Preparation and Application of Conductive Textile Coatings Filled with Honeycomb Structured Carbon Nanotubes

Govaert, Filip; Vanneste, Myriam

doi:10.1155/2014/651265

Cited by 28 publications

(17 citation statements)

References 8 publications

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“…The introduction of electrical conductivity onto the surface of textiles leads to the production of high-added value textiles i.e., the dubbed electronic textiles (e-textiles), with applications in electronic sensors, data storage, optoelectronic and photonics. Such e-textiles have found use in diverse commercial sectors such as sport, protective clothing, healthcare and technical purposes [ 1 ]. This has often involved electronic components and circuit boards being attached to the textile, but this inevitably leads to a change in the feel and drape of a textile and increases its mass.…”

Section: Introductionmentioning

confidence: 99%

“…In another approach, Cho et al used polyurethane-sealing onto Cu/Ni electroless plated polyester fabric for e-textiles [ 7 ]. Govaert and Vanneste employed several techniques to protect a conductive layer consisting of carbon nanotubes i.e., direct coating, transfer coating and screen printing, for the application of water based polyacrylate binder [ 1 ]. To improve wear durability and adhesion at the interface between Cu film and PES fabric, Jiang et al treated the Cu-coated polyester fabric with two commercial solutions of polyester-polyurethane and aqueous acrylate in different concentrations, which also showed advantages in the resistance to aging [ 17 ].…”

Section: Introductionmentioning

confidence: 99%

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The Efficacy of Polymer Coatings for the Protection of Electroless Copper Plated Polyester Fabric

et al. 2020

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The selective metallisation of textiles is becoming a very important process in the development of electronic or e-textiles. This study investigated the efficacy of polymer coatings for the protection of copper (Cu) conductive tracks electroless plated on polyester (PES) fabric against laundering and rubbing, without essentially affecting the physical-mechanical and optical properties of the base material. After the electroless deposition of a consistent layer of Cu onto PES, four polymers were applied individually by screen-printing or padding. The physical-mechanical characterisation of coated textiles revealed that polyurethane resin (PUR) and modified acrylate resin (AR) had little effect on the air permeability, tensile strength and breaking tenacity of the PES, as compared to silicone elastomer polydimethylsiloxane (PDMS) and epoxy resin (ER). On the other hand, PUR and PDMS had higher abrasion resistance and photo-stability under prolonged UV irradiation, as compared to AR and ER. In addition, freshly Cu plated samples were coated with polymers, washed up to 30 cycles and characterised by measuring their electrical resistivity, determination of colour changes and the examination of the surface morphology. Based on these results, PUR presented the most suitable protection of Cu tracks on PES, with the lowest impact on physical-mechanical properties. ER is not recommended to be used for protection of Cu tracks on fabrics, due to its rigidity, low photo-stability, washing and wear durability.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Efficacy of Polymer Coatings for the Protection of Electroless Copper Plated Polyester Fabric

et al. 2020

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“…Further, low glass transition temperatures of polymer make them unusable in high-temperature applications. Ceramic substrates can be an alternative which can withstand high temperature and can be used in flexible applications [ 247 ].…”

Section: Challenges and Future Prospects Of Flexible Antennasmentioning

confidence: 99%

Flexible Antennas: A Review

et al. 2020

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The field of flexible antennas is witnessing an exponential growth due to the demand for wearable devices, Internet of Things (IoT) framework, point of care devices, personalized medicine platform, 5G technology, wireless sensor networks, and communication devices with a smaller form factor to name a few. The choice of non-rigid antennas is application specific and depends on the type of substrate, materials used, processing techniques, antenna performance, and the surrounding environment. There are numerous design innovations, new materials and material properties, intriguing fabrication methods, and niche applications. This review article focuses on the need for flexible antennas, materials, and processes used for fabricating the antennas, various material properties influencing antenna performance, and specific biomedical applications accompanied by the design considerations. After a comprehensive treatment of the above-mentioned topics, the article will focus on inherent challenges and future prospects of flexible antennas. Finally, an insight into the application of flexible antenna on future wireless solutions is discussed.

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“…With the rapid development of technology in the textile industry, conventional textiles have been unable to meet peoples' demand for the functionality like antibacterial, shielding effectiveness, and conductivity . Hence, textiles with high quality of multifunction have attracted a large number of researchers' attention due to large potential for new applications and market demand .…”

Section: Introductionmentioning

confidence: 99%

Conductive, antibacterial, and electromagnetic shielding silver‐plated cotton fabrics activated by dopamine

Mao

Wang

2018

J of Applied Polymer Sci

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A two-step method was developed in this article to fabricate conductive silver-plated cotton fabrics, imparting them with antibacterial and electromagnetic shielding properties. Cotton fabric was firstly functionalized by a spontaneous polymerization of dopamine, which acted as an activation and adsorption layer to initiate the following silver plating through the catechol and indole functional groups. The chemical composition of the functional cotton fabric was investigated by X-ray photoelectron spectroscopy and the surface morphology of the fabric was observed by scanning electron microscopy. The crystalline structure of the silver-coated cotton fibers was characterized by power X-ray diffraction, and thermogravimetric analysis of the fabric was also studied to show thermal stability. The homogeneous silver plating was highly conductive with surface resistance about 23.55 mΩ sq. −1 and shielding effectiveness was about 55~95 dB. It also demonstrated excellent and durable antibacterial property against Staphylococcus aureus and Escherichia coli both with reduction percent of bacteria over 99.99%. All of above features made this silver-plated cotton fabrics a promising candidate as multifunctional textiles.

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Preparation and Application of Conductive Textile Coatings Filled with Honeycomb Structured Carbon Nanotubes

Cited by 28 publications

References 8 publications

The Efficacy of Polymer Coatings for the Protection of Electroless Copper Plated Polyester Fabric

The Efficacy of Polymer Coatings for the Protection of Electroless Copper Plated Polyester Fabric

Flexible Antennas: A Review

Conductive, antibacterial, and electromagnetic shielding silver‐plated cotton fabrics activated by dopamine

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