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Journal articles on the topic 'Smart textiles'

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

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1

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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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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Thahani, Z. Rasmin. "Smart Textiles- On Review." International Journal of Applied and Structural Mechanics, no. 11 (September 2, 2021): 1–11. http://dx.doi.org/10.55529/ijasm11.1.11.

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Smart Textiles Are Intelligent Textile Structure That Can Sense And React To Environmental Stimuli, Which May Be Mechanical, Thermal, Chemical, Biological, And Magnetic Among Others. Research And Development Towards Wearable Textile-Based Personal Systems Allowing E.G. Health Monitoring, Protection & Safety, And Healthy Lifestyle Gained Strong Interest During The Last 10 Years. The Functionalities Include Aesthetic Appeal, Comfort, Textile Soft Display, Smart Controlled Fabric, Fantasy Design With Color Changing, Wound Monitoring, Smart Wetting Properties And Protection Against Extreme Var
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Popescu, Melania, and Camelia Ungureanu. "Green Nanomaterials for Smart Textiles Dedicated to Environmental and Biomedical Applications." Materials 16, no. 11 (2023): 4075. http://dx.doi.org/10.3390/ma16114075.

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Smart textiles recently reaped significant attention owing to their potential applications in various fields, such as environmental and biomedical monitoring. Integrating green nanomaterials into smart textiles can enhance their functionality and sustainability. This review will outline recent advancements in smart textiles incorporating green nanomaterials for environmental and biomedical applications. The article highlights green nanomaterials’ synthesis, characterization, and applications in smart textile development. We discuss the challenges and limitations of using green nanomaterials in
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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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Mohd Nawawi, MM, Khairul Azami Sidek, Amelia Wong Azman, and Fazli Mohd Nasir Nashrul. "Reliability of Electrocardiogram Signals during Feature Extraction Stage for Smart Textile Shirts." Journal of Physics: Conference Series 2071, no. 1 (2021): 012043. http://dx.doi.org/10.1088/1742-6596/2071/1/012043.

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Abstract Wearable smart textiles have garnered significant interest due to their high flexibility, reusability, convenience and ability to work on home-based, real-life and real-time monitoring. Wearable smart textiles are shirts with inbuilt textile sensors that enable electrocardiogram (ECG) data to be collected more comfortably and smoothly outside the laboratory and clinical environment for a continuous and longer duration for ECG data collection. However, the existing ECG wearable smart textile main challenge is maintaining the quality and reliability of data across multiple wearable smar
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He, Fang Rong. "Study on Manufacturing Technology of Phase Change Materials and Smart Thermo-Regulated Textiles." Advanced Materials Research 821-822 (September 2013): 130–38. http://dx.doi.org/10.4028/www.scientific.net/amr.821-822.130.

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Taking the advantages of the unique features of phase change materials (PCM),it is possible to fabricate smart thermoregulated textiles through the effective combination of PCM and textiles. In this study, the candidates of PCM and its requirements suitable for the textiles were summarized, various manufacturing technologies of microPCMs and smart thermo-regulated textiles were reviewed. For the applications on a large scale, further research need to be conducted in aspects including new types of PCM, stability and durability of smart textiles, the advanced fabricating technology, performance
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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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Moya-Jiménez, Roberto, Elizabeth Morales-Urrutia, Andrea Lara-Saltos, et al. "Materials in Technological-Wearable Devices for Health: Review and Perspective." Data and Metadata 4 (February 12, 2025): 200. https://doi.org/10.56294/dm2025200.

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The convergence between the textile industry and technology has revolutionized material design, enabling the development of smart textiles for wearable technological devices, especially in the healthcare sector. These devices, designed to continuously monitor physiological parameters and provide personalized support, have found in smart textiles an essential solution thanks to their properties of flexibility, comfort and adaptability, key to their prolonged use. This article examines the evolution of smart textiles from passive textiles, capable of responding to environmental stimuli, to ultra
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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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Cabral, Isabel, and António Pedro Souto. "Dynamic Qualities of Smart Textiles: Study of Stimuli Magnitude with Chromic Pigments." Solid State Phenomena 333 (June 10, 2022): 97–106. http://dx.doi.org/10.4028/p-se7xco.

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Smart textile behaviour encompasses changes over time, which are triggered upon a sensed stimulus. With a focus on dynamic qualities, this research sought to study how gradual and reversible transitions of smart textiles can be influenced by the activation variable – stimuli magnitude. Taking into account an analysis of different external stimuli for the same property change, the experimental work was conducted with Colour Change Materials, namely textiles screen printed with thermo, photo and hydrochromic pigments. The results attained demonstrate how stimuli magnitude can affect textile temp
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Lewis, Erin. "Between yarns and electrons: A method for designing electromagnetic expressions in woven smart textiles." Artifact 9, no. 1 (2022): 23.1–23.25. http://dx.doi.org/10.1386/art_00023_1.

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The design of woven smart textiles presents a discrepancy of scale where the designer works at the level of structural textile design while facets of the material express at scales beyond one’s senses. Without appropriate methods to address these unknown (or hidden) material dimensions, certain expressional domains of the textile are closed off from textile design possibilities. The aim of the research has been to narrow the gap that presents when one designs simultaneously at the scale of textile structure and electron flow in yarns. It does this by detailing a method for sensing, visualizing
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Allish S, Suthiksha. P, K M Pachiappan, R. Divya Sathiyam, and Saniya A. "A review on recent trends in smart textiles." World Journal of Advanced Research and Reviews 24, no. 1 (2024): 1824–28. http://dx.doi.org/10.30574/wjarr.2024.24.1.3103.

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Recent advancements in both domestic and international research have considerably enhanced the development of smart fibers and smart textile, which are now being increasingly integrated into the textile industry. Advanced textiles encompass five primary functions; sensors, data processing, actuators, storage and communication. These technologies must be effectively integrated into clothing, ensuring they meet essential requirements like comfort, durability, and resilience to routine maintenance. Designers engaged with traditional textiles might address challenges by integrating smart materials
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Allish, S., P. Suthiksha., M. Pachiappan K, Divya Sathiyam R., and A. Saniya. "A review on recent trends in smart textiles." World Journal of Advanced Research and Reviews 24, no. 1 (2024): 1824–28. https://doi.org/10.5281/zenodo.15045530.

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Recent advancements in both domestic and international research have considerably enhanced the development of smart fibers and smart textile, which are now being increasingly integrated into the textile industry. Advanced textiles encompass five primary functions; sensors, data processing, actuators, storage and communication. These technologies must be effectively integrated into clothing, ensuring they meet essential requirements like comfort, durability, and resilience to routine maintenance. Designers engaged with traditional textiles might address challenges by integrating smart materials
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15

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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Proesmans, Remko, Andreas Verleysen, Robbe Vleugels, Paula Veske, Victor-Louis De Gusseme, and Francis Wyffels. "Modular Piezoresistive Smart Textile for State Estimation of Cloths." Sensors 22, no. 1 (2021): 222. http://dx.doi.org/10.3390/s22010222.

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Smart textiles have found numerous applications ranging from health monitoring to smart homes. Their main allure is their flexibility, which allows for seamless integration of sensing in everyday objects like clothing. The application domain also includes robotics; smart textiles have been used to improve human-robot interaction, to solve the problem of state estimation of soft robots, and for state estimation to enable learning of robotic manipulation of textiles. The latter application provides an alternative to computationally expensive vision-based pipelines and we believe it is the key to
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17

Robaiyat, Md Alif. "A tiny analysis about the advancement in smart textile." Journal of Multidisciplinary Cases, no. 52 (July 12, 2025): 1–11. https://doi.org/10.55529/jmc.52.1.11.

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Smart textiles are also referred to as electronic textiles or e-textiles, which have emerged as any enabling technology dealing with active electronic elements integrated into conventional textile materials in several industries. This review article describes recent development about smart textiles toward their materials, applications, and challenges with respect to their development. Further synthesis of the findings from different research papers has established that smart textiles have huge potentials with regard to use cases in healthcare, sports, fashion, and environmental monitoring. It
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Affatato, Lorena, and Cosimo Carfagna. "Smart Textiles: A Strategic Perspective of Textile Industry." Advances in Science and Technology 80 (September 2012): 1–6. http://dx.doi.org/10.4028/www.scientific.net/ast.80.1.

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Comfort is a state of mind affected by many factors, and clothing has contributing to the well being of man, changing in some cases his customs. Since the origin, the primary functions of clothes have been of protection against cold or in general against environmental stimuli. New functions are required to modern textiles: wearing comfort, durability, cleaning properties, optimized functionality for specific applications (workwear, sportswear, medical wear). Smart and interactive textiles represent a budding interdisciplinary field that brings together specialists in information technology, mi
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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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Grancarić, Ana M., Ivona Jerković, Vladan Koncar, et al. "Conductive polymers for smart textile applications." Journal of Industrial Textiles 48, no. 3 (2017): 612–42. http://dx.doi.org/10.1177/1528083717699368.

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Smart textiles are fabrics able to sense external conditions or stimuli, to respond and adapt behaviour to them in an intelligent way and present a challenge in several fields today such as health, sport, automotive and aerospace. Electrically conductive textiles include conductive fibres, yarns, fabrics, and final products made from them. Often they are prerequisite to functioning smart textiles, and their quality determines durability, launderability, reusability and fibrous performances of smart textiles. Important part in smart textiles development has conductive polymers which are defined
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21

Ruckdashel, Rebecca R., Ninad Khadse, and Jay Hoon Park. "Smart E-Textiles: Overview of Components and Outlook." Sensors 22, no. 16 (2022): 6055. http://dx.doi.org/10.3390/s22166055.

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Smart textiles have gained great interest from academia and industries alike, spanning interdisciplinary efforts from materials science, electrical engineering, art, design, and computer science. While recent innovation has been promising, unmet needs between the commercial and academic sectors are pronounced in this field, especially for electronic-based textiles, or e-textiles. In this review, we aim to address the gap by (i) holistically investigating e-textiles’ constituents and their evolution, (ii) identifying the needs and roles of each discipline and sector, and (iii) addressing the ga
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Kongahage, Dharshika, and Javad Foroughi. "Actuator Materials: Review on Recent Advances and Future Outlook for Smart Textiles." Fibers 7, no. 3 (2019): 21. http://dx.doi.org/10.3390/fib7030021.

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Smart textiles based on actuator materials are of practical interest, but few types have been commercially exploited. The challenge for researchers has been to bring the concept out of the laboratory by working out how to build these smart materials on an industrial scale and permanently incorporate them into textiles. Smart textiles are considered as the next frontline for electronics. Recent developments in advance technologies have led to the appearance of wearable electronics by fabricating, miniaturizing and embedding flexible conductive materials into textiles. The combination of textile
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Ivanoska-Dacikj, Aleksandra, Lutz Walter, Karin Eufinger, et al. "Smart textiles: Paving the way to sustainability." Macedonian Journal of Chemistry and Chemical Engineering 43, no. 1 (2024): 149–64. http://dx.doi.org/10.20450/mjcce.2024.2821.

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As an emerging technology, smart textiles can bring solutions to many problems, but also create new ones, especially related to their disposal and their impact on the environment. That is why it is important to address this problem at this stage of technological development when smart textiles have not yet pervaded the mass markets. In this article, first, an attempt is made to understand the chronological development of smart textiles: the reasons for a weak breakthrough in the commercial markets throughout the decades, starting from the 1990s until today, but also the emergence of new drivin
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Fang, Yunsheng, Guorui Chen, Michael Bick, and Jun Chen. "Smart textiles for personalized thermoregulation." Chemical Society Reviews 50, no. 17 (2021): 9357–74. http://dx.doi.org/10.1039/d1cs00003a.

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This article provides a fundamental understanding of the physiology of body thermoregulation and the advances in thermoregulatory textile technologies, and a perspective on future textiles for personalized thermoregulation.
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Júnior, Heitor Luiz Ornaghi, Roberta Motta Neves, Francisco Maciel Monticeli, and Lucas Dall Agnol. "Smart Fabric Textiles: Recent Advances and Challenges." Textiles 2, no. 4 (2022): 582–605. http://dx.doi.org/10.3390/textiles2040034.

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Textiles have been used in our daily life since antiquity in both economies and social relationships. Nowadays, there has never been a greater desire for intelligent materials. Smart fabric textiles with high-quality and high-performance fiber manufacturing with specific functions represented by clothing and apparel brands (such as astronaut suits that can regulate temperature and control muscle vibrations) are becoming increasingly prominent. Product applications also extend from the field of life clothing to the medical/health, ecology/environmental protection, and military/aerospace fields.
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Divya K Siva, S. "Application of Smart Textiles." International Journal of Science and Research (IJSR) 12, no. 6 (2023): 1583–85. http://dx.doi.org/10.21275/sr23614155028.

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Hossain, Md Raihan, Md Raju Ahmed, and Md Shamim Alam. "Smart textiles." Textile Progress 55, no. 2 (2023): 47–108. http://dx.doi.org/10.1080/00405167.2023.2250651.

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Tadesse, Melkie Getnet, Carmen Loghin, Ionuț Dulgheriu, and Emil Loghin. "Comfort Evaluation of Wearable Functional Textiles." Materials 14, no. 21 (2021): 6466. http://dx.doi.org/10.3390/ma14216466.

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Wearable E-textile systems should be comfortable so that highest efficiency of their functionality can be achieved. The development of electronic textiles (functional textiles) as a wearable technology for various applications has intensified the use of flexible wearable functional textiles instead of wearable electronics. However, the wearable functional textiles still bring comfort complications during wear. The purpose of this review paper is to sightsee and recap recent developments in the field of functional textile comfort evaluation systems. For textile-based materials which have close
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KHALID QURESHI, AMNA. "UTILIZING SMART TEXTILES IN INTERIOR DESIGN TO REPLACE CONVENTIONAL ARCHITECTURAL FINISHES." TEXTEH Proceedings 2019 (November 5, 2019): 105–9. http://dx.doi.org/10.35530/tt.2019.24.

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Many architects and designers coincide that fabric structures have an imperative role to play in creating an ecofriendly future. In recent years, the use of smart textiles has been particularly popular in the construction practices. These are hailed as environmentally friendly, deliberated as architecturally aesthetic and are usually cost effective. There is a growing demand for hybrid textile materials that combine strength and functionality in a lightweight product at a competitive price. These materials are developed with advanced technical interventions. This paper aims to conceptualize th
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Razarenkow, Katarzyna. "Smart fibres in forensics." Issues of forensic science, no. 316 (2022): 31–42. http://dx.doi.org/10.34836/pk.2022.316.4.

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n a publication titled „Smart fibres in forensics” contains collected information on modern textile products such as smart textiles and their connection to special-purpose garments such as military or medical clothing. According to the literature, specialised modifications are quite often used in such clothing, giving the textiles special properties, for example, antiseptic, i.e. bactericidal and fungicidal. This publication presents the main applications of modified fibres and interesting areas of this field that in the future may pose a real challenge in the work of experts involved in the f
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Józefczak, Arkadiusz, Katarzyna Kaczmarek, Rafał Bielas, Jitka Procházková, and Ivo Šafařík. "Magneto-Responsive Textiles for Non-Invasive Heating." International Journal of Molecular Sciences 24, no. 14 (2023): 11744. http://dx.doi.org/10.3390/ijms241411744.

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Magneto-responsive textiles have emerged lately as an important carrier in various fields, including biomedical engineering. To date, most research has been performed on single magnetic fibers and focused mainly on the physical characterization of magnetic textiles. Herein, from simple woven and non-woven textiles we engineered materials with magnetic properties that can become potential candidates for a smart magnetic platform for heating treatments. Experiments were performed on tissue-mimicking materials to test the textiles’ heating efficiency in the site of interest. When the heat was ind
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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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Weber, Mandy. "3 Sticktechnologien zur Herstellung von Smart Textiles." Technische Textilien 64, no. 5 (2021): 154–55. http://dx.doi.org/10.51202/0323-3243-2021-5-154.

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Die Verbraucher haben ein ungebremstes Verlangen nach intelligenten „Alltagshelfern“ in allen Lebensbereichen entwickelt. Das Spektrum reicht von smarten Lautsprechern über die Steuerung ihres Smart Home bis hin zu mit immer mehr Assistenten ausgestatteten Fahrzeugen. Dieser Trend ist ebenfalls im Textilbereich zu beobachten. Die Erwartungen an ein Textil haben sich gewandelt und die gesteigerten Anforderungen verlangen nach intelligenten Lösungen. Multifunktionalität setzen die Verbraucher heute voraus, sie wollen etwa mithilfe von Textilen kommunizieren können. Diese smarten Textilien werden
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Offermann-van Heek, Julia, Philipp Brauner, and Martina Ziefle. "Let’s Talk about TEX—Understanding Consumer Preferences for Smart Interactive Textile Products Using a Conjoint Analysis Approach." Sensors 18, no. 9 (2018): 3152. http://dx.doi.org/10.3390/s18093152.

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Interactive textiles are reaching maturity. First technology augmented textiles in form of clothes and furnitures are becoming commercially available. In contrast to the close link between technological development and innovations, future users’ acceptance and usage of such interactive textiles has not been integrated sufficiently, yet. The current study investigates future users’ consumer behavior and acceptance of interactive textiles using a scenario-based conjoint analysis study, which was presented in an online questionnaire ( n = 324 ). Two prototypical interactive textiles were focused
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Degenstein, Lauren M., Dan Sameoto, James D. Hogan, Asad Asad, and Patricia I. Dolez. "Smart Textiles for Visible and IR Camouflage Application: State-of-the-Art and Microfabrication Path Forward." Micromachines 12, no. 7 (2021): 773. http://dx.doi.org/10.3390/mi12070773.

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Protective textiles used for military applications must fulfill a variety of functional requirements, including durability, resistance to environmental conditions and ballistic threats, all while being comfortable and lightweight. In addition, these textiles must provide camouflage and concealment under various environmental conditions and, thus, a range of wavelengths on the electromagnetic spectrum. Similar requirements may exist for other applications, for instance hunting. With improvements in infrared sensing technology, the focus of protective textile research and development has shifted
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Luprano, Jean. "Progress in Interactive Textiles for Health Monitoring." Advances in Science and Technology 86 (September 2012): 1–8. http://dx.doi.org/10.4028/www.scientific.net/ast.86.1.

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Interactive textiles have the capability to interact with the user, which means they embed sensors, local intelligence and actuators to achieve this goal. This interactivity requires to dispose of smart textiles, made of smart materials, completing the often used wording “Smart fabrics and interactive textiles” or SFIT. The term smart is used to refer to materials that sense and respond in a pre-defined way to environmental stimuli. Heath monitoring is an important field of application for smart textiles. Results and sometimes products such as shirts measuring electrocardiogram, respiration or
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Lingayat, Mrunmayee. "Shape Memory Materials and its Use in the Textile Industry." INTERANTIONAL JOURNAL OF SCIENTIFIC RESEARCH IN ENGINEERING AND MANAGEMENT 08, no. 04 (2024): 1–5. http://dx.doi.org/10.55041/ijsrem30905.

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Shape memory materials (SMMs), including shape memory alloys (SMAs) and shape memory polymers (SMPs), possess the remarkable ability to retain and recover significant programmed deformations triggered by external stimuli. This paper explores the utilization of SMAs and SMPs in developing smart textiles, discussing their applications and advancements in various textile sectors. Additionally, recent research on the integration of SMAs and SMPs into fabric structures for responsive textiles is examined, highlighting their potential for enhanced functionality and performance. Keywords: Shape memor
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Sugathan, Manju, and Martin Douglas Hendry. "Market Forecasts and Personal Adoption of Smart Textiles in Fitness Sector." International Journal of Technology Diffusion 8, no. 3 (2017): 57–75. http://dx.doi.org/10.4018/ijtd.2017070104.

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The basic concept of smart textiles consists of textile structures that can sense and react to different stimuli from their environment. While forecasts indicate how this sector has the potential to grow in the future, a gap remains for smart textiles to become commercially viable. Growth in consumerism and consumption of services and experiences has led to innovative products that satisfy higher order needs including ideas, sensory and emotional fulfilment, cultural experiences and entertainment. The aim of the paper is to understand smart textiles in this context and to identify factors that
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Gong, Zidan, Ziyang Xiang, Xia OuYang, et al. "Wearable Fiber Optic Technology Based on Smart Textile: A Review." Materials 12, no. 20 (2019): 3311. http://dx.doi.org/10.3390/ma12203311.

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Emerging smart textiles have enriched a variety of wearable technologies, including fiber optic technology. Optic fibers are widely applied in communication, sensing, and healthcare, and smart textiles enable fiber optic technology to be worn close to soft and curved human body parts for personalized functions. This review briefly introduces wearable fiber optic applications with various functions, including fashion and esthetics, vital signal monitoring, and disease treatment. The main working principles of side emission, wavelength modulation, and intensity modulation are summarized. In addi
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Ivanoska-Dacikj, Aleksandra, Yesim Oguz-Gouillart, Gaffar Hossain, et al. "Advanced and Smart Textiles during and after the COVID-19 Pandemic: Issues, Challenges, and Innovations." Healthcare 11, no. 8 (2023): 1115. http://dx.doi.org/10.3390/healthcare11081115.

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The COVID-19 pandemic has hugely affected the textile and apparel industry. Besides the negative impact due to supply chain disruptions, drop in demand, liquidity problems, and overstocking, this pandemic was found to be a window of opportunity since it accelerated the ongoing digitalization trends and the use of functional materials in the textile industry. This review paper covers the development of smart and advanced textiles that emerged as a response to the outbreak of SARS-CoV-2. We extensively cover the advancements in developing smart textiles that enable monitoring and sensing through
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Sajovic, Irena, Mateja Kert, and Bojana Boh Podgornik. "Smart Textiles: A Review and Bibliometric Mapping." Applied Sciences 13, no. 18 (2023): 10489. http://dx.doi.org/10.3390/app131810489.

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According to ISO/TR 23383, smart textiles reversibly interact with their environment and respond or adapt to changes in the environment. The present review and bibliometric analysis was performed on 5810 documents (1989–2022) from the Scopus database, using VOSviewer and Bibliometrix/Biblioshiny for science mapping. The results show that the field of smart textiles is highly interdisciplinary and dynamic, with an average growth rate of 22% and exponential growth in the last 10 years. Beeby, S.P., and Torah, R.N. have published the highest number of papers, while Wang, Z.L. has the highest numb
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Nithya, N. "A Synopsis of Smart Textiles for Sportswear." ComFin Research 12, S2-Feb (2024): 205–11. http://dx.doi.org/10.34293/commerce.v12is1-feb.7583.

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Engaging in sports during hot and muggy weather can lead to a variety of heat-related illnesses that can have either mild or fatal consequences. The creation and manufacture of sportswear has become increasingly important with the growth of contemporary sports, particularly in many challenging and hazardous sports. The most crucial element is the choice of fiber fabrics since it affects efficiency and performance while guaranteeing safety and physical comfort. Globally, there has been a surge in demand for smart textiles and materials in recent years. E-textiles and smart clothing can serve as
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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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Lee, Ju-Hee, and Min-Woo Han. "Design and Evaluation of Smart Textile Actuator with Chain Structure." Materials 16, no. 16 (2023): 5517. http://dx.doi.org/10.3390/ma16165517.

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Textiles composed of fibers can have their mechanical properties adjusted by changing the arrangement of the fibers, such as strength and flexibility. Particularly, in the case of smart textiles incorporating active materials, various deformations could be created based on fiber patterns that determine the directivity of active materials. In this study, we design a smart fiber-based textile actuator with a chain structure and evaluate its actuation characteristics. Smart fiber composed of shape memory alloy (SMA) generates deformation when the electric current is applied, causing the phase tra
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Dolez, Patricia I. "Energy Harvesting Materials and Structures for Smart Textile Applications: Recent Progress and Path Forward." Sensors 21, no. 18 (2021): 6297. http://dx.doi.org/10.3390/s21186297.

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A major challenge with current wearable electronics and e-textiles, including sensors, is power supply. As an alternative to batteries, energy can be harvested from various sources using garments or other textile products as a substrate. Four different energy-harvesting mechanisms relevant to smart textiles are described in this review. Photovoltaic energy harvesting technologies relevant to textile applications include the use of high efficiency flexible inorganic films, printable organic films, dye-sensitized solar cells, and photovoltaic fibers and filaments. In terms of piezoelectric syste
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Stylios, George K. "Novel Smart Textiles." Materials 13, no. 4 (2020): 950. http://dx.doi.org/10.3390/ma13040950.

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The sensing/adapting/responding, multifunctionality, low energy, small size and weight, ease of forming, and low-cost attributes of SMART textiles and their multidisciplinary scope offer numerous end uses in medical, sports and fitness, military, fashion, automotive, aerospace, built environment, and energy industries. The research and development for these new and high-value materials crosses scientific boundaries, redefines material science design and engineering, and enhances quality of life and our environment. “Novel SMART Textiles” is a focused special issue that reports the latest resea
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Weng, Wei, Peining Chen, Sisi He, Xuemei Sun, and Huisheng Peng. "Smart Electronic Textiles." Angewandte Chemie International Edition 55, no. 21 (2016): 6140–69. http://dx.doi.org/10.1002/anie.201507333.

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Vu, Chi Cuong, and Jooyong Kim. "Highly Sensitive E-Textile Strain Sensors Enhanced by Geometrical Treatment for Human Monitoring." Sensors 20, no. 8 (2020): 2383. http://dx.doi.org/10.3390/s20082383.

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Electronic textiles, also known as smart textiles or smart fabrics, are one of the best form factors that enable electronics to be embedded in them, presenting physical flexibility and sizes that cannot be achieved with other existing electronic manufacturing techniques. As part of smart textiles, e-sensors for human movement monitoring have attracted tremendous interest from researchers in recent years. Although there have been outstanding developments, smart e-textile sensors still present significant challenges in sensitivity, accuracy, durability, and manufacturing efficiency. This study p
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Xiang, Chaoqun, Jianglong Guo, Rujie Sun, et al. "Electroactive Textile Actuators for Breathability Control and Thermal Regulation Devices." Polymers 11, no. 7 (2019): 1199. http://dx.doi.org/10.3390/polym11071199.

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Smart fabrics offer the potential for a new generation of soft robotics and wearable technologies through the fusion of smart materials, textiles and electrical circuitries. Conductive and stretchable textiles have inherent compliance and low resistance that are suitable for driving artificial muscle actuators and are potentially safer electrode materials for soft actuation technologies. We demonstrate how soft electroactive actuating structures can be designed and fabricated from conducting textiles. We first quantitatively analyse a range of stretchable conductive textiles for dielectric ela
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Meinander, Harriet. "Haptic Sensing in Intelligent Textile Development." Advances in Science and Technology 60 (September 2008): 123–27. http://dx.doi.org/10.4028/www.scientific.net/ast.60.123.

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The haptic properties of textiles are of crucial importance in most application areas and particularly for skin contact garments. Extensive research work has therefore been done both in defining the mechanical textile properties, which influence the haptic sensations, in measuring these textile properties, in defining procedures for subjective evaluation of the haptics of textiles, and in simulation of the properties in a virtual environment. In the development of new smart or intelligent textiles it is particularly important to consider the haptic properties. The introduction of non-textile e
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