Directional Trans-Planar and Different In-Plane Water Transfer Properties of Composite Structured Bifacial Fabrics Modified by a Facile Three-Step Plasma Treatment

Sun, Fengxin; Chen, Zhiqiang; Zhu, Licheng; Du, Zhaoqun; Wang, Xungai; Naebe, Maryam

doi:10.3390/coatings7080132

Cited by 11 publications

(8 citation statements)

References 53 publications

(62 reference statements)

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“…Therefore, PTM clothing has made a profound contribution to healthcare textiles as well as smart textile industries. Numerous materials and approaches such as phase-change materials, − shape memory polymers, − smart membranes, − smart coating, smart spider silk, infrared (IR)-responsive materials, , nanoporous polyethylene, − living organisms, conductive polymers, , bifacial fabric, and wearable devices − have been developed to fabricate textiles with personal thermal management ability. However, the limitations of most of the materials are the slower response time, being harmful to nature, complex processability, and high cost, which confine their applications in the industrial scale.…”

Section: Introductionmentioning

confidence: 99%

Knit Architecture for Water-Actuating Woolen Knitwear and Its Personalized Thermal Management

Iqbal

Sun

Fei

et al. 2021

ACS Appl. Mater. Interfaces

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Personalized thermal management using water-actuated woolen knitwear has great potential for smart textile production. However, woolen knitwear exists in a wide range of forms with different derivatives. Manufacturing of smart woolen structures with excellent cooling properties is linked to certain parameters such as changes in loop formation, loop shape, and yarn arrangement upon stimulation of body fluids. To address this issue, textile knit structures with different physical and mechanical properties have been prepared using water-responsive descaled wool fibers and their smart heat and moisture regulation behavior have been investigated and compared to detect the fabric architectural effect on water actuation and cooling performance of woolen garments. The evidence suggests that the technical structure of the fabrics plays a crucial role in pore actuation and fabric cooling performance. The water actuation and thermal management abilities of single jersey were greatly enhanced because of unbalanced structures with lower mechanical stress among the loops and yarns. The experimental data is also in line with the theoretical analysis. Hence, the unbalanced structures control fast heat and mass transfer from the human body, which may offer a promising year-round clothing material to the wearer. This material can have a similar response upon contact with body sweat and humid environments and hence can act as a skinlike fabric. Their possible applications can lie in different fields, such as thermoregulation, functional clothing, sportswear, and medical care.

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Section: Introductionmentioning

confidence: 99%

Knit Architecture for Water-Actuating Woolen Knitwear and Its Personalized Thermal Management

Iqbal

Sun

Fei

et al. 2021

ACS Appl. Mater. Interfaces

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“…The asymmetric coatings were also obtained on polyester fabric substrate via a fluoropolymer (PHFDMA) deposition method, and cotton fabric substrate via plasma-enhanced chemical vapor deposition . However, these methods still suffered the following drawbacks such as (1) the requirement of materials with natural superhydrophilicity; (2) strong dependence of the characteristics of the porous substrate, the health problems cases by the photogenerated reactive oxygen species (ROS); (3) the complicated preparation process and expensive reagents; (4) the cytotoxicity, bioaccumulation, and environmental toxicity of modification agent, which was not suitable for wound dressing. − In addition, the reported materials with asymmetric wettability were mainly filmwise materials (i.e., cotton fabric, polymer film), which possessed relatively low liquid absorbency. Although porous aerogels or sponges with three-dimensional (3D) architecture possessed highly improved liquid adsorption ability compared to filmwise materials, − they cannot avoid the infiltration of pathogenic microorganisms and wound dehydration .…”

Section: Introductionmentioning

confidence: 99%

Stearic Acid-Modified Starch/Chitosan Composite Sponge with Asymmetric and Gradient Wettability for Wound Dressing

Zhao

Yang

et al. 2018

ACS Appl. Bio Mater.

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In this work, we developed a facile approach for the fabrication of stearic acid-modified starch/chitosan composite sponge with asymmetric wettability and gradient wettability via mediating the amount of starch. The starch/chitosan composite sponge exhibited heterogeneous wetting properties on its two surfaces after stearic acid modification. The superhydrophobic top surface with a water contact angle of 150°could prevent water, blood, and bacterial permeation without losing the breathability of the sponge, whereas the superhydrophilic bottom surface possessed optimal water and blood absorption and clotting abilities. The asymmetric wettability of starch/chitosan composite sponge was attributed to the synergistic contribution of gradient distribution of starch, rough three-dimensional skeleton structure induced capillary effect and the nonuniform surface distribution of hydrophilic/hydrophobic groups. Furthermore, the sponge also possessed good biodegradability and noncytotoxicity to the human normal hepatocyte. The results indicated that the stearic acid-modified starch/chitosan composite sponge with ideal liquid absorption, vapor transmission rate, self-cleaning and stain-repellent ability could be used as a promising candidate for wound dressing.

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“…To reduce the use of solvents, the researchers began to prepare single-guide wet textiles by surface deposition/polymerization. 11,12 Tian et al 13 prepared a single-guide wet textile by single-side vapor deposition. They placed the hydrophilic cotton fabric on a container containing perfluorooctane triethoxysilane and silanized the side in contact with steam to form a hydrophobic structure.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Characterization of a PU/(PAN/PVP) Unidirectional Moisture Transport Fibrous Membrane

Qin,

Guo,

et al. 2023

ACS Appl. Polym. Mater.

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The electrostatic spinning process synthesized and prepared a PU/ (PAN/PVP) double-layer fibrous membrane with different wettability. In the research, polyethylene pyrrolidone (PVP) was added to increase the hydrophilic property of polyacrylonitrile (PAN). Meanwhile, dopamine was introduced to modify the hydrophobic material to strengthen the polyurethane (PU) fiber film surface wettability. It was found that the hydrophilicity and wettability of the PAN fiber membrane could be improved with the addition of PVP. The wicking height of the PAN/PVP fiber membrane could reach 9.8 cm as the additional amount of PVP was 2 wt %. The liquid moisture management tester was used to characterize the effect of unidirectional wet performance on the thickness ratio of the PAN/ PVP fiber membrane and PU fiber membrane. The experimental results show that the unidirectional moisture conductivity reaches as high as 967% with the best effect when (PAN/PVP)/PU thickness ratio was 2:1; a unidirectional wet effect could be achieved as water can be transferred from the PU fiber membrane interface to the PAN/PVP layer.

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Directional Trans-Planar and Different In-Plane Water Transfer Properties of Composite Structured Bifacial Fabrics Modified by a Facile Three-Step Plasma Treatment

Cited by 11 publications

References 53 publications

Knit Architecture for Water-Actuating Woolen Knitwear and Its Personalized Thermal Management

Knit Architecture for Water-Actuating Woolen Knitwear and Its Personalized Thermal Management

Stearic Acid-Modified Starch/Chitosan Composite Sponge with Asymmetric and Gradient Wettability for Wound Dressing

Preparation and Characterization of a PU/(PAN/PVP) Unidirectional Moisture Transport Fibrous Membrane

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