductive composite hydrogel with reinforced mechanical properties is demonstrated that can be rapidly 3D printed using digital light processing technology. By using both γ‐methacryloxypropyltrimethoxysilane moderately modified attapulgite rigid particle and polyvinyl alcohol (PVA) semicrystal dual‐network reinforcement, the mechanically robust and highly conductive N,N,N‐trimethylethanaminium‐chloride‐based hydrogels are obtained, demonstrating a 5 times higher tensile strength than the initial one due to the turning and orienting of the attapulgite as well as the robust PVA secondary network. Furthermore, encapsulation strategy is used to avoid the dehydration of hydrogel, and strain sensors that exceed the strain limit of the hydrogel are fabricated through structural design. This work provides a reference for attapulgite‐reinforced hydrogel in biosensing. [ABSTRACT FROM AUTHOR]

Published

2024

148. Nanowear circuits: multiwalled carbon nanotubes transforming yarn into strain sensors.

Author

Mamatha, B., Pradeep, N., Uma, V., and Kumar, S. Mahendra

Subjects

MULTIWALLED carbon nanotubes, YARN, STRAIN sensors, NYLON yarns, CHEMICAL vapor deposition, CARBON nanotubes, ELECTROTEXTILES, HUMAN activity recognition

Abstract

The continuous monitoring of various parameters has led to the widespread use of wearable sensors, with smart yarns and textiles being a particularly active area of research due to their potential applications in wearable devices and electronic sensors. By incorporating conductive fillers into ordinary yarns, composite yarns with new and intriguing functions can be created, such as the ability to sense and monitor strain and stress. In this study, a wearable strain sensor was fabricated using multiwalled carbon nanotubes (MWCNTs) synthesized through the chemical vapour deposition (CVD) method. The optical, structural, and tensile strength properties of the MWCNTs were characterized. These MWCNTs were then coated onto several types of yarns, including nylon, polyester, silk, and cotton, using a dipping method. Silver contacts were added to the yarns to measure the strain parameters. The piezo-resistive properties, repeatability, and gauge factor of the strain sensors were investigated by applying different loads. Among all the yarns, nylon yarn exhibited excellent sensitivity and strain variation, particularly in terms of its specific piezo-resistive property. [ABSTRACT FROM AUTHOR]

Published

2024

149. The Impact of Liquids and Saturated Salt Solutions on Polymer-Coated Fiber Optic Sensors for Distributed Strain and Temperature Measurement.

Author

Weisbrich, Martin, Messerer, Dennis, Holzer, Frank, Trommler, Ulf, Roland, Ulf, and Holschemacher, Klaus

Subjects

*OPTICAL fiber detectors, *SOLUTION (Chemistry), *DISTRIBUTED sensors, *TEMPERATURE measurements, *STRAIN sensors, *MAGNESIUM chloride

Abstract

The application of distributed fiber optic strain and temperature measurement can be utilized to address a multitude of measurement tasks across a diverse range of fields, particularly in the context of structural health monitoring in the domains of building construction, civil engineering, and special foundation engineering. However, a comprehensive understanding of the influences on the measurement method and the sensors is essential to prevent misinterpretations or measurement deviations. In this context, this study investigated the effects of moisture exposure, including various salt solutions and a high pH value, on a distributed strain measurement using Rayleigh backscattering. Three fiber optic sensors with different coating materials and one uncoated fiber were exposed to five different solutions for 24 h. The study revealed significant discrepancies (∼38%) in deformation between the three coating types depending on the surrounding solution. Furthermore, in contrast to the prevailing literature, which predominantly describes swelling effects, a negative deformation (∼−47 μ ε ) was observed in a magnesium chloride solution. The findings of this study indicate that corresponding effects can impact the precision of measurement, potentially leading to misinterpretations. Conversely, these effects could be used to conduct large-scale monitoring of chemical components using distributed fiber optic sensing. [ABSTRACT FROM AUTHOR]

Published

2024

150. Recent Advances in Poly(vinyl alcohol)-Based Hydrogels.

Author

Bercea, Maria

Subjects

*CHEMICAL stability, *PACKAGING materials, *STRAIN sensors, *CHEMICAL amplification, *ORGANIC compounds

Abstract

Poly(vinyl alcohol) (PVA) is a versatile synthetic polymer, used for the design of hydrogels, porous membranes and films. Its solubility in water, film- and hydrogel-forming capabilities, non-toxicity, crystallinity and excellent mechanical properties, chemical inertness and stability towards biological fluids, superior oxygen and gas barrier properties, good printability and availability (relatively low production cost) are the main aspects that make PVA suitable for a variety of applications, from biomedical and pharmaceutical uses to sensing devices, packaging materials or wastewater treatment. However, pure PVA materials present low stability in water, limited flexibility and poor biocompatibility and biodegradability, which restrict its use alone in various applications. PVA mixed with other synthetic polymers or biomolecules (polysaccharides, proteins, peptides, amino acids etc.), as well as with inorganic/organic compounds, generates a wide variety of materials in which PVA's shortcomings are considerably improved, and new functionalities are obtained. Also, PVA's chemical transformation brings new features and opens the door for new and unexpected uses. The present review is focused on recent advances in PVA-based hydrogels. [ABSTRACT FROM AUTHOR]

Published

2024