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Journal articles on the topic 'Technical textiles'

Author: Grafiati
Published: 4 June 2021
Last updated: 25 July 2025

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1

Zhezhova, Silvana, Sonja Jordeva, Sashka Golomeova-Longurova, and Stojanche Jovanov. "Application of technical textile in medicine." Tekstilna industrija 69, no. 2 (2021): 21–29. http://dx.doi.org/10.5937/tekstind2102021z.

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Medical textile is an extremely important subcategory of technical textile because it is covering a wide range of products. The term medical textile itself covers all types of textile materials that are used in the healthcare system for various purposes. Medical textile is also known as health textile and is one of the fastest growing sectors in the technical textile market. The growth rate of technical textiles in this area is due to constant improvements and innovations in both areas: textile technologies and medical procedures. Textile structures used in this field include yarns, woven, kni
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2

Bai, S. Kauvery. "Textile Application in Technical Fields." Mapana - Journal of Sciences 3, no. 1 (2004): 85–93. http://dx.doi.org/10.12723/mjs.5.10.

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Textile is generally referred as spinning and weaving and the layman does not hove idea of textiles in transportation, filtration, protective clothing, military application a nd in the medical field. The use cf textiles for clothing was to mankind from primitive age and was extended to household and domestic applications with progressive civilization. Amit Dayal 1999) states that the technological advancement of textile science has Seen tc such cn extent that no area seem fo be untouched by textiles. David Rigby (1997) defined Technicol textik materials products manufactured primarily for thei
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TRIPA, SIMONA, LILIANA INDRIE, PABLO DÍAZ GARCÍA, and DAIVA MIKUCIONIENE. "Solutions to reduce the environmental pressure exerted by technical textiles: a review." Industria Textila 75, no. 01 (2024): 66–74. http://dx.doi.org/10.35530/it.075.01.202367.

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This paper highlights the fact that the technical textile industry plays a significant role in the textile and apparel industry and the technical textile subsector is one of the most dynamic, accounting for an increasing share of EU textile output. In recent years, there has been a significant increase in the production of technical textiles in the EU, which in turn leads to an increase in the environmental impact generated by the production and consumption of these products. The entire process of producing technical textile items creates several forms of pollution in the air, water, and soil,
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Aldalbahi, Ali, Mehrez E. El-Naggar, Mohamed H. El-Newehy, Mostafizur Rahaman, Mohammad Rafe Hatshan, and Tawfik A. Khattab. "Effects of Technical Textiles and Synthetic Nanofibers on Environmental Pollution." Polymers 13, no. 1 (2021): 155. http://dx.doi.org/10.3390/polym13010155.

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Textile manufacturing has been one of the highest polluting industrial sectors. It represents about one-fifth of worldwide industrial water pollution. It uses a huge number of chemicals, numerous of which are carcinogenic. The textile industry releases many harmful chemicals, such as heavy metals and formaldehyde, into water streams and soil, as well as toxic gases such as suspended particulate matter and sulphur dioxide to air. These hazardous wastes, may cause diseases and severe problems to human health such as respiratory and heart diseases. Pollution caused by the worldwide textile manufa
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Caicedo, Carolina, Leticia Melo López, Christian Javier Cabello Alvarado, Víctor Cruz Delgado, and Carlos Alberto Ávila Orta. "Nanocomposite and biodegradable polymers applied to technical textiles." DYNA 86, no. 211 (2019): 288–99. http://dx.doi.org/10.15446/dyna.v86n211.80230.

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Based on the results of research papers reflected in the scientific literature, the main examples, methods and perspectives for the development of technical textiles are considered. The focus of this work is to concentrate the results obtained for different textile applications (technical textiles) through the use of biodegradable polymers modified and improved with nanoparticles. The techniques for obtaining polymeric nanocomposites, finishing processes, type and structure of textiles are specified. In general, key aspects are identified for a better understanding of the technical challenges
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Klinkhammer, Kristina, Hanna Hohenbild, Mohammad Toufiqul Hoque, Laura Elze, Helen Teshay, and Boris Mahltig. "Functionalization of Technical Textiles with Chitosan." Textiles 4, no. 1 (2024): 70–90. http://dx.doi.org/10.3390/textiles4010006.

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Textiles are used for many different applications and require a variety of properties. Wet functionalization improve textiles’ properties, such as hydrophilicity or antimicrobial activity. Chitosan is a bio-based polymer widely investigated in the textile industry for this purpose. A weaving comprising a cotton/polyester mix and a pure-polyester weaving was functionalized with different concentrations of chitosan to determine the most robust method for chitosan detection in both cotton- and polyester-containing materials. Additionally, mixtures of chitosan with 3-glycidyloxypropyltriethoxy sil
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7

Bosowski, Patrycja, Christian Husemann, Till Quadflieg, Stefan Jockenhövel, and Thomas Gries. "Classified Catalogue for Textile Based Sensors." Advances in Science and Technology 80 (September 2012): 142–51. http://dx.doi.org/10.4028/www.scientific.net/ast.80.142.

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Technical textiles are used primarily for their technical functionality in many different industries. For monitoring the functionality of textiles it is possible to integrate sensors into the textile. Since textiles are made of fibres, yarns, two-or three dimensional structures the sensor systems should accordingly be designed as a part of them. Smart textiles are concerned with textile based sensors integrated mechanically and structurally to a textile. The state of the art in developing textile based sensors extends from sensor fibres to over coated yarns and textiles but without using stand
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Malashin, Ivan, Dmitry Martysyuk, Vadim Tynchenko, et al. "Machine Learning in Polymeric Technical Textiles: A Review." Polymers 17, no. 9 (2025): 1172. https://doi.org/10.3390/polym17091172.

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The integration of machine learning (ML) has begun to reshape the development of advanced polymeric materials used in technical textiles. Polymeric materials, with their versatile properties, are central to the performance of technical textiles across industries such as healthcare, aerospace, automotive, and construction. By utilizing ML and AI, researchers are now able to design and optimize polymers for specific applications more efficiently, predict their behavior under extreme conditions, and develop smart, responsive textiles that enhance functionality. This review highlights the transfor
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RADULESCU, Ion Razvan, Carmen GHITULEASA, Emilia VISILEANU, et al. "SMART TEXTILES TO PROMOTE MULTIDISCIPLINARY STEM TRAINING." TEXTEH Proceedings 2019 (November 5, 2019): 174–77. http://dx.doi.org/10.35530/tt.2019.38.

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Smart textiles consist of multi-disciplinary knowledge. Disciplines such as physics, mathematics, material science or electrics is needed in order to be able to design and manufacture a smart textiles product. This is why knowledge in smart textiles may be used to showcase high school and university students in basic years of preparation some applications of technical disciplines they are learning. The Erasmus+ project “Smart textiles for STEM training – Skills4Smartex” is a strategic partnership project for Vocational Education and Training aiming to promote additional knowledge and skills fo
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Wang, Yang. "Research on Flexible Capacitive Sensors for Smart Textiles." Journal of Physics: Conference Series 2181, no. 1 (2022): 012038. http://dx.doi.org/10.1088/1742-6596/2181/1/012038.

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Abstract Smart textiles are a new era of smart textiles that not only have traditional textile functions, but also have information collection, feedback, and multiple intelligent interaction functions with users. As a manifestation of the combination of art and technology in the textile field, smart textiles are of great significance to traditional textiles, clothing, home textiles, and wearable devices. From the perspectives of the background, technology, and development prospects of smart textiles, this article systematically analyses the application technology of smart textiles in practice.
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11

Faical, Zaim, and Morad Sbiti. "Product’s Selection for the Moroccan Technical Textile Industry by Using Custom’s Imports Data and Analytic Models." Modern Applied Science 10, no. 4 (2016): 47. http://dx.doi.org/10.5539/mas.v10n4p47.

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<p>This paper proposes a model of product’s selection for Moroccan technical Textile industry. In a first step, using software, the study selects technical textiles positions, classes them by technologies segments, and extracts their import’s data from governmental data based, in term of value, volume, unit price and suppliers. In a second step overweight various segments and products using Analytical Hierarchy Process (AHP) to calculate attractiveness and competitive strength and chooses which of them are the most suitable for investment by using a Mckinsey matrix. From the 481 products
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Aishwarya, R., and M. Sumithra. "Importance of Antimicrobial Finishes in Sportech: An Overview." ComFin Research 12, S2-Feb (2024): 193–200. http://dx.doi.org/10.34293/commerce.v12is1-feb.7581.

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Technical textiles are distinct from other types of textiles because their purpose is not to be aesthetically pleasing or decorative, but rather to have specific functional properties and technical performance.Textiles can be made to have unique functions by applying surface finishing agents and surface treatments, or by incorporating specialty fibers and polymers. Barrier, protection, improved comfort, medication, sensory, actuation, and shielding are a few examples of these functions.One of the biggest manufacturers of products in the Packtech, Clothtech, Hometech, and Sportech segments of t
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Rayhan, Md Golam Sarower, M. Khalid Hasan Khan, Mahfuza Tahsin Shoily, et al. "Conductive Textiles for Signal Sensing and Technical Applications." Signals 4, no. 1 (2022): 1–39. http://dx.doi.org/10.3390/signals4010001.

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Conductive textiles have found notable applications as electrodes and sensors capable of detecting biosignals like the electrocardiogram (ECG), electrogastrogram (EGG), electroencephalogram (EEG), and electromyogram (EMG), etc; other applications include electromagnetic shielding, supercapacitors, and soft robotics. There are several classes of materials that impart conductivity, including polymers, metals, and non-metals. The most significant materials are Polypyrrole (PPy), Polyaniline (PANI), Poly(3,4-ethylenedioxythiophene) (PEDOT), carbon, and metallic nanoparticles. The processes of maki
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14

Şahin, Yelda Durgun, and Mehmet Okur. "THE TYPES OF TEXTILES USED IN THE FACADE AND ROOFING SYSTEMS OF STADIUM FACILITIES IN TURKEY." Fibres and Textiles 32, no. 1 (2025): 96–101. https://doi.org/10.15240/tul/008/2025-1-019.

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Technical textiles are functional fabrics that have applications across including both construction (BuildTech) and architecture (ArchiTech). This technical textile is developed for high-tech and high-performance applications. In modern architecture, high-performance textile materials are highly valued and widely used in various applications, including self-cleaning, low-maintenance structures, fabric canopies, and energyefficient buildings. They are also utilized for high-performance façades, energy-harvesting curtains, flexible mega-structures, responsive phase-change materials, air-supporte
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15

Uddin, Faheem, Komal Umer, and Syeda Tehniyat Anjum. "Textile solid waste in product development studies." Chemical Reports 3, no. 1 (2022): 203–9. http://dx.doi.org/10.25082/cr.2021.01.005.

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Textile solid waste disposal and utilization is currently an important concern worldwide. Fashion and traditional articles of textiles are sourcing the solid textile waste generation. An increasing population and consumption of fiber and textile articles emphasize the development studies for the re-use of solid textile waste. Production of textiles is accompanied by the release of volatile emission and effluent during processing, and disposal of fibrous articles are producing solid waste. The hazardous waste generated from the textile can be seen as pre- consumer solid waste (fiber, yarn, and
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16

Choudhury, Lipi. "MAKING INDIA’S TECHNICAL TEXTILE INDUSTRY GLOBALLY COMPETITIVE: A STRATEGIC APPROACH." Journal of Modern Management & Entrepreneurship 15, no. 02 (2025): 151–56. https://doi.org/10.62823/jmme/15.02.7610.

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Compared to conventional textiles, technical textiles have better performance characteristics in terms of durability, functionality, ergonomics, moisture wicking, temperature maintenance etc. which leads to their increased usage in areas like protective clothing used during exposure to fire, chemicals and severe weather conditions; applications in agriculture, real estate and public infrastructure construction due to the safety, comfort and sustainability associated with these textile products. Coupled with this factor like urbanization, industrialization and advancements in healthcare, automo
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17

Vashist, Paribha, Santanu Basak, and Wazed Ali. "Bark Extracts as Multifunctional Finishing Agents for Technical Textiles: A Scientific Review." AATCC Journal of Research 8, no. 2 (2021): 26–37. http://dx.doi.org/10.14504/ajr.8.2.4.

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Bark extracts are important sources of natural dyes. They possess many functional properties of potential interest to the textile industry. Currently, textiles with eco-friendly functional finishing are increasingly sought for in medical and protective clothing due to stringent environmental laws and the associated toxicity of synthetic agents. In view of this, recent studies on bark extracts for multi-functional finishing of textiles, particularly for antimicrobial and UV protective finishing, is reviewed. Bark extracts from various trees are able to effectively impart antimicrobial resistanc
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18

M. Shahidi, Arash, Kalana Marasinghe, Parvin Ebrahimi, et al. "Quantification of Fundamental Textile Properties of Electronic Textiles Fabricated Using Different Techniques." Textiles 4, no. 2 (2024): 218–36. http://dx.doi.org/10.3390/textiles4020013.

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Electronic textiles (E-textiles) have experienced an increase in interest in recent years leading to a variety of new concepts emerging in the field. Despite these technical innovations, there is limited literature relating to the testing of E-textiles for some of the fundamental properties linked to wearer comfort. As such, this research investigates four fundamental properties of E-textiles: air permeability, drape, heat transfer, and moisture transfer. Three different types of E-textiles were explored: an embroidered electrode, a knitted electrode, and a knitted structure with an embedded e
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19

Janarthanan, M., and M. Senthil Kumar. "The properties of bioactive substances obtained from seaweeds and their applications in textile industries." Journal of Industrial Textiles 48, no. 1 (2017): 361–401. http://dx.doi.org/10.1177/1528083717692596.

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Technical textiles are one of the fastest emergent sectors of textile industries worldwide. Medical textiles and healthcare textiles are the most important development areas within technical textiles. A rapid advancement in the health care and hygiene sector together with an increase in health consciousness has made medical textiles an important field. In order to protect people against harmful pathogens, an antimicrobial textile has been developed and as a result, finishes began to evolve in recent years. A critical problem regarding healthcare and hygiene products chemical based synthetic an
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Kgatuke, Matholo, Dorothy Hardy, Katherine Townsend, et al. "Exploring the Role of Textile Craft Practice in Interdisciplinary E-Textiles Development through the Design of an Illuminated Safety Cycling Jacket." Proceedings 32, no. 1 (2019): 12. http://dx.doi.org/10.3390/proceedings2019032012.

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Most E-textile research tends to fall within the arts or science disciplinary boundaries, despite E-textiles themselves being interdisciplinary in nature. This work explores how contemporary woven textile practice methodologies can play a role within interdisciplinary research, expanding the creative and technical applications of materials and technologies. A team of electronics, textiles, and fashion specialists was formed to design and make an illuminated jacket for use by cyclists. The jacket incorporated bespoke woven panels that integrated electronic yarns within the pattern. The developm
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Schnatmann, Anna Katharina, Fabian Schoden, Andrea Ehrmann, and Eva Schwenzfeier-Hellkamp. "R principles for circular economy in the textile industry – a mini-review." Communications in Development and Assembling of Textile Products 4, no. 2 (2023): 295–305. http://dx.doi.org/10.25367/cdatp.2023.4.p295-305.

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Textiles are used by humans for many purposes, from clothing to technical applications such as geotextiles, agrotextiles, or medical textiles. However, in addition to their importance, textiles are also responsible for various types of environmental pollution along the entire textile chain, from production, transport and trade to daily use to their end-of-life. Here we provide a brief overview of current approaches to establishing R principles in the textile industry in order to transform the recent linear structures into a circular economy and show in which areas there is a particular need fo
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Veske-Lepp, Paula, Bjorn Vandecasteele, Filip Thielemans, et al. "Study of a Narrow Fabric-Based E-Textile System—From Research to Field Tests." Sensors 24, no. 14 (2024): 4624. http://dx.doi.org/10.3390/s24144624.

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Electronic textiles (e-textiles) are a branch of wearable technology based on integrating smart systems into textile materials creating different possibilities, transforming industries, and improving individuals’ quality of life. E-textiles hold vast potential, particularly for use in personal protective equipment (PPE) by embedding sensors and smart technologies into garments, thus significantly enhancing safety and performance. Although this branch of research has been active for several decades now, only a few products have made it to the market. Achieving durability, reliability, user acce
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DIAS, Ana, Luís ALMEIDA, Mirela BLAGA, et al. "GUIDE FOR SMART PRACTICES TO SUPPORT INNOVATION IN SMART TEXTILES." TEXTEH Proceedings 2019 (November 5, 2019): 28–31. http://dx.doi.org/10.35530/tt.2019.07.

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Smart Textiles for STEM training (Science, Technology, Engineering and Math’s).is an Erasmus+ project aiming to bridge Textile Companies with the Education sector via Smart Textiles Innovation and Training. Industries have been surveyed to analyze the needs for new jobs and skills in Smart textiles, contributing to improve the links with VET Schools training and closing the gap between industry and education. During the project a number of smart textiles examples and prototypes are worked to be transferred to Schools and used by students and teachers, aiming to foster STEM training. This paper
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Yasin, Sohail, Massimo Curti, Giorgio Rovero, Munir Hussain, and Danmei Sun. "Spouted-Bed Gasification of Flame Retardant Textiles as a Potential Non-Conventional Biomass." Applied Sciences 10, no. 3 (2020): 946. http://dx.doi.org/10.3390/app10030946.

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Renewable energy from thermal valorization plays a key part in today’s energy from natural cellulosic textiles that are resourceful biomass and safe from toxicity at high temperature treatments. The situation is opposite, when technical textiles are treated with synthetic chemical finishes adding functionality as anti-bacterial, water repellent or flame retardant, etc. Incineration of flame retardant textile results in possible unfavorable gases, toxic fumes and contaminated ash. Other thermal valorization techniques like gasification would assist in avoiding the formation of additional toxic
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Zhezhova, Silvana, Sonja Jordeva, Sanja Risteski, Sashka Golomeova Longurova, and Vangja Dimitrijeva-Kuzmanoska. "Primjena tehničkog tekstila u sportu." Koža & obuća 73, no. 2 (2024): 3–10. http://dx.doi.org/10.34187/ko.73.2.1.

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Textile materials are used in all kinds of sports as sportswear in the form of shorts, T- shirts, tracksuits, swimwear, compression garments etc. Except for making clothes, textiles are used as an integral part of sports equipment or part of sports footwear. Also, technical textiles are widely used for production of sports accessories to provide additional comfort, support, and functionality. The application of textile composites in sports equipment has proven to be very useful, not only for improving overall performance but also in controlling every possible feature, leading to safer and fair
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KU, Savitha, Kavitha AL, and Revathi M. "AN OVERVIEW OF ELECTRICALLY CONDUCTING TEXTILES." Journal of Advanced Scientific Research 14, no. 03 (2023): 01–14. http://dx.doi.org/10.55218/jasr.2023140302.

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Textiles are having evolution from being normal protective clothing to smart and technical textiles. Electrically conducting fabrics forms the backbone of being smart textiles. The smart textile combines electronics with textile structures, referred to as “textronics”. One major challenge to the success of such wearable smart textile resides in the development of lightweight and flexible components, and fibrous structures with high electrical conductivity able to withstand the stresses associated with wearing and caring for the textile. Therefore, flexible, deformable, stretchable, and durable
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Chowdhury, Md Jonayet, Shamima Nasrin, and Md Abdullah Al Faruque. "Significance of Agro-Textiles and Future Prospects in Bangladesh." European Scientific Journal, ESJ 13, no. 21 (2017): 139. http://dx.doi.org/10.19044/esj.2017.v13n21p139.

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Agro-textile is a crucial and emerging sector among all the twelve sectors of technical textiles. It covers all the textile products from horticulture application to fishing and animal husbandry application. However, the significance of agro-textiles can be stated substantial all over the world. Also in Bangladesh, some application of agro-textiles products have shown great extent of outcomes and it has positive impacts on growth and production of various crops, vegetables. The main purpose of this research is to deliver an overview and importance of agro-textiles and to indicate the prospect
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Hegyi, Dezső, István Sajtos, and György Sándor. "Long-Term Strain Measuring of Technical Textiles by Photographic Method." Materials Science Forum 537-538 (February 2007): 381–88. http://dx.doi.org/10.4028/www.scientific.net/msf.537-538.381.

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The technical textiles are very sensitive materials. To measure the elongation of such a material needs special care. A photographic procedure has been investigated to measure the plain elongation of textile specimens. It is especially suitable for long-term measuring programs. Some experimental results measured by the described method are published.
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Xu, Qian, Yabin Yu, and Xiao Yu. "Analysis of the Technological Convergence in Smart Textiles." Sustainability 14, no. 20 (2022): 13451. http://dx.doi.org/10.3390/su142013451.

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Convergence between emerging technologies and traditional industries has become a crucial strategy for enhancing a technology’s competitiveness. Technical convergence (TC) for smart textiles aims to reveal the convergence of emerging technologies with textile technologies, including the field, structure, and critical technologies of the TC. For the empirical analysis, the technology life cycle (TLC) and network analysis method are utilized to observe the TC of 15,125 patent data for textiles from the Derwent Patent Database. The results indicate the following: (1) after 2021, the TC of smart t
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Oğuz, Naciye Sündüz. "Current Potential Use of Antibacterial Textile Products in Medical Technical Textiles." Journal of Green Technology and Environment 2, no. 2 (2024): 18–25. https://doi.org/10.5281/zenodo.14427385.

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In recent years, medical technical textiles have gained great importance with increasing customer demands, technological developments and consumer awareness. People can be exposed to many microorganisms in daily life and these microorganisms can reproduce rapidly under the influence of appropriate temperature, humidity and nutrients. These microorganisms can cause infectious diseases and deaths. Bacteria formed on textile materials negatively affect human health, and cause loss of strength, bad odor and stain formation on textile surfaces. Nowadays, in order to prevent the harm given to the us
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Krishnappa, Likith, Jan-Hendrik Ohlendorf, Michael Brink, and Klaus-Dieter Thoben. "Investigating the factors influencing the shear behaviour of 0/90∘ non-crimp fabrics to form a reference shear test." Journal of Composite Materials 55, no. 20 (2021): 2739–50. http://dx.doi.org/10.1177/0021998321991625.

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Technical textiles have the ability to deform under load by shearing, which distinguishes them from thin sheet materials such as paper. This particular property helps them to deform and take the shape of the complex part that they were intended to create. Draping, flexibility and handling of technical textiles are greatly affected by their shearing behaviour. In this paper, the influence that factors such as stitch (i.e., presence or absence of it), testing speed and the pre-tension force applied have on the shear behaviour of 0/90∘ technical textile is studied to form a reference test. To ach
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Vlach, Tomáš, Lenka Laiblová, Michal Ženíšek, Alexandru Chira, Anuj Kumar, and Petr Hájek. "The Effect of Surface Treatments of Textile Reinforcement on Mechanical Parameters of HPC Facade Elements." Key Engineering Materials 677 (January 2016): 203–6. http://dx.doi.org/10.4028/www.scientific.net/kem.677.203.

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Development of extremely thin concrete structures and demand for extremely thin elements are the reason of using composite non-traditional materials as reinforcement. Steel reinforcement is not very chemically resistant and it limits the thickness because of the required concrete cover as protection. This is the reason why textile reinforced concrete (TRC) going to be very famous and modern material. TRC in combination with fine grain high performance concrete (HPC) allows a significant saving of concrete. Due to its non-corrosive properties of composite technical textiles it is possible to de
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Revaiah, R. G., T. M. Kotresh, and Balasubramanian Kandasubramanian. "Technical textiles for military applications." Journal of The Textile Institute 111, no. 2 (2019): 273–308. http://dx.doi.org/10.1080/00405000.2019.1627987.

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Beer, M., V. Schrank, Y.-S. Gloy, and T. Gries. "Systematic development of technical textiles." IOP Conference Series: Materials Science and Engineering 141 (July 2016): 012005. http://dx.doi.org/10.1088/1757-899x/141/1/012005.

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35

ETHRIDGE, E., and D. URBAN. "ELECTROTEXTILES." International Journal of High Speed Electronics and Systems 12, no. 02 (2002): 365–69. http://dx.doi.org/10.1142/s0129156402001319.

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ElectroTexitles, the merging of electronics and textiles, is a new and novel technical area that leverages a fortuitous synergism between the electronics and textile industries. At some time in the future, we will look back upon what is happening now as turning point in the history of how electronic systems are fabricated. This session provides a summary of the technical challenges and some early technical results.
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Gowri, Sorna, Mohammad Akram Khan, and Avanish Kumar Srivastava. "Textile Finishing Using Polymer Nanocomposites for Radiation Shielding, Flame Retardancy and Mechanical Strength." Textile & Leather Review 4, no. 3 (2021): 160–80. http://dx.doi.org/10.31881/tlr.2021.07.

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The uses of nanotechnologies in textiles are strategic and allow textiles to become multifunctional. There is an ever-increasing demand for new functionalities, like flame retardancy, radiation shielding, improved mechanical strength etc., for highly specific applications. There is no industrial supply for the above-mentioned functionalities. Keeping in view of this background, surface treatment becomes one of the most important methods to create new textile properties. Polymer nanocomposites based on coatings for textiles have a huge potential for innovative modifications of surface propertie
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Prof, (Dr) Nemailal Tarafder. "Importance of Technical Textiles as Filtration Media-A Review." Journal of Industrial Mechanics 4, no. 1 (2019): 1–10. https://doi.org/10.5281/zenodo.2586465.

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Textiles are widely used in our day-to-day needs like filtration of air, liquids, food preparation as well as industrial production in large to keep us healthier from the surrounding environment. A variety of fibres, yarns and fabrics both in woven and nonwoven types are used in the field of filtration techniques. The innovative applications of textile filtration fabrics is widely accepted in the pharmaceutical industry in the process of separation of liquids, gases, powders and suspensions involved in the filtration processes. Textile materials in any form play an important role the industria
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Guérineau, Julia, Jollan Ton, and Mariia Zhuldybina. "Screen Printing Conductive Inks on Textiles: Impact of Plasma Treatment." Sensors 25, no. 13 (2025): 4240. https://doi.org/10.3390/s25134240.

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Textile-based wearable devices are rapidly gaining traction in the Internet of Things paradigm and offer distinct advantages for data collection and analysis across a wide variety of applications. Seamlessly integrating electronics in textiles remains a technical challenge, especially when the textiles’ essential properties, such as comfort, breathability, and flexibility, are meant to be preserved. This article investigates screen printing as a textile post-processing technique for electronic integration, and highlights its versatility, cost-effectiveness, and adaptability in terms of design
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Faruq, Omar, Saima Mahjabin, Narayan Chandra Nath, and Preanka Kabiraj. "Electronic smart textiles: new possibilities in textile industry in Bangladesh." Современные инновации, системы и технологии - Modern Innovations, Systems and Technologies 4, no. 4 (2024): 0401–25. http://dx.doi.org/10.47813/2782-2818-2024-4-4-0401-0425.

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Manufacturing has made significant advances this century across all technical and technological domains. In the race for this kind of growing, textiles compete. An interesting development in the textile and apparel sectors is smart textiles. Intelligent textiles are capable of sensing, processing, and interpreting a wide range of impulses and reactions, whether they come from electrical, chemical, biological, magnetic, or other sources. Three categories may be used to categorize the amount of intelligence: bright materials, dynamic creative clothes, and passively intelligent clothing. The five
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Banck-Burgess, Johanna. "‘Nothing like Textiles’: Manufacturing Traditions in Textile Archaeology." Światowit 56, no. 1 (2019): 13–22. http://dx.doi.org/10.5604/01.3001.0012.8451.

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Textiles are evaluated mainly in regard to their visual appearance and technical features of textile production. From a modern point of view, it is their optical perception that is most often displayed in reconstructions. This, however, can rarely be achieved due to the poor and fragmentary preservation of archaeological textiles, which hinders gathering basic information about details of the production technique. Sources illustrating garments or putative textile patterns are often additionally consulted to achieve a better understanding of the textiles. Over the past two decades, the author h
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STJEPANOVIČ, Zoran, Andrej CUPAR, Razvan RADULESCU, and Andreja RUDOLF. "USING STEM PRINCIPLES FOR UNDERSTANDING SMART TEXTILES’ SOLUTIONS – THE SLOVENIAN EXPERIENCE." TEXTEH Proceedings 2019 (November 5, 2019): 224–27. http://dx.doi.org/10.35530/tt.2019.58.

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The contribution gives an overview of the Erasmus+ project Smart textiles for STEM training – Skills4Smartex, funded by the European Commission. Presented are main objectives, aims and expected results, focused on experiences, gained through the first year’s project activities’ in Slovenia. The project aims to improve the knowledge, skills and employability of students in the fields, related to STEM (Science, Technology, Engineering, Mathematics) by providing appropriate training tools to understand multidisciplinary work through smart textiles. The main objectives of the project are: (1) Crea
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Folić, Radomir, and Damir Zenunović. "Textile reinforced concrete." Tekstilna industrija 71, no. 3 (2023): 13–25. http://dx.doi.org/10.5937/tekstind2303013f.

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Textile-reinforced concrete (TRC) is a reinforced concrete, where steel reinforcement is replaced with textiles or fibers. Textile reinforcement is a material consisting of natural or synthetic singular technical fibres processed into yarns or rovings which are woven into multi-axial textile fabrics having an open mesh or grid structure. In the paper an overview of tests results related to mechanical properties, deformation properties and durability characteristics of textile meshs are presented. Applications of different textiles as reinforcement in TRC is analyzed through some realized proje
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Ojstršek, Alenka, Olivija Plohl, Selestina Gorgieva, et al. "Metallisation of Textiles and Protection of Conductive Layers: An Overview of Application Techniques." Sensors 21, no. 10 (2021): 3508. http://dx.doi.org/10.3390/s21103508.

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The rapid growth in wearable technology has recently stimulated the development of conductive textiles for broad application purposes, i.e., wearable electronics, heat generators, sensors, electromagnetic interference (EMI) shielding, optoelectronic and photonics. Textile material, which was always considered just as the interface between the wearer and the environment, now plays a more active role in different sectors, such as sport, healthcare, security, entertainment, military, and technical sectors, etc. This expansion in applied development of e-textiles is governed by a vast amount of re
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Nemailal, Tarafder. "Defence Textiles Types with Materials and Methods of Manufacturing-A Review." Journal of Industrial Mechanics 4, no. 2 (2019): 25–33. https://doi.org/10.5281/zenodo.3361358.

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Textiles always have an important role in providing huge support to the defence personnel in various ways. It has played a vital role in providing protection to certain extent to the soldiers. Modern days defence is dealing with high performance textiles. Functional textiles have wide applications in defence. Examples of such textiles are like parachute fabric, three layer breathable fabric, camouflage printed fabric, flame retardant fabric, Thermoplastic Polyurethane Urethanes (TPU) coated fabric, etc. It is a great challenge to the system designers for defence departments to satisfy the conf
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Patti, Antonella, Francesco Costa, Marta Perrotti, Domenico Barbarino, and Domenico Acierno. "Polyurethane Impregnation for Improving the Mechanical and the Water Resistance of Polypropylene-Based Textiles." Materials 14, no. 8 (2021): 1951. http://dx.doi.org/10.3390/ma14081951.

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Commercial waterborne polyurethane (PU) dispersions, different in chemistry and selected on the basis of eco-friendly components, have been applied to a common polypropylene (PP)-based woven fabric. Impregnation has been chosen as a textile treatment for improving the features of basic technical textiles in light of potential applicability in luggage and bag production. The effect of drying method, performed under conditions achieved by varying the process temperature and pressure, on the features of the treated textiles, has been verified. The prepared specimens were characterized in terms of
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Lüling, Claudia, Petra Rucker-Gramm, Agnes Weilandt, et al. "Advanced 3D Textile Applications for the Building Envelope." Applied Composite Materials 29, no. 1 (2021): 343–56. http://dx.doi.org/10.1007/s10443-021-09941-8.

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AbstractWithin the field of textile construction, textiles are traditionally used either as decorative elements in interior design or as flat textiles in tensile-stressed lightweight constructions (roofs, temporary buildings, etc.). Technical textiles made of glass or carbon fibers are now also used as steel substitutes in concrete construction. There, flat textiles are also used as lost formwork or shaping semi-finished products. Applications for 3D textiles and in particular spacer textiles have so far only been investigated as part of multilayer constructions in combination with other eleme
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Betancourt Chavez, Diego, Eduardo Santiago Suarez Abril, Andrea Goyes Balladares, and Juan Paredes Chicaiza. "Technical instructions for textile materials used in tensile surface structures." Medwave 23, S1 (2023): eUTA333. http://dx.doi.org/10.5867/medwave.2023.s1.uta333.

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Introducción Este proyecto surge de la necesidad de conocer los principios utilizados en el diseño estructural con materiales textiles. Estas estructuras, que consisten en materiales textiles tensados por cables, se utilizan cada vez más en la construcción de techos y cerramientos debido a sus cualidades positivas, como su bajo peso y la capacidad de cubrir grandes espacios. Sin embargo, la selección del material adecuado para estas construcciones es uno de los aspectos menos estudiados a nivel local y nacional. Por lo tanto, se pretende determinar los aspectos más relevantes para la selección
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PARASKA, OLGA, КATERYNA PODOLINA, LUBOS HES, and HRYSTYNA KOVTUN. "ANALYSIS OF SOCIO-ECONOMIC, TECHNOLOGICAL, ENVIRONMENTAL CHARACTERISTICS OF THE LIFE CYCLE OF TEXTILE PRODUCTS." Herald of Khmelnytskyi National University. Technical sciences 307, no. 2 (2022): 153–58. http://dx.doi.org/10.31891/2307-5732-2022-307-2-153-158.

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The article analyzes the socio-economic, technological, ecological characteristics of the life cycle of textiles, their impact on the environment and human health. According to the results, the directions of safe manufacture and use of textile products in order to preserve natural resources and human health are proffered. Analysis of socio-economic, technological, ecological characteristics of the life cycle of textile products showed that 45% of textile products can be reused, 30% are suitable for processing into technical textiles, 20% – textile fibers. Only 5% of used textile products are w
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Simpson, Elizabeth, Mary W. Ballard, G. Asher Newsome, and Brendan Burke. "King Midas’s Textiles: Dyeing and Weaving Technology in Ancient Phrygia." Textile Museum Journal 50, no. 1 (2023): 4–31. http://dx.doi.org/10.1353/tmj.2023.a932848.

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Abstract: Many civilizations have left behind evidence of wonderful textiles exhibiting advanced weaving techniques and a variety of colors. It has been the task of textile historians, weavers, technologists, and chemists to investigate the extant finds. For ancient Phrygian textiles of the ninth–eighth centuries bce, this approach has been upended. The colorants in the largest royal burial at Gordion, Tumulus MM (for “Midas Mound”), were biologically disassociated from the textiles they once colored, which had degraded inside the tomb. Some years earlier, a fire had engulfed the City Mound at
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Abishova, A. S. "Investigation of the structural parameters of combined weaves for the manufacture of formresistant knitwear." Journal of Almaty Technological University 148, no. 2 (2025): 200–209. https://doi.org/10.48184/2304-568x-2025-2-200-209.

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The study of ways and technologies for obtaining shape–resistant textiles in textile production is an urgent and important scientific and technical problem. Shape stability for textiles is a complex indicator reflecting operational and technological properties. To study the features of technology and methods for producing competitive textiles from form-resistant textile fabrics, the following tasks were set: analysis of the type of raw materials for form-resistant textiles, study of methods and technology for producing form-resistant textiles, analysis of ways to increase shape stability for f
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