Your search keyword '"*THREE-dimensional textiles"' showing total 483 results

1. 基于形态仿生的3D打印面料柔性结构设计.

Author

刘馨丹 and 史文莉

Subjects

BIOMIMETIC materials, THREE-dimensional textiles, FLEXIBLE structures, THREE-dimensional printing, BIONICS

Abstract

Copyright of Wool Textile Journal is the property of National Wool Textile Science & Technology Information Center and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

2. 3D simulation of warp knitted boa for visual and quicker design.

Author

Dong, Zhijia, liu, Haisang, Jiang, Gaoming, and Ma, Pibo

Subjects

WARP knitting, THREE-dimensional textiles, COORDINATE transformations, SIMULATION methods & models, KNITTING

Abstract

Recent stitch-based simulation methods permit effective and realistic simulation for the planar structure of warp-knitted fabrics. However, simulating the warp-knitted fully formed jacquard fabric with a specific shape remains a challenge. Characteristics of diversity and complexity of this kind of fabric greatly raise the simulation difficulty. We propose a new modeling and simulation method based on the mesh model with complex shapes. We start from the analysis of the double needle bed warp-knitting technique, and establish a three-dimensional fabric mesh model, producing a finer stitch placement on a double needle bed knitted structure. Due to the deformation date derived from the jacquard pattern, stitches are placed at the actual locations. The used stitches forming the fully formed products are rendered according to the jacquard pattern. Using the two-dimensional plates and corresponding three-dimensional objects as input models to define the shape of the warp-knitted products, stitches are transferred from two to three-dimensional model objects by spatial mapping. The interface of our modeling system allows for designing complex jacquard patterns and selecting specific models for warp-knitted products. The method we propose leads to a visible design process with results visualization, which is convenient for designers to modify the knitting parameters covering knitting information and jacquard pattern before the product is knitted. The simulation method can be applied to the rapid design of the warp-knitted boa, which can reduce duplicate sampling, shorten the design process, and save raw material costs. Further research will be carried out in the future to improve this simulation method. [ABSTRACT FROM AUTHOR]

Published

2024

3. X-ray CT quantification of in situ fabric evolution and shearing behaviour of granular soils of different particle shapes.

Author

Liu, Jianbin, Leung, Anthony Kwan, Jiang, Zhenliang, Kootahi, Karim, and Zhang, Zhongjian

Subjects

*COMPUTED tomography, *SOIL granularity, *THREE-dimensional textiles, *SOIL particles, *X-ray imaging

Abstract

The role of particle shape on soil mechanical response has been studied extensively especially through numerical means. The underlying micromechanics of how particle shape may affect the soil mechanical responses at element scale remains unclear. Systematic micromechanical experiments that consider in situ tracking of the evolution of fabric during the shearing process is missing. Aided by a miniaturised triaxial apparatus and X-ray computed tomography (CT), this study presents a series of triaxial compression on four granular soils with different particle shapes yet the same mineralogy, grading, and initial density. Evolution of three-dimensional soil fabric quantifiers during shearing was captured based on 192 full-field CT images. The results revealed that the initial shearing reduced the packing density without changing the particle packing pattern, followed by particle sliding and particle rotation, which redistributed the force chains and formed a new packing pattern to resist shearing, causing strain localisation, and reductions in both the contact number and concentration of contacts direction. Fabric anisotropy increased before reaching the peak and attained the maximum value as the soil approached the critical state. Particle shape, especially when quantified by overall regularity or other combinations of descriptors, displayed more significant linear correlations with critical-state parameters than by local descriptor. [ABSTRACT FROM AUTHOR]

Published

2024

4. Acoustic behavior of three-dimensional woven fabrics and their composites: role of fiber type and weave architecture.

Author

Paul, Parikshit, Ahirwar, Meenakshi, and Behera, B. K.

Subjects

ABSORPTION of sound, AIR resistance, THREE-dimensional textiles, FLOW coefficient, WOVEN composites

Abstract

The ability of composites to insulate against noise and heat is crucial when utilized in buildings and other public structures and provide enhanced load bearing properties. Three-dimensional (3D) woven textile structural fabric and composites are one of the least investigated. Therefore, in this research, the acoustic behavior of various woven structures was investigated. The effect of weave geometry, weave architecture, number of stuffer layers, etc. on the acoustic behaviors of 3D woven orthogonal fabrics was studied. The textile reinforced composites were also characterized for tensile properties. The acoustic performance of the woven fabrics also depends on the air porosity in the structure. Therefore, investigation of air flow resistance and its correlation with sound absorption coefficient is very essential. It was observed that the acoustic behavior of jute and flax orthogonal fabrics is superior to glass fabrics. Fiber-reinforced composites show less sound absorption characteristics due to the infusion of epoxy resin. [ABSTRACT FROM AUTHOR]

Published

2024

5. 3D fabric-based piezoresistive pressure sensor: design, preparation, performance and simulation.

Author

Su, Shusheng, Gao, Yuan, Zhou, Xinghai, Qian, Yongfang, and Lyu, Lihua

Subjects

*PRESSURE sensors, *THREE-dimensional textiles, *TECHNOLOGICAL innovations, *LOADING & unloading, *WEAVING patterns, *YARN

Abstract

The application of flexible piezoresistive pressure sensors based on textiles in wearable electronics for health monitoring and motion tracking is being explored. Textiles are inherently strain-sensitive and functional, offering wear-resistance, comfort, and versatility. However, their application potential can be greatly enhanced with improvements in precision, mechanical reliability, and long-term stability. This study developed a three-dimensional fabric piezoresistive sensor with integrated electrodes and a piezoresistive layer to address these challenges. Utilizing low preparation costs and simple fabrication processes, the sensor leveraged the synergistic effects of multiple layers of contact between fibers, yarns, and fabrics in a three-dimensional weaving structure, achieving ultra-high sensitivities of 76.48 kPa−1 at 0–5 kPa and 63.78 kPa−1 at 5–50 kPa. The sensor's operation mechanism under various working conditions was validated using COMSOL simulations. The sensor exhibits rapid response and recovery times (12/13 ms) and high stability (> 500 loading and unloading cycles). Compared to previous efforts, this sensor offers greater integration and functionality, capable of detecting breathing and a variety of limb movements. With ongoing technological advancements, flexible textile-based sensors are well-positioned to monitor individuals' physiological parameters, such as heart rate, breathing, and body temperature. These sensors could be used in various fields, including aerospace, military, environmental monitoring, and healthcare, and are expected to play an increasingly critical role in future strategic initiatives. [ABSTRACT FROM AUTHOR]

Published

2024

6. Three-Dimensional Double-Layer Multi-Stage Thermal Management Fabric for Solar Desalination.

Author

Feng, Xiao, Ge, Can, Du, Heng, Yang, Xing, and Fang, Jian

Subjects

*SOLAR thermal energy, *THREE-dimensional textiles, *PHOTOTHERMAL conversion, *HEAT losses, *WIND speed

Abstract

Water scarcity is a serious threat to the survival and development of mankind. Interfacial solar steam generation (ISSG) can alleviate the global freshwater shortage by converting sustainable solar power into thermal energy for desalination. ISSG possesses many advantages such as high photothermal efficiency, robust durability, and environmental friendliness. However, conventional evaporators suffered from huge heat losses in the evaporation process due to the lack of efficient thermal management. Herein, hydrophilic Tencel yarn is applied to fabricate a three-dimensional double-layer fabric evaporator (DLE) with efficient multi-stage thermal management. DLE enables multiple solar absorptions, promotes cold evaporation, and optimizes thermal management. The airflow was utilized after structure engineering for enhanced energy evaporation efficiency. The evaporation rate can reach 2.86 kg·m−2·h−1 under 1 sun (1 kW·m−2), and 6.26 kg·m−2·h−1 at a wind speed of 3 m·s−1. After a long duration of outdoor operation, the average daily evaporation rate remains stable at over 8.9 kg·m−2, and the removal rate of metal ions in seawater reaches 99%. Overall, DLE with efficient and durable three-dimensional multi-stage thermal management exhibits excellent practicality for solar desalination. [ABSTRACT FROM AUTHOR]

Published

2024

7. Unravelling the mechanics of knitted fabrics through hierarchical geometric representation.

Author

Ding, Xiaoxiao, Sanchez, Vanessa, Bertoldi, Katia, and Rycroft, Chris H.

Subjects

*THREE-dimensional textiles, *KNIT goods, *BIOLOGICAL networks, *MECHANICAL models, *KNITTING, *YARN

Abstract

Knitting interloops one-dimensional yarns into three-dimensional fabrics that exhibit behaviour beyond their constitutive materials. How extensibility and anisotropy emerge from the hierarchical organization of yarns into knitted fabrics has long been unresolved. We seek to unravel the mechanical roles of tensile mechanics, assembly and dynamics arising from the yarn level on fabric nonlinearity by developing a yarn-based dynamical model. This physically validated model captures the mechanical response of knitted fabrics, analogous to flexible metamaterials and biological fibre networks due to geometric nonlinearity within such hierarchical systems. Fabric anisotropy originates from observed yarn–yarn rearrangements during alignment dynamics and is topology-dependent. This yarn-based model also provides a design space of knitted fabrics to embed functionalities by varying geometric configuration and material property in instructed procedures compatible to machine manufacturing. Our hierarchical approach to build up a knitted fabric computationally modernizes an ancient craft and represents a first step towards mechanical programmability of knitted fabrics in wide engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

8. all dressed up.

Author

Finch, Ellen

Subjects

PALETTE (Color range), EMBROIDERY, THREE-dimensional textiles

Abstract

This article discusses the use of embroidery in new-season fabrics for home decor. It highlights different fabrics and their unique embroidery techniques, such as Larsen's Wenge fabric that mimics woodcarving techniques and Camengo's Geode fabric with swirling patterns. The article also mentions Mark Alexander's Sandtrace fabric for those who prefer more understated embroidery and Élitis' Menorca fabric that combines beaded flowers and raffia stitches for a modern bohemian style. Additionally, Liberty Fabrics' Botanical Atlas collection and GP & J Baker's Lombok fabric are mentioned as options for using embroidered fabrics as wallcoverings. [Extracted from the article]

Published

2024

9. Bionic design of knitted fabrics for ice and snow sports.

Author

Zhang, Bingjie, Ramírez-Gómez, Álvaro, Wang, Jianping, and Yuan, Luning

Subjects

TEXTILE design, THREE-dimensional textiles, WINTER sports, EXTREME environments, THERMAL insulation

Abstract

The extreme environment of winter sports significantly impacts the performance of athletes, leading to a need for clothing that meets composite functional requirements such as warmth, comfort, and protection to improve competition performance. Knitted fabrics for ice and snow sports with excellent heat and moisture performance were inspired by the water collection and transmission system used by the Moloch horridus. A bionic design model of multi-state fabric morphology was developed by using a topological derivation method and three-dimensional parametric surface modeling technology. The experimental results showed that the four single-sided three-dimensional fabrics have better moisture management characteristics and it is possible to achieve an excellent thermal insulation performance. The textile design application models based on this new design method can provide a feasible solution for developing high-performance textiles for winter sports. [ABSTRACT FROM AUTHOR]

Published

2024

10. Metabole.

Author

Sandilands, Catriona

Subjects

THREE-dimensional textiles, ECOLOGICAL art, SCHOLARSHIPS, SILKWORMS, GENDER transition, POLITICAL ecology

Abstract

The article "Metabole" in Antennae: The Journal of Nature in Visual Culture explores the work of artist and researcher Estraven Lupino-Smith, who delved into the Trans Archives at the University of Victoria to investigate the relationship between trans identities and ecological politics. Through weaving, Lupino-Smith creates dense and textured tapestries that reflect on themes of transition, transformation, and the interconnectedness of human and non-human histories. The weavings highlight the messy and revolutionary nature of trans identities, emphasizing the ongoing process of change and transformation. [Extracted from the article]

Published

2024

11. 3D HOLLOW FABRIC PRODUCTION WITH MODIFIED DOBBY SAMPLE WEAVING MACHINE.

Author

MORGÜL, Elifsu Hazal, BAŞAL, Güldemet, ALTAŞ, Sevda, and GÜLAS, Hüseyin Yavuzer

Subjects

WEAVING, THREE-dimensional textiles, TEXTILES, WEAVING patterns, COMPOSITE materials

Abstract

Copyright of SDU Journal of Engineering Sciences & Design / Mühendislik Bilimleri ve Tasarım Dergisi is the property of Journal of Engineering Sciences & Design and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

12. Discuss on Preparation Method of Composite Sports Equipment Based on Stretchable Nanofiber Fabric.

Author

Zhou, Xiaomin and Wu, Wenjuan

Subjects

*CARBON fiber testing, *THREE-dimensional textiles, *SPECIFIC heat capacity, *STRAINS & stresses (Mechanics), *SPORTING goods, *FIBROUS composites

Abstract

Stretchable nanofiber fabrics refer to fabrics woven with elastic nanofibers, and nanofibers are defined as fibers with a diameter less than 100 nm. For example, nanofibers are implanted on the surface of the fabric to form a stable gas film. The biphobic interface can be used for the purification and filtration of sports equipment, chemical products, medical drugs and other products. The development of sports is increasingly dependent on science and technology, and stretchable nanofibers, as an emerging field of science and technology, are undoubtedly widely used in sports materials. This article first explains the role and background of stretchable nanofiber fabrics in sports equipment, and explains related methods, such as the slurry method for preparing rubber thermally conductive composites in sports equipment, and testing the thermal conductivity and thermal conductivity of composite materials. Diffusion coefficient, density and specific heat capacity; and then explain the polyrhodanine coating method, coating stretchable nano fabric, testing its mechanical properties and thermal conductivity, calculating the agglomeration phenomenon of particles in the rubber, you can get the wrapped PRh- The effect of BNNSs' self-aggregation is suppressed; then the stress and strain of the nano-layer are tested using electrospinning technology, that is, the mechanical properties; finally, the tensile test of carbon fiber three-directional nano-fabric sports composite material is carried out, the tensile model is set, and the test is performed The strain and deformation in the stretching process at 0° and 90°, the load change and tensile elongation at break of the two are analyzed, the tensile attenuation rate in the 0° direction is lower than the attenuation rate in the 90° direction, 0° The tensile elongation at break in the direction of 90° is less than the tensile elongation at break in the direction of 90°, and one of the differences is judged that there is no carbon nanofiber on the parallel load in the 90° direction. The application of the above, taking bicycle tires and golf clubs as examples, combined with the average expected lift and 90° three-dimensional weaving method, the tensile strength direction can be obtained. This nanofiber three-dimensional weaving method has a higher tensile load than the composite material in the 90° direction. The average expected improvement of the ordinary weaving method is 36.1%, and the use of 90° three-dimensional nano fabric materials can improve the performance of sports equipment under this material by 16.9% to 51.8%. [ABSTRACT FROM AUTHOR]

Published

2024

13. Meso-scale damage analysis of three-dimensional textile stitched composite subjected to compression loading.

Author

Safaei, Hossein, Selahi, Ehsan, Faham, Hamid Reza, and Azadi, Mohammad

Subjects

FINITE element method, DAMAGE models, COMPRESSION loads, TEXTILE fibers, THREE-dimensional textiles

Abstract

This article deals with damage simulations of three-dimensional (3D) textile stitched composites under compression loading at meso-scale. The 3D fabric geometry is created by experimental geometry measurements based on textile fiber microscopic images. At first, if a meso-scale of 3D unit-cell of the stitched composite is drawn in Catia software, then the model is imported into Abaqus finite element (FE) software. In addition, a Fortran code is prepared and linked to the Abaqus FE software for computing the stitched composite's mechanical coefficient. Finally, a user-defined subroutine in the finite element implements the damage model to anticipate the stitched composite's damage initiation and growth. The results of FE modeling show good agreement with the experimental results. This research could contribute the investigation of the integrity and damage tolerance of 3D-stitched composites for aerospace structures. [ABSTRACT FROM AUTHOR]

Published

2024

14. Three-dimensional biphase fabric estimation from 2D images by deep learning.

Author

Chou, Daniel, Etcheverry, Matias, and Arson, Chloé

Subjects

*DEEP learning, *THREE-dimensional textiles, *CONVOLUTIONAL neural networks, *STANDARD deviations

Abstract

A pruned VGG19 model subjected to Axial Coronal Sagittal (ACS) convolutions and a custom VGG16 model are benchmarked to predict 3D fabric descriptors from a set of 2D images. The data used for training and testing are extracted from a set of 600 3D biphase microstructures created numerically. Fabric descriptors calculated from the 3D microstructures constitute the ground truth, while the input data are obtained by slicing the 3D microstructures in each direction of space at regular intervals. The computational cost to train the custom ACS-VGG19 model increases linearly with p (the number of images extracted in each direction of space), and increasing p does not improve the performance of the model - or only does so marginally. The best performing ACS-VGG19 model provides a MAPE of 2 to 5% for the means of aggregate size, aspect ratios and solidity, but cannot be used to estimate orientations. The custom VGG16 yields a MAPE of 2% or less for the means of aggregate size, distance to nearest neighbor, aspect ratios and solidity. The MAPE is less than 3% for the mean roundness, and in the range of 5-7% for the aggregate volume fraction and the mean diagonal components of the orientation matrix. Increasing p improves the performance of the custom VGG16 model, but becomes cost ineffective beyond 3 images per direction. For both models, the aggregate volume fraction is predicted with less accuracy than higher order descriptors, which is attributed to the bias given by the loss function towards highly-correlated descriptors. Both models perform better to predict means than standard deviations, which are noisy quantities. The custom VGG16 model performs better than the pruned version of the ACS-VGG19 model, likely because it contains 3 times (p = 1) to 28 times (p = 10) less parameters than the ACS-VGG19 model, allowing better and faster cnvergence, with less data. The custom VGG16 model predicts the second and third invariants of the orientation matrix with a MAPE of 2.8% and 8.9%, respectively, which suggests that the model can predict orientation descriptors regardless of the orientation of the input images. [ABSTRACT FROM AUTHOR]

Published

2024

15. Three-dimensional weaving capability parametric analysis based on vibration characteristics of variable length cantilever beam.

Author

Wang, Peixin, Xue, Debo, He, Lei, Li, Jianhui, and Liu, Xuejie

Subjects

*THREE-dimensional textiles, *HAMILTON'S principle function, *CANTILEVERS, *RUNGE-Kutta formulas, *MAXIMUM principles (Mathematics), *FREE vibration

Abstract

The aim of this study is to parametrically analyze the vibration characteristics of weaving needles during the feeding motion, providing effective references for the selection of parameters in the three-dimensional weaving process. To control the degree of carbon fiber wear during the manufacturing process and maximize its maximum forming height, we have established a systematic dynamic model based on Hamilton's principle. The state equation was solved using the Runge-Kutta method. The influence of different weaving parameters on the weaving needle's free-end vibration response and equilibrium position of was studied. The results indicate that the weaving velocity and height of the cross-section have a significant impact on the vibration amplitude of the free end of the weaving needle and the deflection of the equilibrium position. Moreover, the increase in deflection exhibits a certain inhibitory effect on the amplitude. [ABSTRACT FROM AUTHOR]

Published

2024

16. Simulation of heat transport in textiles inspired by polar bear fur.

Author

Adesiji, Adedire D. and Brown, Keith A.

Subjects

*POLAR bear, *TEXTILE fibers, *THREE-dimensional textiles, *THERMAL insulation, *FINITE element method, *FUR

Abstract

The polar bear and several other Arctic mammals use fur composed of hollow-core fibers to survive in extremely cold environments. Here, we use finite element analysis to elucidate the role that the hollow core plays in regulating thermal transport. Specifically, we establish a three-dimensional model of a textile based on fibers with various core diameters and study transverse heat transport. First, these simulations revealed that textiles based on hollow-core fibers conduct significantly less heat than their solid-core counterparts with fibers with a core-to-fiber diameter ratio of 0.95, reducing thermal transport by 33%. In addition to this decrease in thermal transport, the mass per area of textiles is substantially reduced by making them hollow core. This led us to consider the performance of multi-layer textiles and to find that four-layer hollow-core textiles can exhibit a four-fold decrease in heat flux relative to single-layer solid-core textiles with the same mass per area. Taken together, these simulations show that hollow-core fibers are well suited for thermal insulation applications in which gravimetric thermal insulation is a priority. [ABSTRACT FROM AUTHOR]

Published

2024

17. The propensity for covalent organic frameworks to template polymer entanglement.

Author

Neumann, S. Ephraim, Kwon, Junpyo, Gropp, Cornelius, Le Ma, Giovine, Raynald, Tianqiong Ma, Hanikel, Nikita, Kaiyu Wang, Chen, Tiffany, Shaan Jagani, Ritchie, Robert O., Ting Xu, and Yaghi, Omar M.

Subjects

*CRYSTALLINE polymers, *SPATIAL arrangement, *SURFACE interactions, *THREE-dimensional textiles, *POLYMERS

Abstract

The introduction of molecularly woven three-dimensional (3D) covalent organic framework (COF) crystals into polymers of varying types invokes different forms of contact between filler and polymer. Whereas the combination of woven COFs with amorphous and brittle polymethyl methacrylate results in surface interactions, the use of the liquid-crystalline polymer polyimide induces the formation of polymer-COF junctions. These junctions are generated by the threading of polymer chains through the pores of the nanocrystals, thus allowing for spatial arrangement of polymer strands. This offers a programmable pathway for unthreading polymer strands under stress and leads to the in situ formation of high-aspect-ratio nanofibrils, which dissipate energy during the fracture. Polymer-COF junctions also strengthen the filler-matrix interfaces and lower the percolation thresholds of the composites, enhancing strength, ductility, and toughness of the composites by adding small amounts (~1 weight %) of woven COF nanocrystals. The ability of the polymer strands to closely interact with the woven framework is highlighted as the main parameter to forming these junctions, thus affecting polymer chain penetration and conformation. [ABSTRACT FROM AUTHOR]

Published

2024

18. Three-dimensional orthogonal woven hybrid fabrics in X band frequency region for electromagnetic shielding effectiveness.

Author

Singh, Mukesh Kumar, Saraswat, Gaurav, and Mukhopadhyay, Samrat

Subjects

THREE-dimensional textiles, ELECTROMAGNETIC shielding, POLYPHENYLENE sulfide, COPPER, ELECTROMAGNETIC testing, YARN

Abstract

The three-dimensional fabric structures with metallic yarns and different fibers offer additional opportunities to enhance the electromagnetic shielding potential. This study involves the manufacturing of a Three-Dimensional Orthogonal Woven (3DOW) hybrid conductive fabric to be potentially used in an electromagnetic shielding field. 3DOW fabric consisting of copper filament-based core-sheath hybrid yarn in the weft direction has been manufactured to obtain maximum shielding effect. Hybrid yarns were produced using the DREF-III spinning technique, having copper filament in the core and sheathing by Polyphenylene Sulfide (PPS) staple fibers. The experiment was designed using Box-Behnken method. The orthogonal fabric samples are tested in an electromagnetic frequency region of 8-12 GHz using Free Space Measurement System (FSMS) to estimate absorbance, reflectance, and transmittance. Hybrid yarn parameters such as PPS fiber diameter, copper filament diameter, and yarn linear density considerably affect electromagnetic shielding. 3DOW fabric's electromagnetic shielding effect increase with the diameter of the copper core filament, as does PPS yarn's diameter, showing a promising trend towards shielding. The findings of orthogonal structure can be further extended in other Three-Dimensional structures like multi-layer, angle interlock, draperies, and tops for civilians and soldierly applications. [ABSTRACT FROM AUTHOR]

Published

2024

19. Textile structures in concrete reinforcement.

Author

Barman, Nabo Kumar, Bhattacharya, Someshwar S., and Alagirusamy, Ramasamy

Subjects

YARN, THREE-dimensional textiles, COATED textiles, CONCRETE durability, KNIT goods, NONWOVEN textiles

Abstract

Traditional steel-based reinforcements face corrosion issues that compromise the durability of concrete structures. Large concrete covers are recommended to mitigate corrosion of steel reinforcements, resulting in thicker, heavier structures with increased material consumption and costs, making them less sustainable. Textile reinforced concrete (TRC), with its corrosion resistance, high tensile strength, drapeability, formability, and lightweight nature, offers a sustainable alternative. It necessitates less concrete cover, thereby reducing costs and material consumption, making it suitable for lightweight and durable structural components. Various combinations of textile structures achieved through selective adjustments to fibre, yarn, and fabric geometry present significant potential for developing customized TRC elements. This issue of Textile Progress delves into the environmental impact of construction materials, TRC composition and manufacturing, mechanical testing techniques, and the influence of textile (yarn, braided fabric, woven fabric, knitted fabric, 3-D spacer fabric, nonwoven fabric) structural parameters on TRC behaviour. Additionally, the effects of textile coatings, filler incorporation, and discrete fibre integration on TRC properties are also explored. Overall, textile reinforcement in concrete enhances properties such as tensile strength, ductility, strain hardening behaviour, flexural strength, impact resistance, toughness, multiple cracking behaviour, and reduced crack width and spacing, whilst also bolstering resistance to environmental factors. [ABSTRACT FROM AUTHOR]

Published

2024

20. Low-Velocity Impact and Post-Impact Residual Flexural Properties of Kevlar/EP Three-Dimensional Angle-Interlock Composites.

Author

Shi, Juanjuan, Guo, Yanwen, Huang, Xiaomei, Chen, Hongxia, and Cao, Haijian

Subjects

*POLYPHENYLENETEREPHTHALAMIDE, *FAILURE mode & effects analysis, *THREE-dimensional textiles, *FLEXURAL strength, *YARN, *CASCADE impactors (Meteorological instruments), *DEBONDING

Abstract

In this study, five three-dimensional angle-interlock fabrics with different warp and weft densities were fabricated using 1000D Kevlar filaments. The Kevlar/EP composites were prepared by vacuum-assisted molding techniques. The low-velocity impact property of the composite was tested, focusing on the effects of the warp and weft densities, impact energy, impactor shape, and impactor diameter. The damage area, dent depth, and crack lengths in the warp and weft direction were used to evaluate the impact performance, and the specimens were compared with plain-weave composites with similar areal densities. The dominant failure mode of the conical impactor was fiber fracture, while the dominant failure mode of the hemispherical impactor was fiber–resin debonding. The cylindrical impactor showed only minor resin fragmentation. The residual flexural strength of the composite after impact was tested to provide insights into its mechanical properties. The study findings will provide a theoretical basis for the optimization of the design of impact-resistant structures using such materials and facilitate their engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

21. Partial auxetic behavior of 3D mesh fabric under compression.

Author

Huang, Jing, Zheng, Fei, He, Yu, Fu, Shaoju, and Liu, Yanping

Subjects

POISSON'S ratio, AUTOMOBILE seats, UNIT cell, THREE-dimensional textiles, AUTOMOBILE parts

Abstract

The 3D mesh fabric is a key component of automotive seat ventilation systems as it has good compression resistance and creates channels to provide effective circulating airflow. The dimensional inconsistency of fabric sheets by laser cutting to be integrated into car seats and their unrecoverable dimension changes in subsequent cushioning applications are challenging problems. A typical commercialized 3D mesh fabric was observed to shorten and widen under compression, showing an auxetic behavior in the length–thickness section. This counterintuitive partial auxetic behavior accounts for the dimensional variation. A full-size finite element (FE) model of the fabric was established to simulate the complex fabric deformation based on the precise geometry of a unit cell obtained by X-ray micro-computed tomography (μCT) scanning. The FE simulation reproduced the planar dimension change process of the fabric. The underlying mechanism of partial auxeticity was revealed from the global to local analysis, including fabric global deformation, unit meshes deformation and unit cell geometric structure change. It was shown that buckling of initially post-buckled spacer monofilaments drives in-plane movements of monofilament loops to cause partial auxetic behavior. The partial auxeticity weakens in the compression process due to the gradual intercontact and densification of spacer monofilaments. Different constraints on monofilament loops from adjacent unit cells and multifilament inlays make the deformation uneven in the plane of fabric. It is important to fully analyze the dimensional change, especially the partial auxetic deformation, of the 3D mesh fabric under compression for its practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

22. Finite element analysis on global and local deformation behavior of 3D spacer fabric.

Author

Zhang, Yuan, Hu, Hong, Kyosev, Yordan, and Liu, Yanping

Subjects

SANDWICH construction (Materials), DEFORMATIONS (Mechanics), THREE-dimensional textiles, CUSHIONING materials, FINITE element method, DEFORMATION of surfaces, TORSION

Abstract

Three-dimensional spacer fabric is a type of one-piece sandwich structure consisting of two outer layers and vertical and inclined spacer monofilaments. It behaves like a cushioning material, having linear, plateau, and densification stages under compression. This article elucidates the compression mechanism of a typical spacer fabric in terms of global deformation, local deformation, and internal contact behavior of spacer monofilaments through finite element simulation. While the linear stage is post-buckling of spacer monofilaments with tight constraints, the plateau stage is a combination of post-buckling, torsion, rotation, and contact of spacer monofilaments. The densification stage is attributed to the contact between spacer monofilaments and outer layers, which decreases the effective length to bear the load and enhances the constraints on the spacer monofilaments. The vertical spacer monofilaments with almost triple the normal strains of the inclined ones contribute more to compression resistance. [ABSTRACT FROM AUTHOR]

Published

2023

23. 3D 打印纬编单面不均匀提花面料.

Author

程燕婷, 孟家光, 薛涛, 支超, and 王彦杰

Subjects

POLYLACTIC acid, THREE-dimensional printing, THREE-dimensional textiles

Abstract

Copyright of Wool Textile Journal is the property of National Wool Textile Science & Technology Information Center and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

24. A kinetic grid for fabric draping simulation.

Author

Tao, Chen, Yu, Wei, Cao, Jingzhe, and Hong, Xinghua

Subjects

THREE-dimensional textiles, DRAPERIES, TEXTILES, MODEL airplanes, RIGID bodies

Abstract

In allusion to the hot issue of fabric simulation, this paper proposes a kinetic grid for reproducing the drape profile of fabric in three-dimensional space. In our model, the interaction inside fabric is built up through a constraint factor as well as an attenuation factor, and the contact between the flexible body of the fabric and the rigid plane is emulated with a touch-counteract mechanism. The forces on the particles in the grid, which are calculated with grid deformation, are then used to generate the additional displacement of the grid. Evolution of the grid is led by step-by-step iteration so that the draping kinetics of the virtual fabric can be achieved. When the draping process meets its steady state, the drape coefficient is worked out through identifying and quantifying the projection area of the grid. The unevenness of the ripples along the drape surface is characterized and manifested by emulating the mechanical anisotropy of the fabric through differentiated constraint factors. The evolution algorithm is improved and an optimized version that reduces calculation error using the third-order Taylor theorem is presented, by which a smoother curved surface for the drape can be produced. The convergence of the grid under different fineness values is explored to reveal the capacity of the model, and a reasonable grid scale has been identified. The computed drape is then compared to a real drape featuring different strengths in the warp and weft, and adjusted to meet the target drape coefficient, as well as drape unevenness considering the anisotropy index. The result shows they are properly matched. The virtual drape is also tested in additional scenes including square support with sharp corners, one-way overhanging and mixed. It has turned out to be a simple, rapid and precise model for fabric drape simulation and assessment. [ABSTRACT FROM AUTHOR]

Published

2023

25. Design and characterization of multi-functional ternary composites with a hierarchically porous and filled-microperforated plate structure.

Author

Nan, Jingjing, Zhou, Qiang, Song, Qingwen, Meng, Jiaguang, Dong, Zijing, Yu, Lingjie, and Zhi, Chao

Subjects

ABSORPTION of sound, INSULATING materials, THERMAL insulation, FIREPROOFING, THREE-dimensional textiles

Abstract

To effectively overcome the shortcomings of common polyurethane (PU) insulation materials in terms of flame retardancy, mechanical properties, and sound absorption, a new multi-functional insulation material needs to be developed. Here, simple materials such as PU and silica aerogel (SA) combined with a special three-dimensional spacer fabric were used to design an innovative SA/PU/spacer fabric (SPS) ternary composite. It integrates a "hierarchically porous" and "filled-microperforated plate" structure. The superior structure design endows the new type of composite with a remarkable performance while maintaining low density (0.198 g/cm3). Specifically, the SPS composite was difficult to ignite by alcohol lamps compared with PU and SA/PU, and its thermal conductivity and compression modulus can reach 0.0392 W/(m·k) and 1.5 MPa, respectively. Moreover, the average absorption coefficient of the SPS composite (7.5 mm thickness) is 0.62, and its noise reduction coefficient per unit thickness (0.37) exceeds most reported sound absorption materials. From these results, the SPS composite provides a convenient and low-cost method to improve the overall performance of traditional thermal insulation material, which is of great significance in the fields of construction and transportation. [ABSTRACT FROM AUTHOR]

Published

2023

26. Prediction of optimum alkaline hydrolysis conditions for imparting superhydrophobicity to large-area fabrics using three-dimensional modeling.

Author

Cho, Yoonkyung and Kim, Sungmin

Subjects

ALKALINE hydrolysis, YARN, THREE-dimensional textiles, WEAVING patterns, CONTACT angle, NANOFLUIDICS, THREE-dimensional modeling

Abstract

This study proposes a fabric-specific alkaline hydrolysis method to impart stable water repellency to large-area polyester fabrics, regardless of yarn type or weave pattern. The geometries of 120 virtual fabrics with varying yarn properties, weave patterns, and weave densities are modeled, and their surface-etching efficiency and superhydrophobicity are predicted. While the alkaline hydrolysis-derived nano-structuring efficiencies of fabrics are predicted based on the Kallay and Grancaric model (1990) with changes to reflect the fiber volume fraction F as a major variable for fabric structures. For predicting superhydrophobicity, the fabric meso-structure contact angle is calculated based on the Michielsen and Lee model (2007); the fixed yarn distance used in the original model is replaced by the simulated inter-yarn porosity P to exclude error caused by structural variability. The final virtual fabric contact angle is predicted reflecting the effect of nano-roughness, which is validated by comparing the predicted contact angle with a physical sample having identical geometries. The contact angle of any fabric can be predicted using structural simulation, given the alkaline treatment conditions are adjusted according to the unique geometry of each fabric to express superhydrophobicity. Moreover, even for samples with low predictive contact angles, superhydrophobicity can be achieved by maximizing the effect of the nanostructure through strong alkaline treatment. An ISO 5 water repellency is achieved for all large-area polyester fabrics. [ABSTRACT FROM AUTHOR]

Published

2023

27. Experimental study of low-velocity impact behavior and damage characteristics of flat-knitted spacer fabrics reinforced composites.

Author

Tan, Jiangtao, Jiang, Gaoming, Gao, Zhe, Zhou, Mengmeng, and Ma, Pibo

Subjects

YARN, ULTRAHIGH molecular weight polyethylene, THREE-dimensional textiles, IMPACT testing, COMPOSITE plates

Abstract

Flat-knitted spacer fabrics are three-dimensional fabrics with good formability and impact resistance, which can be rapidly produced complicated shape preforms. In this work, low-velocity impact behavior and damage characteristics of flat-knitted spacer fabrics reinforced composites were studied and the mechanism of the effects of spacer yarn structure on the impact properties of the composites were explored. Flat-knitted spacer fabrics with three spacer structures were produced using ultrahigh molecular weight polyethylene (UHMWPE) filaments, and composite plates were prepared by vacuum-assisted resin infusion. Low-velocity impact tests were carried out using a drop-weight impact testing machine equipped with a hemispherical impactor. It was revealed that the impact process of the flat-knitted spacer fabrics reinforced composites could be divided into three areas. The effect of initial impact energy on the impact properties of the sample was mainly reflected in the damage speed and initial damage threshold in the first areas. With the increase of spacer yarn span, the damage tolerance, stiffness, and impact resistance of the composite were also increased. Besides, the main damage mechanism of flat-knitted spacer fabric reinforced composites was plastic deformation, matrix fracture, fiber-matrix debonding, and tow splitting. [ABSTRACT FROM AUTHOR]

Published

2023

28. 包覆纱织物的制备及防刺性能研究.

Author

金礼月, 钟林, 曹海建, 孙茂军, and 黄晓梅

Subjects

YARN, ULTRAHIGH molecular weight polyethylene, THREE-dimensional textiles, RAW materials, CUTTING force, FIBERS

Abstract

Copyright of Cotton Textile Technology is the property of Cotton Textile Technology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

29. rich pickings.

Author

Finch, Ellen

Subjects

THREE-dimensional textiles, INTERIOR decoration, UPHOLSTERY, WEAVING patterns, WEAVING, TEXTILES

Abstract

The article discusses the fabric forecast for the new season, focusing on luxurious jacquards and weaves that emphasize texture. It highlights various trends, such as the growing popularity of patchwork designs, the use of layered woven details in lighter-weight curtains, and the modern forms of jacquard in contemporary upholstery. The article also mentions the use of three-dimensional fabrics, simple patterns brought to life through jacquard, and tapestry-style weaves with geometric motifs. The text provides examples of fabrics from different brands and suggests ways to incorporate these trends into interior design. [Extracted from the article]

Published

2024

30. Finnish Woven Waves.

Author

Larson, Kate

Subjects

WEAVERS, THREE-dimensional textiles, TEXTURED woven textiles, TEXTILE fibers

Abstract

The article presents an interview with Finnish weaver Hannele Köngäs, exploring her use of high-twist yarns in creating three-dimensional, dynamic textiles. Topics discussed include inspiration from antique textiles, the influence of twist direction and wool type on fabric effects, and the use of high-twist yarns in combination with specific weaving patterns to achieve unique textures.

Published

2024

31. The influence of high molecular weight polyethylene and basalt content on the mechanical risks of protective three-dimensional weft-knitted fabrics designed to wear next to skin.

Author

Krauledaitė, Julija, Ancutienė, Kristina, Krauledas, Sigitas, Urbelis, Virginijus, and Sacevičienė, Virginija

Subjects

THREE-dimensional textiles, DEGRADATION of textiles, MOLECULAR weights, BASALT, IMPACT (Mechanics), POLYETHYLENE

Abstract

This study examines the resistance of three-dimensional (3D) weft-knitted fabrics to mechanical risks to determine the influence of varying percentage contents of high molecular weight polyethylene and basalt on cut, puncture, abrasion, and tear resistance. The three-dimensional weft-knitted fabrics are designed by separating functional layers: the outer (protective) layer contains varying percentage contents of high molecular weight polyethylene and basalt; the inner layer (suitable for contact with the skin) contains polyester; both layers are connected using polyamide. The strength properties of knits in response to mechanical impact were evaluated by performing cut, puncture, abrasion, and tear resistance tests. Basalt was found to improve the cut resistance of knits significantly, even with its content as low as 5% in the outer layer. The knit with the highest high molecular weight polyethylene content in the outer layer demonstrated the best puncture and tear resistance. No correlation was established between the varying percentage contents of high molecular weight polyethylene and basalt and the maximum number of abrasion cycles, as the three-dimensional weft-knitted fabrics showed no noticeable wear. The test results show that the structure of three-dimensional weft-knitted fabric with the outer layer designed to withstand mechanical impact and the inner layer suitable for direct contact with the skin protects against a wide range of mechanical impacts. This applies even when varying percentage contents of high molecular weight polyethylene and basalt are used only in the outer layer. [ABSTRACT FROM AUTHOR]

Published

2023

32. Numerical simulation and image analysis of thermal behavior of spacer fabric.

Author

Dehghan, Neda, Payvandy, Pedram, and Talebi, Shahram

Subjects

*IMAGE analysis, *BEHAVIORAL assessment, *THERMAL analysis, *COMPUTER simulation, *THREE-dimensional textiles, *DIGITAL image processing, *TECHNICAL textiles

Abstract

Due to spacer fabrics applications in industries, the importance of understanding their thermal properties is considered a reason for developing fast and accurate methods such as numerical simulation and image processing to determine such properties. The aim of this study was to propose a numerical simulation to determine the spacer fabric temperature distribution. The exact temperature in all different parts of the fabric and the relationship between the heat transfer and the fabric parameters were determined using FLUENT software. The performance of the simulation method was evaluated by thermal image processing, a non-contact method with high accuracy in determining the thermal properties. The results showed that the heat transfer depends on the fabric porosity, thickness and density. The samples with a high density have a more uniform temperature distribution. As the thickness increases, the thermal equilibrium occurs gradually over a longer period of time. The porosity of the three-dimensional fabric is affected by the knit pattern, density and arrangement of monofilaments. As the porosity increases, the temperature rises quickly in the samples with the same thickness. The results of the numerical simulation were compared with the thermal image processing, and a good agreement between them is found. The results showed that the simulation method is able to calculate the temperature and its distribution in all different parts of the fabric, so it is proposed as an accurate method for calculating the temperature distribution in the textiles. [ABSTRACT FROM AUTHOR]

Published

2023

33. Mosquito Blood Feeding Prevention Using an Extra-Low DC Voltage Charged Cloth.

Author

Luan, Kun, McCord, Marian G., West, Andre J., Cave, Grayson, Travanty, Nicholas V., Apperson, Charles S., and Roe, R. Michael

Subjects

*MOSQUITOES, *MOSQUITO control, *AEDES aegypti, *THREE-dimensional textiles, *ARTIFICIAL membranes, *VOLTAGE

Abstract

Simple Summary: An extra-low, DC (direct current) voltage field applied to a textile was used to prevent mosquito blood feeding. A novel 3-D textile was developed based on the mosquito head structure that when charged with 15 volts was 100% effective in preventing mosquito blood feeding across an artificial membrane. Mosquito vector-borne diseases such as malaria and dengue pose a major threat to human health. Personal protection from mosquito blood feeding is mostly by treating clothing with insecticides and the use of repellents on clothing and skin. Here, we developed a low-voltage, mosquito-resistant cloth (MRC) that blocked all blood feeding across the textile and was flexible and breathable. The design was based on mosquito head and proboscis morphometrics, the development of a novel 3-D textile with the outer conductive layers insulated from each other with an inner, non-conductive woven mesh, and the use of a DC (direct current; extra-low-voltage) resistor-capacitor. Blockage of blood feeding was measured using host-seeking Aedes aegypti adult female mosquitoes and whether they could blood feed across the MRC and an artificial membrane. Mosquito blood feeding decreased as voltage increased from 0 to 15 volts. Blood feeding inhibition was 97.8% at 10 volts and 100% inhibition at 15 volts, demonstrating proof of concept. Current flow is minimal since conductance only occurs when the mosquito proboscis simultaneously touches the outside layers of the MRC and is then quickly repelled. Our results demonstrated for the first time the use of a biomimetic, mosquito-repelling technology to prevent blood feeding using extra-low energy consumption. [ABSTRACT FROM AUTHOR]

Published

2023

34. Classification of doubly periodic untwisted (p,q)-weaves by their crossing number and matrices.

Author

Fukuda, Mizuki, Kotani, Motoko, and Mahmoudi, Sonia

Subjects

*PLANAR graphs, *GRAPH connectivity, *THREE-dimensional textiles, *MATRICES (Mathematics), *WEAVING patterns, *CLASSIFICATION

Abstract

A weave is the lift to the thickened Euclidean plane of a particular type of quadrivalent planar connected graph with an over or under crossing information to each vertex and such that the lifted components are non-intersecting simple open curves. In this paper, we introduce a formal topological definition of weaves as three-dimensional entangled structures and characterize the equivalence classes of doubly periodic untwisted (p , q) -weaves by introducing a new invariant, called crossing matrix. Finally, we suggest a combinatorial approach to classify this specific class of weaves by their crossing number. [ABSTRACT FROM AUTHOR]

Published

2023

35. Three-dimensional porous structure on cotton fabric through the breath figure method with functions of self-cleaning and oil/water separation.

Author

Kong, Que, Ren, Xuehong, and Li, Zhiguang

Subjects

COTTON textiles, THREE-dimensional textiles, FIREPROOFING agents, METHACRYLATES

Abstract

Cotton fabric can be modified to obtain additional functionality such as hydrophobic property, antibacterial property and flame retardant property. The traditional coating method often has adverse influence on the strength and permeability of cotton fabric. Polyhedral oligomeric silsesquioxanes-(poly(trifluoroethyl methacrylate)8) copolymer was modified on the surface of cotton fabric with three-dimensional (3D) ordered porous structure via the breath figure. A key factor of solution concentration was studied to regulate the formation of 3D porous structure. The morphology and chemical composition of the modified fabric were characterized. The hydrophobic and the dynamic hydrophobic property of the modified fabrics with different copolymer concentrations were studied. The self-cleaning properties, oil/water separation, rubbing durability and bacterial adsorption on the modified fabrics were examined. It was showed that the modified fabric had self-cleaning, oil/water separation capabilities, rubbing durability and an effective inhibitory effect on the biofilm formation of bacteria. In addition, compared to the unmodified fabric, the comfortable capability and breaking strength of the modified fabric were investigated. [ABSTRACT FROM AUTHOR]

Published

2023

36. Geometric Analysis of Three-Dimensional Woven Fabric with in-Plane Auxetic Behavior.

Author

Zeeshan, Muhammad, Hu, Hong, and Etemadi, Ehsan

Subjects

*THREE-dimensional textiles, *POISSON'S ratio, *GEOMETRIC analysis, *HEXAGONS, *GEOMETRIC modeling, *UNIT cell

Abstract

Auxetic textiles are emerging as an enticing option for many advanced applications due to their unique deformation behavior under tensile loading. This study reports the geometrical analysis of three-dimensional (3D) auxetic woven structures based on semi-empirical equations. The 3D woven fabric was developed with a special geometrical arrangement of warp (multi-filament polyester), binding (polyester-wrapped polyurethane), and weft yarns (polyester-wrapped polyurethane) to achieve an auxetic effect. The auxetic geometry, the unit cell resembling a re-entrant hexagon, was modeled at the micro-level in terms of the yarn's parameters. The geometrical model was used to establish a relationship between the Poisson's ratio (PR) and the tensile strain when it was stretched along the warp direction. For validation of the model, the experimental results of the developed woven fabrics were correlated with the calculated results from the geometrical analysis. It was found that the calculated results were in good agreement with the experimental results. After experimental validation, the model was used to calculate and discuss critical parameters that affect the auxetic behavior of the structure. Thus, geometrical analysis is believed to be helpful in predicting the auxetic behavior of 3D woven fabrics with different structural parameters. [ABSTRACT FROM AUTHOR]

Published

2023

37. Quantitative analysis of monofilament architecture in three-dimensional mesh fabric using micro X-ray computed tomography.

Author

Liu, Xia, Zheng, Fei, and Liu, Yanping

Subjects

COMPUTED tomography, THREE-dimensional textiles, QUANTITATIVE research, UNIT cell, X-rays

Abstract

Three-dimensional mesh fabric has been successfully installed in ventilated car seats due to its excellent cushioning and ventilating properties originating from a sandwich monofilament architecture. In this paper, a detailed structural analysis is presented of a 10.3 mm thick three-dimensional mesh fabric to better understand the structural features and mechanical behavior. A continuous monofilament architecture was reconstructed by using a filament centerline tracing technique and micro X-ray computed tomography data. The curvature, torsion, and length of a unit cell extracted from the monofilament architecture were calculated. Inflection points from the curvature and torsion curves were used to divide the continuous monofilament architecture into separate monofilament loops and spacer monofilaments. The monofilament loops are found to have similar maximum curvatures at their intermediate points between 1.5 and 1.8 mm−1, but the spacer monofilaments have discrepant maximum curvatures close to the ends between 0.3 and 0.75 mm−1. The monofilament loops are sinusoidally arranged with a sinusoidal torsion distribution at their ends ranging from 0.2 and 0.9 mm−1 due to the stretching and heat setting process. Spacer monofilament torsions vary nonlinearly from negative to positive and the maximum torsions are between 0.45 and 0.9 mm−1. The monofilament loops have a length of 3.07–3.90 mm, while the spacer monofilaments have a length of 10.94–12.54 mm. Spacer monofilaments within the unit cell differ in curvature, torsion, and length, so their contributions to fabric compression resistance should be different. [ABSTRACT FROM AUTHOR]

Published

2023

38. An experimental study on the vibration behavior and the physical properties of weft-knitted spacer fabrics manufactured using flat knitting technology.

Author

Chen, Fuxing, Wang, Ji, Gao, Shouwu, Ning, Xin, Yan, Pengxiang, and Tian, Mingwei

Subjects

SURGICAL gloves, TEXTILE technology, THREE-dimensional textiles, URETHANE foam, SPONGE (Material), FREQUENCIES of oscillating systems, KNITTING, VIBRATION isolation

Abstract

Weft-knitted spacer fabrics, a kind of three-dimensional fabric structure, are potential substitutes for typical rubber sponges and polyurethane foams for the protection of human body from exposure to vibrations. To explore the capability and the designability of weft-knitted spacer fabrics as the functional material of personal protective equipment against vibration, such as anti-vibration gloves and car cushions, the vibration behavior and physical properties of weft-knitted spacer fabrics manufactured using flat knitting technology were studied. In the first part of the article, the vibration behavior of top-loaded weft-knitted spacer fabric under harmonic base excitation was analyzed. The effects of monofilament diameter, linking distance and excitation acceleration level on the transmissibility curve of the mass-spacer fabric were evaluated. It was shown that to broaden the frequency range for vibration isolation, spacer fabrics with smaller monofilament diameter and longer linking distance were preferred. In the second part of the article, the effects of monofilament type, monofilament diameter, and spacer structure on the physical properties of spacer fabric including fabric shrinkage coefficient, fabric thickness, fabric stitch densities, and fabric areal mass were analyzed. It was found that fabric thickness was increased by employing spacer structures with longer linking distance and lower filling density of spacer monofilament. In addition, in order to obtain an optimized high fabric thickness, nylon monofilament was preferred to polyester monofilament. On the other hand, monofilament diameter has a significant influence on stitch densities and fabric areal mass. Larger monofilament diameter resulted in lower stitch densities and heavier areal mass for spacer fabric. [ABSTRACT FROM AUTHOR]

Published

2023

39. Sound absorption property of hierarchical three-dimensional flat-knitted spacer fabric with microfiber.

Author

Wang, Kai, Chen, Chaoyu, and Ma, Pibo

Subjects

ABSORPTION of sound, THREE-dimensional textiles, NOISE control, ABSORPTION coefficients, POROSITY, MICROFIBERS

Abstract

The harm of sound pollution to human health is nonnegligible. To construct a good sound absorbent fabric, we proposed a combination of flat-knitting and microfibers, which is a simple and effective way to prepare a hierarchical three-dimensional spacer fabric with macroscopic and microscopic pore structure. The effects of spacer layer structure, surface yarn thickness and sea islands composite filaments split durations on sound absorption property were investigated. The sound absorption property was evaluated by the sound absorption coefficient and noise reduction rate. The results show that the sound absorption property of the spacer fabric is improved by splitting, especially under the middle frequency range (1000–3000 Hz). What is more, the noise reduction rate of our layered hierarchical spacer fabric increased by 4.1% with the thickness decreased by 21.1% compared with a recently reported hierarchical porous sound absorbent fabric. [ABSTRACT FROM AUTHOR]

Published

2023

40. 基于纺织结构的摩擦纳米发电机研究进展.

Author

李兆彤 and 吕丽华

Subjects

THREE-dimensional textiles, MICROFABRICATION, TACTILE sensors, ENERGY harvesting, TEXTILES

Abstract

Copyright of Cotton Textile Technology is the property of Cotton Textile Technology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

41. Design-manufacturing-performance of electromagnetic absorbing/load bearing three-dimensional honeycomb woven composites.

Author

Yao, Wenbin, Zhou, Xinghai, Gao, Yuan, Qian, Yongfang, and Lyu, Lihua

Subjects

*TRANSFER molding, *MULTIWALLED carbon nanotubes, *WOVEN composites, *IRON powder, *THREE-dimensional textiles

Abstract

• A hexagonal cross-section three-dimensional honeycomb woven composite was successfully fabricated by VARTM. • The EM absorption mechanism was revealed by experiments and CST simulations. • The mechanism of bending damage was analysed by the load-displacement curves and the details of the damage. Structural electromagnetic wave (EMW) absorbing composites play a critical role in both civilian and military applications. However, traditional sandwich honeycomb EMW absorbing composites have poor out-of-plane mechanical properties and load-bearing performance.This study introduces the development of a three-dimensional honeycomb woven composite (3DHWC) that integrates EMW absorption and load-bearing capabilities. A weaving loom was used to fabricate a three-dimensional honeycomb woven structure fabric (3DHSWF) with varying structural parameters. Subsequently, the composites were formed using carbon black (CB), multi-walled carbon nanotubes (MWCNTs), and carbonyl iron powder (CIP) as hybrid absorbers, epoxy resin as the matrix, combined with the vacuum-assisted resin transfer molding (VARTM) process. Testing confirmed the material's excellent EMW absorption and mechanical properties, achieving a maximum reflection loss (RL) of −30.9 dB and an adequate EMW absorption bandwidth (EAB) of 14.58 GHz. The maximum bending load reached 5799.1 N, with no delamination observed in the samples. This material demonstrates outstanding EMW absorption performance and exhibits superior load-bearing capacity while maintaining structural integrity. Our research provides valuable insights into the design of honeycomb EMW absorbing composites, offering significant advancements in EMW absorption efficiency and bending mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2025

42. Development of three dimensional (3D) woven flax/PLA composites with high mechanical and thermal properties using braided yarns.

Author

Islam, Md Azizul, Islam, Md Mazharul, Yang, Chunbing, Wodag, Awoke Fenta, Wang, Ruijie, Chen, Wei, Zhou, Bangze, Gao, Shuo, and Xu, Fujun

Subjects

*WOVEN composites, *GLASS transition temperature, *THREE-dimensional textiles, *BRAIDED structures, *FOURIER transform infrared spectroscopy, *FIBROUS composites, *POLYLACTIC acid

Abstract

Natural fiber-reinforced polylactic acid (PLA) composites possess renewability, good mechanical properties, and biodegradability. To enhance the mechanical properties of natural fiber-reinforced composites, the flax/PLA braided yarns were woven into three-dimensional orthogonal fabrics with an integrated structure. After the fabrics was hot-pressed, three-dimensional flax/PLA composites with the flax/PLA mass ratios of 50/50 and 25/75 were formed. The results showed that the 50/50 ratio exhibited the higher tensile strength (70.20 MPa) and flexural strength (172.99 MPa), respectively. Thermal analysis indicated its enhanced thermal stability, with the main degradation regions at 354.3°C and 394.7°C. In addition, FTIR spectroscopy showed that the flax/PLA composites exhibited a glass transition temperature of 83.88°C and a melting temperature of 172.89°C. Compared to recent studies, the newly developed three-dimensional orthogonal flax/PLA composites demonstrated superior performance, indicating their potential applications in the field of biodegradable composites, particularly in high-load-bearing applications. • 3D woven flax /PLA composites with higher mechanical properties were developed using braided yarns. • Tensile and flexural properties were studied. • Increasing flax mass ratio results higher mechanical properties. • The mechanical strengths were improved compared to the related reported findings. [ABSTRACT FROM AUTHOR]

Published

2024

43. Mechanism of pre-tension on the impact response of plain weave fabric: Experimental and numerical investigation.

Author

Chen, Cong, Long, Shuchang, Wang, Heran, and Yao, Xiaohu

Subjects

*SHEAR waves, *FINITE element method, *THREE-dimensional textiles, *IMPACT testing, *IMPACT response

Abstract

• A novel biaxial pre-tension fixture was developed, and bullet impact test of the fabric in pre-tensile state was realized using an air gun. • The displacement-time history of each point on fabric in three-dimensional space was characterized through 3-D DIC technology. • The effect of pre-tension on transverse wave propagation is studied. • Finite element model established by the truss element verifies the experimental conclusion. • The wave transmission process in yarns at a mesoscopic level was analyzed. The fabrics made of high strength and toughness fibers are increasingly used in the structural and individual protection. The research on energy dissipation mechanism and the improvement methods for improving energy dissipation of the fabric under impact, as well as the change of ballistic limit velocity under pre-stress, is relatively mature. However, the transmission mode and velocity of transverse wave in the fabric, as well as the method of accurate finite element simulation is still lacking. In this paper, the transverse impact response of ultra high molecular weight polyethylene (UHMWPE) fabric subjected to fragment impact is studied experimentally and numerically. A novel biaxial pre-tension fixture was developed, and fragment impact test of the fabric in pre-tension state was realized using a gas gun. The displacement-time history of each point on the fabric in three-dimensional space was characterized through 3-D DIC technology, and the process of transverse wave transmission on the fabric after fragment impact was obtained. The calculated results of the finite element model established by truss element agrees reasonably well with the experimental results. The experimental and numerical results indicate that the impact velocity of fragment affects the velocity of transverse wave in the fabric, but does not change its transmission mode. With the increase of pre-tension amount, the propagation mode changes from a cross shape to a rhombic shape and finally to a circular shape, and the wave velocity increases greatly. The wave transmission process in yarns at a mesoscopic level was analyzed through finite element simulation, and the transmission path was determined. It was found that pre-tension accelerated the wave velocity on the stepwise path, causing the transverse wave to reach a farther position in the diagonal direction of the fabric, resulting in different modes of wave transmission. The research content may provide more ways for the application of fabrics in protection. [ABSTRACT FROM AUTHOR]

Published

2024

44. The initial fabric of undisturbed and reconstituted fluvial sand.

Author

Quinteros, V. Santiago and Carraro, J. Antonio H.

Subjects

*BIOMASS liquefaction, *SAND, *THREE-dimensional textiles, *PARTICLE size distribution, *IMAGE analysis, *SLURRY

Abstract

High-quality undisturbed samples of fluvial sand were obtained from the field using the ground freezing technique. In the laboratory, the in situ void ratio of these high-quality undisturbed frozen samples was replicated using four different reconstitution methods: dry deposition, moist tamping, water sedimentation (by spooning) and slurry deposition. The initial fabric of the specimens was evaluated using X-ray micro-computed tomography and advanced image analysis. Initial fabric features were assessed in terms of the particle orientation, anisotropy, void ratio distribution and particle sizes within the specimens. Fabric analysis results suggest that none of the laboratory reconstitution techniques used captures the true three-dimensional initial fabric of undisturbed fluvial sand. However, the slurry deposition method managed to reproduce the inherent particle orientation, anisotropy and the variations of void ratio and particle sizes of the undisturbed fluvial sand. This observation explains why previous rigorous studies on the macro-mechanical behaviour of sands deposited under water have systematically demonstrated that slurry deposition is the most suitable method to reconstitute in the laboratory natural sands deposited under water. This has major implications for geotechnical testing and analyses of liquefaction of sands deposited under water such as fluvial, offshore and tailings sands. [ABSTRACT FROM AUTHOR]

Published

2023

45. Thermal Response in Two Models of Socks with Different 3-D Weave Separations.

Author

Sánchez-Rodríguez, Raquel, Gómez-Martín, Beatriz, Escamilla-Martínez, Elena, Morán-Cortés, Juan Francisco, and Martínez-Nova, Alfonso

Subjects

THREE-dimensional textiles, INFRARED cameras, SOCKS, ARTIFICIAL feet, COOLDOWN

Abstract

Socks with the same three-dimensional plantar design but with different compositions in the separation of their weaves could have different thermoregulatory effects. The objective of this study was therefore to evaluate the temperatures on the sole of the foot after a 10-km run using two models of socks with different weave separations. In a sample of 20 individuals (14 men and 6 women), plantar temperatures were analyzed using a Flir E60bx® (Flir Systems) thermographic camera before and after a run of 10 km wearing two models of socks that had different separations between the fabric weaves (5 mm versus 3 mm). After the post-exercise thermographic analysis, the participants responded to a Likert-type survey to evaluate the physiological characteristics of the two models of socks. There was a significant increase of temperature (+4 °C, p < 0.001) after the 10-km run with both models of sock. However, the temperature under the 1st metatarsal head was higher with the AWC 2.1 model than with the AWC 1 (33.6 ± 2.0 °C vs. 33.2 ± 2.1 °C, p = 0.014). No significant differences were found in the scores on the physiological characteristics comfort survey (p > 0.05 in all cases). The two models presented similar thermoregulatory effects on the soles of the feet, although the model with the narrowest weave separation generated greater temperatures (+0.4 °C) under the first metatarsal head. [ABSTRACT FROM AUTHOR]

Published

2023

46. Three-dimensional narrow woven fabric with in-plane auxetic behavior.

Author

Zeeshan, Muhammad, Hu, Hong, and Zulifqar, Adeel

Subjects

YARN, AUXETIC materials, POISSON'S ratio, TEXTILES, TENSILE tests, THREE-dimensional textiles, HEXAGONS

Abstract

Different auxetic structures and auxetic phenomena are continuously explored by researchers in the field of textiles with enhanced properties for broader application areas. However, developing three-dimensional (3D) auxetic structures by using weaving technology is a real challenge compared to knitting and non-weaving techniques. This research work reports a novel approach to develop 3D woven structures with in-plane auxetic behavior. A conventional 3D multilayer orthogonal through-the-thickness structure was converted into a 3D auxetic woven structure. The structure was designed with three different yarn components to incorporate auxetic geometry. One type of yarn was used in the warp direction, while the other two-yarn systems, comprised of fine elastic yarn and coarse binding yarn, were used in the weft direction. The auxetic geometry achieved resembles the reentrant hexagon by the unusual arrangement of warp yarns. For an in-depth study of the structure, nine fabric samples were fabricated by using a conventional semi-automatic weaving machine with four different influencing parameters. The developed samples were then tested on a tensile testing machine to evaluate their mechanical and auxetic behavior. The results show that the 3D fabrics have a negative Poisson's ratio (NPR) even at higher tensile strain and that the appropriate binding to the warp yarn diameter can produce a higher NPR. In addition, the repeat size of the elastic weft yarn, bending stiffness of the binding yarn, and stretch percentage of the elastic weft yarn can highly affect the NPR of the fabric. Furthermore, among all the 3D woven fabrics developed with different structural parameters, the maximum NPR achieved was –1.61. [ABSTRACT FROM AUTHOR]

Published

2022

47. Investigation of the influence of high molecular weight polyethylene and basalt content used in three-dimensional weft-knitted fabrics on the mechanical risks.

Author

Krauledaitė, Julija, Ancutienė, Kristina, Krauledas, Sigitas, Urbelis, Virginijus, and Sacevičienė, Virginija

Subjects

THREE-dimensional textiles, MOLECULAR weights, BASALT, MECHANICAL loads, POLYETHYLENE, CIRCULAR RNA

Abstract

This study investigates the resistance of three-dimensional (3D) weft-knitted fabrics to mechanical risks in order to determine the impact of the percentage content of raw materials in the knits on mechanical loads. For this purpose, 3D weft-knitted fabrics, consisting of a front side, binding, and back side layers, were designed and produced on an E20 circular weft-knitting machine using organic multifilament yarns (high molecular weight polyethylene, HMWPE) and inorganic multifilament (basalt, BS) yarns for the front and back side layers and conventional polyamide yarns for the binding layer. The cut, puncture, abrasion, and tear resistance tests were performed to assess the resistance of 3D weft-knitted fabrics to mechanical risks. According to the testing results, basalt in the structure of 3D weft-knitted fabrics significantly increases the cut resistance, even in cases of a small basalt content in the knit. The puncture, abrasion, and tear resistance testing results showed that the highest HMWPE percentage content in the knitted structure provided the highest resistance to these risks, while increasing the basalt content in the knit did not improve the resistance testing results. Based on the testing results and the assessment of the protection levels provided by the knitted fabrics, the conclusion can be made that the use of HMWPE multifilament yarns and basalt multifilament yarns in the structure of 3D weft-knitted fabrics contributes to the achievement of the highest levels of performance. All the designed 3D weft-knitted fabrics provide complex protection against different mechanical risks (cut, puncture, abrasion, tear). The tests performed may be useful for further development of knitted fabrics designed to provide protection against mechanical risks. [ABSTRACT FROM AUTHOR]

Published

2022

48. Effects of impactors' shape on three-dimensional woven fabric composites at low-velocity impacts.

Author

MUHAMAD, ZULKIFLI, AIMAN, CHIK, BILAL, ZAHID, and MOHAMAD, YAHYA

Subjects

WOVEN composites, THREE-dimensional textiles, CASCADE impactors (Meteorological instruments), IMPACT (Mechanics), COMPOSITE structures

Abstract

Copyright of Industria Textila is the property of Institutul National de Cercetare-Dezvoltare pentru Textile si Pielarie and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

49. Characterizing and predicting the self-folding behavior of weft-knit fabrics.

Author

Amanatides, Chelsea, Ghita, Oana, Evans, Ken E, and Dion, Genevieve

Subjects

TECHNICAL textiles, COMPUTER-aided design software, THREE-dimensional textiles, TEXTILES, POWER transmission, KNITTING machines

Abstract

Self-folding behavior is an exciting property of weft-knit fabrics that can be created using just front and back stitches. This behavior is easy to create, but not easy to anticipate and currently cannot be predicted by the existing computer-aided design software that controls industrial knitting machines. This work identifies the edge deformation behaviors that lead to self-folding in weft knits, and methods to characterize the mechanical forces driving these behaviors with regard to chosen manufacturing parameters. With this data and analysis of the fabric deformations, the self-folding behavior was purposely controlled using calculated scaling factors. Furthermore, theoretical equations were developed to mathematically predict these scaling factors, minimizing the trial and error required to design with self-folding behavior and create textiles with novel engineered properties. By understanding the mechanisms responsible for creating these three-dimensional self-folding textiles, they can then be designed in a programmable manner for use in technical applications. [ABSTRACT FROM AUTHOR]

Published

2022

50. Preparation and property of soluble hemostatic material with 3D knitted structure.

Author

Zhang, Shiyao, Shi, Tingting, Wu, Guangjun, Zhang, Qi, and Ma, Pibo

Subjects

THREE-dimensional textiles, BLOOD coagulation, WATER vapor, SKIN injuries, WOUND healing

Abstract

To solve the problems of low mechanical properties and poor coagulation effect of soluble hemostatic dressings, a new type of soluble hemostatic fabric with three-dimensional knitted structure is proposed in this paper. Three-dimensional knitted fabrics had good extension and porous structure. This three-dimensional soluble knitted fabric can be used for skin wounds clotting and healing. This paper mainly studied the influence of structural thickness on the performance of three-dimensional knitted dressings. Characterization analysis showed that three-dimensional knitted soluble hemostatic dressings had appropriate porosity and water vapor transmission rate (WVTR), and the fabric with the maximum thickness had good elongation (70.04%) and a very low blood clotting index (BCI) (11.18%). This suggests the potential application for soluble three-dimensional knitted structure fabric on skin wound hemostasis. [ABSTRACT FROM AUTHOR]

Published

2022