Stainless steel/polyester woven fabrics and copper/polyester woven fabrics: Manufacturing techniques and electromagnetic shielding effectiveness

Lou, Ching‐Wen; Lin, Ting An; Chen, An-Pang; Lin, Jia‐Horng

doi:10.1177/1528083715580518

Cited by 35 publications

(34 citation statements)

References 25 publications

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“…When the frequency exceeds 2000 MHz, the incident waves become short enough to easily penetrate through the slit on the shield. This results in leaky wave phenomenon and decreases EMI SE [21][22][23]. FIGURE 11.…”

Section: Emi Shielding Property Of Conductive Woven Fabric Effects Ofmentioning

confidence: 99%

Preparation Technique and EMI Shielding Evaluation of Flexible Conductive Composite Fabrics Made by Single and Double Wrapped Yarns

Lou

Hwang

et al. 2017

Journal of Engineered Fibers and Fabrics

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Electronics products and communication equipment release electromagnetic (EM) waves in service. EM waves affect biological health and precision instrument accuracy. This study purposes to fabricate flexible conductive composite fabric which is made of complex yarn using metal (stainless steel, copper) fibers and PET filaments. Complex yarn is formed by a rotor twisting machine, at varying values of wrapped number (6.5-16 turns/cm) and lamination number (single-layer, double-layer). Results show that when the complex yarn was wrapped 16 turns/ cm, volume resistivity reached 2.9 Ohm-cm and conductivity reaches 0.408 S/cm. Four layers of conductive composite plied with 0°/90°/ 0°/ 90° resulted in the optimum electromagnetic shielding effectiveness, up to 47.7 dB.

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Section: Emi Shielding Property Of Conductive Woven Fabric Effects Ofmentioning

confidence: 99%

Preparation Technique and EMI Shielding Evaluation of Flexible Conductive Composite Fabrics Made by Single and Double Wrapped Yarns

Lou

Hwang

et al. 2017

Journal of Engineered Fibers and Fabrics

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“…For EM shielding yarns, metal wires incorporated into the yarn are often considered to be the best and most straightforward EM shielding material because of their excellent conductivity and the fabric s permeability [14]. Compared to traditional stiff metallic materials, yarns and/or fabrics containing metallic staple fibers/continuous wires have gained considerable interest recently [14][15][16][17][18]. Yarns with a range of different conductive fibers and wires have been examined including stainless steel [5,7,[19][20][21][22][23], copper [23,24], silver-coated wire [25].…”

Section: Introductionmentioning

confidence: 99%

“…Based on current literature on the EMI shielding of woven/knitted fabrics containing continuous metal wires and/or metallic fibers, it is noted that factors such as the type of metal, its thickness, metallic content and its distribution and orientation of within a yarn and/or fabric, along with fabric factors such as weave construction, warp/weft density, the lamination layers and lamination angles have considerable effects on the EMSE values of the resultant composite fabrics [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27]. However, work reported so far has mostly measured EM radiation in the low frequency range (usually 0-3 GHz) and fabrics without any elastic features.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Stretchable Conductive Woven Fabric Containing Metal Wire with Durable Structural Stability and Electromagnetic Shielding in the X-Band

et al. 2020

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Elastomeric, conductive composite yarns have recently received attention around the opportunity for them to offer special protective fields. A straightforward approach for fabricating tri-component elastic-conductive composite yarns (t-ECCYs) containing stainless steel wire (SSW) was proposed previously. This work mainly focuses on the electromagnetic shielding effectiveness (EMSE) of weft-stretchable woven fabric containing t-ECCY over the X-band under different testing conditions, e.g., single step-by-step elongation, cyclic stretch and lamination events. Results showed that a woven cotton fabric with weft yarn of t-ECCY not only exhibited superior weft stretch-ability to a higher elongation (>40%) compared with a pure cotton control but also had an acceptable 15-cyclic stability with 80% shape recovery retention. The t-ECCY weft fabric was effective in shielding electromagnetic radiation, and its EMSE was also enhanced at elevated elongations during stretch at parallel polarization of EM waves. There was also no decay in EMSE before and after the t-ECCY fabric was subject to 15 stretch cycles at extension of 20%. In addition, a 90 • by 90 • cross lamination of t-ECCY fabric remarkably improved the EMSE compared to a 0 • /90 • one. The scalable fabrication strategy and excellent EMSE seen in t-ECCY-incorporated fabrics represent a significant step forward in protective fields.

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“…Therefore, hybrid yarns produced from metal wires with synthetic or natural fibers/yarns can be preferable. 8,12 In previous studies, various methods were used for the production of metal composite yarn such as blending in staple form, 6,13 hollow spindle, 9,10,14 metal coating, 15 plying/twisting with metal wire, [16][17][18] core spun, 1,[19][20][21][22][23][24] and siro core spinning. 8 There are many studies about knitted fabrics produced from different types of metal composite yarns.…”

Section: Introductionmentioning

confidence: 99%

Investigation on antimicrobial activity and electromagnetic shielding effectiveness of metal composite single jersey fabrics

Özkan

2019

Journal of Engineered Fibers and Fabrics

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In this study, antimicrobial and electromagnetic shielding properties of metal composite single jersey fabrics were investigated. For this purpose, stainless steel wire, copper wire, and metalized silver polyamide filament were commingled with textured polyester. The composite yarns were knitted to single jersey fabrics. Electromagnetic shielding effectiveness of samples was measured according to free space test method between 0.8 and 5.2 GHz frequency range. In addition, antibacterial and antifungal activity tests were performed for the overall technical characterization of composite fabrics. The effects of metal type, filament form on electromagnetic shielding effectiveness, and antimicrobial properties were examined. All composite fabrics showed electromagnetic shielding properties at different levels up to 35 dB in vertical direction. Fabrics including metalized multifilament yarn exhibit higher electromagnetic shielding effectiveness in both vertical and horizontal directions. In addition, antibacterial activity level of metalized silver polyamide and copper composite fabrics reached up to 99% against Klebsiella pneumoniae and Staphylococcus aureus. Furthermore, Aspergillus niger could not grow on these composite fabrics.

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Stainless steel/polyester woven fabrics and copper/polyester woven fabrics: Manufacturing techniques and electromagnetic shielding effectiveness

Cited by 35 publications

References 25 publications

Preparation Technique and EMI Shielding Evaluation of Flexible Conductive Composite Fabrics Made by Single and Double Wrapped Yarns

Preparation Technique and EMI Shielding Evaluation of Flexible Conductive Composite Fabrics Made by Single and Double Wrapped Yarns

Multifunctional Stretchable Conductive Woven Fabric Containing Metal Wire with Durable Structural Stability and Electromagnetic Shielding in the X-Band

Investigation on antimicrobial activity and electromagnetic shielding effectiveness of metal composite single jersey fabrics

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