Relevant bibliographies by topics / Textiles

Academic literature on the topic 'Textiles'

Author: Grafiati
Published: 4 June 2021
Last updated: 18 May 2024

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Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Journal articles on the topic "Textiles":

1

Primc, Gregor, Rok Zaplotnik, Alenka Vesel, and Miran Mozetič. "Mechanisms Involved in the Modification of Textiles by Non-Equilibrium Plasma Treatment." Molecules 27, no. 24 (December 19, 2022): 9064. http://dx.doi.org/10.3390/molecules27249064.

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Plasma methods are often employed for the desired wettability and soaking properties of polymeric textiles, but the exact mechanisms involved in plasma–textile interactions are yet to be discovered. This review presents the fundamentals of plasma penetration into textiles and illustrates mechanisms that lead to the appropriate surface finish of fibers inside the textile. The crucial relations are provided, and the different concepts of low-pressure and atmospheric-pressure discharges useful for the modification of textile’s properties are explained. The atmospheric-pressure plasma sustained in the form of numerous stochastical streamers will penetrate textiles of reasonable porosity, so the reactive species useful for the functionalization of fibers deep inside the textile will be created inside the textile. Low-pressure plasmas sustained at reasonable discharge power will not penetrate into the textile, so the depth of the modified textile is limited by the diffusion of reactive species. Since the charged particles neutralize on the textile surface, the neutral species will functionalize the fibers deep inside the textile when low-pressure plasma is chosen for the treatment of textiles.
2

Gonzales Arnao, Walter. "ARQUITECTURA INCA A TRAVES DE SUS TEXTILES PERU– FAUA/UNI." Revista Cientifica TECNIA 24, no. 2 (February 8, 2017): 5. http://dx.doi.org/10.21754/tecnia.v24i2.38.

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Proponemos una mirada a los textiles incas como soporte planímetro de su territorio e inducir a reflexionar sobre las probables aplicaciones de los textiles incas en arquitectura y poner en evidencia a los ojos de los diseñadores, arquitectos e ingenieros, la hipótesis del valor y aplicación de los textiles incas en la representación planimetría de la tridimensionalidad del mundo material como lo concebían. Ensayar ideas sobre los usos del arte de los telares y su influencia en la arquitectura Inca. Utilizar este conocimiento milenario es un instrumento de inspiración de los futuros arquitectos. Palabras clave.- Arte textil inca, Arquitectura, Revalorar tecnología textil originaria, Reflexión estética textil, Aplicación actual como inspiración. ABSTRACTWe propose a look at incas textiles and planimetric support of its territory an Inducing reflection on the possible applications of textiles in architecture incas, and bring out the eyes of designers, architects and engineers with the hypothesis of the value and application of incas textiles in representing three-dimensional surveying of the material world as conceived. Test ideas about the uses of the art of weaving and its influence on Inca architecture. Use this ancient knowledge an instrument of inspiration for future architects. Keywords.- Inca textile art, Architecture, Textile technology reassessment, Aesthetic reflection textile, Current application as inspiration
3

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 durch eine gezielt integrierte Elektronik möglich. Der weltweite Markt für Smart Textiles wird bis 2031 etwa 1,3 Mrd. US-Dollar umfassen, so Prognosen von IDTechEx. Voraussetzung dafür ist, dass sich die Verbindung aus Textil und Elektronik effizient herstellen lässt und ausreichend technologische Flexibilität für unterschiedliche Anwendungsszenarien bietet – vom körpernahen Einsatz in Bekleidung oder Medizintextilien bis hin zu architektonischen Elementen.
4

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 (July 21, 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 induced with magneto-responsive textiles, the temperature increase in tissue-mimicking phantoms depended on several factors, such as the type of basic textile material, the concentration of magnetic nanoparticles deposited on the textile’s surface, and the number of layers covering the phantom. The values of temperature elevation, achieved with the use of magnetic textiles, are sufficient for potential application in magnetic hyperthermia therapies and as heating patches or bandages.
5

Barcalde, Sol, and Carolina Morales. "Estrategias pedagógicas para “acortar las distancias”: curso virtual de técnicas de remoción de manchas en textiles." Intervención 1, no. 27 (September 30, 2023): 268–93. http://dx.doi.org/10.30763/intervencion.283.v1n27.62.2023.

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En el ámbito de la conservación textil sudamericana la escasez de cursos en español y la dificultad para vincularse con otros profesionales en la comunidad internacional son desafíos que se enfrentan en el intento de actualizar los conocimientos en el área. Con esta premisa, el Comité Nacional de Conservación Textil (CNCT), institución que reúne a profesionales afines a la conservación e investigación del patrimonio textil de Chile y de otros países del Cono Sur, gestó la iniciativa de organizar, con novedosos métodos de aplicación, un curso de técnicas de remoción de manchas en textiles. Esta RESEÑA narra la experiencia como participantes en torno de aquél, titulado Disolver o remover para resolver. Curso virtual de conservación sobre la limpieza localizada en textiles. ___________ In the field of South American textile conservation, the lack of courses in Spanish and the difficulty of connecting with other professionals in the international community are challenges faced in the attempt to update knowledge within the area. With this premise, the Comité Nacional de Conservación Textil (CNCT, National Textile Conservation Committee)—an institution that brings together professionals related to the conservation and investigation of the textile heritage of Chile and other countries of the Southern Cone—developed the initiative to organize a course on textile stain removal techniques with innovative application methods. This REVIEW presents the experience of the participants on such a course, titled Disolver o remover para resolver. Curso virtual de conservación sobre la limpieza localizada en textiles (Dissolve or Remove to Resolve. Virtual Conservation Course on Localized Cleaning on Textiles).
6

Wang, Yang. "Research on Flexible Capacitive Sensors for Smart Textiles." Journal of Physics: Conference Series 2181, no. 1 (January 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. Starting from the current state of smart textile research, the article explains the promotion of new material technology to the research of smart textiles. Focus on the technical improvement of capacitive sensing equipment based on flexible fabrics, and find a sensing fabric structure with lower hysteresis, fast response time, good repeatability and stability through design experiments.
7

Jang, Hyun-Seok, Min Soo Moon, and Byung Hoon Kim. "Electronic Textiles Fabricated with Graphene Oxide-Coated Commercial Textiles." Coatings 11, no. 5 (April 22, 2021): 489. http://dx.doi.org/10.3390/coatings11050489.

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Demand for wearable and portable electronic devices has increased, raising interest in electronic textiles (e-textiles). E-textiles have been produced using various materials including carbon nanotubes, graphene, and graphene oxide. Among the materials in this minireview, we introduce e-textiles fabricated with graphene oxide (GO) coating, using commercial textiles. GO-coated cotton, nylon, polyester, and silk are reported. The GO-coated commercial textiles were reduced chemically and thermally. The maximum e-textile conductivity of about 10 S/cm was achieved in GO-coated silk. We also introduce an e-textile made of uncoated silk. The silk-based e-textiles were obtained using a simple heat treatment with axial tension. The conductivity of the e-textiles was over 100 S/cm.
8

ABDEL-KAREEM, OMAR. "Evaluating the Combined Efficacy of Polymers with Fungicides for Protection of Museum Textiles against Fungal Deterioration in Egypt." Polish Journal of Microbiology 59, no. 4 (2010): 271–80. http://dx.doi.org/10.33073/pjm-2010-041.

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Fungal deterioration is one of the highest risk factors for damage of historical textile objects in Egypt. This paper represents both a study case about the fungal microflora deteriorating historical textiles in the Egyptian Museum and the Coptic museum in Cairo, and evaluation of the efficacy of several combinations of polymers with fungicides for the reinforcement of textiles and their prevention against fungal deterioration. Both cotton swab technique and biodeteriorated textile part technique were used for isolation of fungi from historical textile objects. The plate method with the manual key was used for identification of fungi. The results show that the most dominant fungi isolated from the tested textile samples belong to Alternaria, Aspergillus, Chaetomium, Penicillium and Trichoderma species. Microbiological testing was used for evaluating the usefulness of the suggested conservation materials (polymers combined with fungicides) in prevention of the fungal deterioration of ancient Egyptian textiles. Textile samples were treated with 4 selected polymers combined with two selected fungicides. Untreated and treated textile samples were deteriorated by 3 selected active fungal strains isolated from ancient Egyptian textiles. This study reports that most of the tested polymers combined with the tested fungicides prevented the fungal deterioration of textiles. Treatment of ancient textiles by suggested polymers combined with the suggested fungicides not only reinforces these textiles, but also prevents fungal deterioration and increases the durability of these textiles. The tested polymers without fungicides reduce the fungal deterioration of textiles but do not prevent it completely.
9

Rotzler, Sigrid, and Martin Schneider-Ramelow. "Washability of E-Textiles: Failure Modes and Influences on Washing Reliability." Textiles 1, no. 1 (May 21, 2021): 37–54. http://dx.doi.org/10.3390/textiles1010004.

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E-textiles, hybrid products that incorporate electronic functionality into textiles, often need to withstand washing procedures to ensure textile typical usability. Yet, the washability—which is essential for many e-textile applications like medical or sports due to hygiene requirements—is often still insufficient. The influence factors for washing damage in textile integrated electronics as well as common weak points are not extensively researched, which makes a targeted approach to improve washability in e-textiles difficult. As a step towards reliably washable e-textiles, this review bundles existing information and findings on the topic: a summary of common failure modes in e-textiles brought about by washing as well as influencing parameters that affect the washability of e-textiles. The findings of this paper can be utilized in the development of e-textile systems with an improved washability.
10

Simegnaw, Abdella Ahmmed, Benny Malengier, Gideon Rotich, Melkie Getnet Tadesse, and Lieva Van Langenhove. "Review on the Integration of Microelectronics for E-Textile." Materials 14, no. 17 (September 6, 2021): 5113. http://dx.doi.org/10.3390/ma14175113.

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Modern electronic textiles are moving towards flexible wearable textiles, so-called e-textiles that have micro-electronic elements embedded onto the textile fabric that can be used for varied classes of functionalities. There are different methods of integrating rigid microelectronic components into/onto textiles for the development of smart textiles, which include, but are not limited to, physical, mechanical, and chemical approaches. The integration systems must satisfy being flexible, lightweight, stretchable, and washable to offer a superior usability, comfortability, and non-intrusiveness. Furthermore, the resulting wearable garment needs to be breathable. In this review work, three levels of integration of the microelectronics into/onto the textile structures are discussed, the textile-adapted, the textile-integrated, and the textile-based integration. The textile-integrated and the textile-adapted e-textiles have failed to efficiently meet being flexible and washable. To overcome the above problems, researchers studied the integration of microelectronics into/onto textile at fiber or yarn level applying various mechanisms. Hence, a new method of integration, textile-based, has risen to the challenge due to the flexibility and washability advantages of the ultimate product. In general, the aim of this review is to provide a complete overview of the different interconnection methods of electronic components into/onto textile substrate.
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You might also be interested in the extended bibliographies on the topic 'Textiles' for particular source types:
Journal articles Dissertations / Theses Books

Dissertations / Theses on the topic "Textiles":

1

Hyer, Maren Clegg. "Textiles and textile imagery in Old English literature." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1998. http://www.collectionscanada.ca/obj/s4/f2/dsk1/tape11/PQDD_0013/NQ41444.pdf.

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Shams, Glorianne Pionati. "Some minor textiles in antiquity." Göteborg : P. Åström, 1987. http://catalogue.bnf.fr/ark:/12148/cb38912890q.

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3

Berglin, Lena. "Interactive Textile Structures : Creating Multifunctional Textiles based on Smart Materials." Doctoral thesis, Högskolan i Borås, Institutionen Textilhögskolan, 2008. http://urn.kb.se/resolve?urn=urn:nbn:se:hb:diva-3490.

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Textiles of today are materials with applications in almost all our activities. We wear clothes all the time and we are surrounded with textiles in almost all our environments. The integration of multifunctional values in such a common material has become a special area of interest in recent years. Smart Textile represents the next generation of textiles anticipated for use in several fashion, furnishing and technical textile applications. The term smart is used to refer to materials that sense and respond in a pre-defined manner to environmental stimuli. The degree of smartness varies and it is possible to enhance the intelligence further by combining these materials with a controlling unit, for example a microprocessor. As an interdisciplinary area Smart Textile includes design spaces from several areas; the textile design space, the information technology design space and the design space of material science. This thesis addresses how Smart Textiles affect the textile design space; how the introduction of smart materials and information technology affects the creation of future textile products. The aim is to explore the convergence between textiles, smart materials and information technology and to contribute to providing a basis for future research in this area. The research method is based on a series of interlinked experiments designed through the research questions and the research objects. The experiments are separated into two different sections: interactive textile structures and health monitoring. The result is a series of basic methods for how interactive textile structures are created and a general system for health monitoring. Furthermore the result consists of a new design space, advanced textile design. In advanced textile design the focus is set on the relation between the different natures of a textile object: its physical structure and its structure in the context of design and use.
4

BHAT, KAILASH. "ELECTROWETTING TEXTILES - A NEW PARADIGM FOR TUNING OF TEXTILE WETTABILITY." University of Cincinnati / OhioLINK, 2007. http://rave.ohiolink.edu/etdc/view?acc_num=ucin1186679134.

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Veja, Priti. "An investigation of integrated woven electronic textiles (e-textiles) via design led processes." Thesis, Brunel University, 2015. http://bura.brunel.ac.uk/handle/2438/10528.

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Electronic textiles (e­‐textiles) are created by the amalgamation of electronics and textiles, where electronics are integrated into or onto fabric substrates. Woven textiles are specifically considered in this thesis to integrate electronics into textiles' orthogonal architecture. This thesis investigates 'How can the weaving process be manipulated to make woven e-­textiles with integrated electronics?' The methodological approach taken is practice based research carried out via a technical materials approach and creative craft methods. An investigation of woven e-­textiles through design led practice and woven expertise is presented. Previously, woven e-­textiles have been investigated either via technical material approaches, (where the main emphasis remains on function) or via creative craft methods, (which emphasise experimental forms, manipulate integration methods and apply craft based knowledge). Both of these approaches have presented only limited investigation of unobtrusive integrated electronics in woven e-­textiles, and woven structures have not been fully utilised to support the integration. The research applies reflective practice through a design process model; this is based on the researcher's previous weaving expertise and designing methods. The work investigates how woven construction may be manipulated to develop novel integrated woven e-­textiles. It was found that five woven approaches were particularly of value for electronics integration. These were the use of double cloth, the integration of multiple functions into the textiles as part of the weaving, the use of complex weaving techniques to attach and integrate components, the use of inlay weft weaving and the manipulation of floats (free floating threads). The thesis makes original contributions to knowledge, including identification of key stages in the woven e-­textile design process, identification and application of advanced weaving techniques to facilitate integrated woven e-­textiles, and compilation of a systematic record of woven e-­‐textile techniques as a technical woven repository. Underpinning design principles that influence the developed e-­textile outcomes are identified. A range of woven e-­textile samples are designed and made. Three specific examples including an actuator ('RGB colour mixer'), a circuit ('corrugated pleat LED v2') and a soft module ('battery holder module v4'), are described in detail to illustrate their development using the e-­textile design process model. The knowledge gained has potential to be applied to industrial woven processes for e-­textiles.
6

Raubenheimer, Hendrieka. "WARP + WEFT : translating textiles into interior architecture - in search for inspiration and continuation of African textile traditions." Diss., University of Pretoria, 2012. http://hdl.handle.net/2263/30222.

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WARP and WEFT is a textile making guild, intricately woven into KNOOP, the proposed Clothing and Consumer Science building for the University of Pretoria. This building is situated in Hatfield next to the railway line, in close proximity to the Gautrain station and Rissik Station. KNOOP was designed in 2008 by Korine Stegmann in fulfilment of her MArch(Prof) at the University of Pretoria. Therefore, the building in which the intervention is proposed is, to date, only an architectural proposal and has not yet been built. The project was initiated due to a fascination with textiles and the relevance of textiles in interior architecture. This fascination with textiles is ascribed to the following: The first intriguing aspect of textiles is the structure and the underlying construction principles of textiles. The second aspect is the unique character of textiles compared to other building materials. Another interesting notion is the current international textile trend and current re-focus on textiles as a construction material after a long period of being neglected. The current hype about textiles is ascribed to the tactile qualities of textiles, which opposes an increasing movement towards virtualism. The raw and organic production process of handmade textiles is desirable and opposes automated production. Similarly to the Arts and Crafts movement, designers are once more interested in handmade products. Fourthly, textiles used in architecture has the intriguing ability to create an architecture which better relates to fashion in terms of fashion’s ability to easily change and adapt; fashion’s fleeting nature. Lastly, handmade textiles of a specific region have the ability to convey the identity of that specific region. This is a crucial ability to resist globalization and monotony in cultural identity. Appropriately, the fascination of this dissertation is with traditional African handmade textiles and its relevance in interior architecture. The contemporary unbuilt building was selected to demonstrate the value of a collaborative approach between an architect and interior architect prior to construction. The analysis of the architectural proposal shows that the interior architect can effectively recognize the strengths and weaknesses of a building from an interior perspective and enhance and improve these aspects. The aim is also to show that two programmes can function collaborative in one building and that intervention is possible within a building with a fixed programme. The site was selected due to the location and framework it falls within. The location of the site allows for exposure due to the pedestrian demand on the site. Also, the site is advantageously located within close proximity to main transportation nodes. The site falls within the extended Arcadia Arts and Cultural Corridor. The vision for this corridor is a lively and multicultural precinct which hosts a variety of arts and cultural facilities. The vision for these facilities is to portray the zest of local culture, especially to those disembarking the Gautrain. The textile making guild, WARP + WEFT is an important project within this precinct, due to the core concept of the guild to celebrate African textiles. The aim of the guild is to produce contemporary woven textiles which portray the identity of traditional African woven textiles. The vision for WARP + WEFT within the precinct is to exhibit textiles, expose the textile making processes and to create a unique African textile experience for both the public and the users of the guild. The interior intervention will celebrate African textiles by demonstrating how textiles are used to solve and embrace aspects identified through the analysis of the architectural proposal. These aspects include acoustic absorption, solar screening, adding softness, texture and colour to an environment predominantly defined by cold, hard, smooth and monotone surfaces, as well as providing versatile branding elements. The use of textiles in the interior intervention introduces the unique design question of how to design with textiles for a textile related programme, opposed to textiles being used for another programme, such as a theatre or a hotel. It is a matter of “textiles for textiles” instead of “textiles for music” or “textiles for sleeping”. The solution to this unique design problem is to differentiate between spaces which celebrate textiles by acting as a background or blank canvas for the exhibition and production of textiles and spaces which celebrate textiles by becoming textile-like. To create these spatial variations, the exclusive use of textiles is not sufficient. Textiles need to be translated into interior architecture which will be achieved through the following five methods: Translation through metaphor, translation through structure, interpretation of actual textiles, engagement through text and the translation of the unique qualities of textiles. Thus, the aim of the investigation is to celebrate textiles through the application of textiles and through the translation of textiles in interior architecture.
Dissertation MInt(Prof)--University of Pretoria, 2012
Architecture
MInt(Prof)
Unrestricted
7

Thompson, Amanda J. "Textiles as indicators of Hopewellian culture burial practices." The Ohio State University, 2003. http://rave.ohiolink.edu/etdc/view?acc_num=osu1054507830.

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Vikova, Martina. "Photochromic textiles." Thesis, Heriot-Watt University, 2011. http://hdl.handle.net/10399/2439.

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This thesis describes a new investigation into the relationship between the developed colour intensity of photochromic textiles and the time of UV exposure and also the time of relaxation. As a result of this relationship the potential of flexible textilebased sensor constructions which might be used for the identification of radiation intensity is demonstrated. In addition the differences between photochromic pigment behaviour in solution and incorporated into prints on textiles are demonstrated. Differences in the effect of the spectral power distributions of light sources on the photochromic response are also examined. Bi-exponential functions, which are used in optical yield (Oy) calculations, have been described to provide a good description of the kinetics of colour change intensity of photochromic pigments, giving a good fit. The optical yield of the photochromic reaction Oy is linearly related to the intensity of illumination E. The optical yield obtained from the photochromic reaction curves are described by a kinetic model, which defines the rate of colour change initiated by external stimulus of UV light. Verification of the kinetic model is demonstrated for textile sensors with photochromic pigments applied by textile printing and by fibre mass dyeing. The thesis also describes a unique instrument developed by author, which measures colour differences ΔE* and spectral remission curves derived from photochromic colour change simultaneously with UV irradiation. In this thesis the photochromic behaviour of selected pigments in three different applications (type of media – textile prints, non-woven textiles and solution) is investigated.
9

Kharchenko, Zoya. "Smart textiles." Thesis, Київський національний університет технологій та дизайну, 2019. https://er.knutd.edu.ua/handle/123456789/13180.

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Nilsson, Linnéa. "Textile influence : exploring the role of textiles in the product design process." Licentiate thesis, Högskolan i Borås, Institutionen Textilhögskolan, 2014. http://urn.kb.se/resolve?urn=urn:nbn:se:hb:diva-3716.

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Textile materials and textile design are a part of countless products in our surroundings, as well as of diverse design fields and industries, with very different material traditions and working methods. Textile materials and industry have undergone many changes during recent decades, in terms of how and where textiles are produced, and what textiles can be and do; in much the same way, the design practices that textiles are involved in have also developed. What these diverse and evolving design contexts in which textiles are involved in have in common is that textile materials and textile design decisions somehow meet the rest of the design during a design process. The aim of this thesis is to add to our understanding of the relationship between textiles and products in the design process, and to explore the roles that textile design plays when designing textile products, the roles they can come to play when textiles become more complex and offer new means of functionality and expressiveness, for example through smart textile technology. This thesis presents two types of result: Firstly, descriptions of textile product design processes that highlight the wide range of roles that textiles can play in the textile product design processes of today, accentuate how textile materials and design decisions can influence both what can be designed and the design process, and describe some of the additional complexities that come with designing and designing with smart textiles. These examples are presented in the appended papers, and are the outcome of an observation of students who were designing textile products and collaborative, practice-based design research projects. Secondly, this thesis presents a theoretical framework which aims to offer a broad perspective on the relationship between textile design and the product design process, with the intention of opening up for reflection on how we design, and can design, with textiles. The framework focuses on how textile design decisions and textile materials participate in the process, and to what degree they influence the development of the design; this includes methods, questions, etc. that can be used to explore and define this dynamic. One of the main points of the framework is the importance of the textile influence in textile product design processes; the specific qualities of textiles as a design material - the considerations, possibilities, and challenges, which influence both the design of the product and the process of designing it. This includes not only the textiles in the final design, but also the textiles that, in other ways, feature in this process.
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Books on the topic "Textiles":

1

Institution, British Standards. Textiles: Determination of thickness of textiles and textile products. London: B.S.I., 1987.

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2

Gonseth-Favre, Pierrette. Pierrette Gonseth-Favre: Textiles = Textilien. Lausanne: Ed. Vie Art Cite, 1987.

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Marín-Aguilera, Beatriz, and Stefan Hanß. In-Between Textiles, 1400–1800. Nieuwe Prinsengracht 89 1018 VR Amsterdam Nederland: Amsterdam University Press, 2023. http://dx.doi.org/10.5117/9789463729086.

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In-Between Textiles is a decentred study of how textiles shaped, disrupted, and transformed subjectivities in the age of the first globalisation. The volume presents a radically cross-disciplinary approach that brings together world-leading anthropologists, archaeologists, art historians, conservators, curators, historians, scientists, and weavers to reflect on the power of textiles to reshape increasingly contested identities on a global scale between 1400 and 1800. Contributors posit the concept of “in-between textiles,” building upon Homi Bhabha’s notion of in-betweenness as the actual material ground of the negotiation of cultural practices and meanings; a site identified as the battleground over strategies of selfhood and the production of identity signs troubled by colonialism and consumerism across the world. In-Between Textiles establishes cutting-edge conversations between textile studies, critical cultural theory, and material culture studies to examine how textiles created and challenged experiences of subjectivity, relatedness, and dis/location that transformed social fabrics around the globe.
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Jørgensen, Lise Bender. Forhistoriske textiler i Skandinavien =: Prehistoric Scandinavian textiles. København: Det Kongelige Nordiske oldskriftselskab, 1986.

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Hosack, Karen. Textiles. Chicago, IL: Raintree, 2008.

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Doney, Meryl. Textiles. London: Franklin Watts, 1997.

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Janes, Susan Niner. Textiles. New York: Children's Press, 1998.

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Jakab, Cheryl. Textiles. North Mankato, MN: Smart Apple, 2006.

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Hosack, Karen. Textiles. Oxford: Heinemann Library, 2008.

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Black, Sue. Textiles. Barnsley: Open College of the Arts, 1994.

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Book chapters on the topic "Textiles":

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Paradiso, Rita, Nicola Taccini, and Giannicola Loriga. "Textile Sensing and e-Textiles (Smart Textiles)." In The Engineering Handbook of Smart Technology for Aging, Disability, and Independence, 673–92. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2008. http://dx.doi.org/10.1002/9780470379424.ch36.

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Mao, Ningtao. "Textile Materials for Protective Textiles." In High Performance Technical Textiles, 107–57. Chichester, UK: John Wiley & Sons, Ltd, 2019. http://dx.doi.org/10.1002/9781119325062.ch5.

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Mostafizur Rahman, Md, Md Shamsuzzaman, Dip Das, Md Abdus Shahid, and Mohammad Bellal Hoque. "Introduction to Textiles and Textile Fibers." In Advanced Technology in Textiles, 1–29. Singapore: Springer Nature Singapore, 2023. http://dx.doi.org/10.1007/978-981-99-2142-3_1.

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Malinauskiene, Laura, and Kristina Morgardt-Ryberg. "Textiles." In Quick Guide to Contact Dermatitis, 183–88. Berlin, Heidelberg: Springer Berlin Heidelberg, 2016. http://dx.doi.org/10.1007/978-3-662-47714-4_15.

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Nussinovitch, A. "Textiles." In Hydrocolloid Applications, 312–27. Boston, MA: Springer US, 1997. http://dx.doi.org/10.1007/978-1-4615-6385-3_19.

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Zarach, Stephanie. "Textiles." In Debrett’s Bibliography of Business History, 228–39. London: Palgrave Macmillan UK, 1987. http://dx.doi.org/10.1007/978-1-349-08984-0_47.

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Westman, Annabel. "Textiles." In Interior Finishes & Fittings for Historic Building Conservation, 105–23. Oxford, UK: Wiley-Blackwell, 2011. http://dx.doi.org/10.1002/9781444344837.ch9.

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Hatch, K. L., and H. I. Maibach. "Textiles." In Handbook of Occupational Dermatology, 622–36. Berlin, Heidelberg: Springer Berlin Heidelberg, 2000. http://dx.doi.org/10.1007/978-3-662-07677-4_79.

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Isaksson, Marléne, and Laura Malinauskiene. "Textiles." In Contact Dermatitis, 1–23. Cham: Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-319-72451-5_77-1.

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Faltermeier, Robert B. "Textiles." In An Easy Guide to Care for Sculpture and Antique Art Collections, 47–54. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-08897-6_5.

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Conference papers on the topic "Textiles":

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Soleimani, Manuchehr. "Development of Starin Gauges Using Electrically Active Textiles With Knitting Technology for Medical Applications." In ASME 2008 9th Biennial Conference on Engineering Systems Design and Analysis. ASMEDC, 2008. http://dx.doi.org/10.1115/esda2008-59046.

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Current generation of textiles, including technical textiles are passive. However, the next generation of textiles will have the ability to monitor its environment and interact accordingly in order to accomplish a pre-programmed functionality. One of the solutions for incorporating the above components into a textile structure is to create electrically active zones within the structure, whose electrical characteristics could vary due to an environmental change or whose structural properties could be changed by the application of an electrical signal, for example change of dimensions due to the flow of an electrical current in the electrically active area. Generally textiles are made out of materials of very high electrical resistance and therefore these structures can be considered as materials with good electrical insulating properties. In this paper we are presenting application of electrically active textiles for strain gauge application. Electromechanical tests shows the chractersitics of electronic textile for strain gauge application.
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Bashir, Asad, and Abigail R. Clarke-Sather. "Reuse Potential of Used Textiles for American Industries." In ASME 2019 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/detc2019-98521.

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Abstract Increasing the recovery of textiles from municipal solid waste (MSW) is important for improving environmental sustainability. In 2015, over 10.5 million tons of textile waste was landfilled, which is 7.6% of total landfilled MSW according to the U.S. EPA. For all materials, recycling in the U.S. has increased over the past decade to 25.8% of the weight of the waste generated, textile recycling is below this level at 15.3%. This research quantifies the availability of used textiles by material type from Goodwill of Delaware (Goodwill-DE), a thrift store franchise, between 2012 and 2014. It examines the feasibility of recycling this amount of available discarded textiles, specifically cotton, into U.S. industrial subsectors that traditionally use new cotton textiles. A hybrid product model was created using EIO-LCA to compare economic and environmental impacts in the cut and sew apparel, airplane and automotive seating, upholstered furniture, and textile bag manufacturing industrial subsectors. Economic impacts on supply purchases and profits were considered. Environmental impacts in energy use and CO2 equivalent emissions were examined. As a result, utilizing all of Goodwill-DE’s annual discarded cotton textiles by the cut and sew apparel industrial subsectors would have positive impacts in terms of supply purchase and energy savings and reduction in CO2 equivalent emissions, but negative impacts on profits. Supply purchase savings are greater than the profit loss, resulting in a net economic gain for the cut and sew apparel industrial subsectors. Of the seven industrial subsectors considered, the U.S. cut and sew apparel industries would benefit the most from utilizing used cotton textiles.
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Dubova, Ilze, Agnija Apine, Dace Grauda, Dalius Butkauskas, Inga Lashenko, and Līga Jankevica. "Adaptation of methods for the determination of biodegradation of bio-textiles with amber particles." In 79th International Scientific Conference of the University of Latvia. University of Latvia, 2022. http://dx.doi.org/10.22364/iarb.2021.07.

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One of the criteria for bio-textiles is the potential for biodegradation. Our goal was to adapt methods for the determination of biodegradation of bio-textiles containing amber particles. We adapted methods EN ISO 11721-1: 2001 and ISO 11721-2: 2003 developed for the study of interaction of cellulose – containing textiles and microorganisms. To determine the changes of fabrics, the mechanical properties and level of biodegradation were examined. Experiments revealing level of biodegradation of bio-textile were carried out at the Institute of Biology, University of Latvia while mechanical properties were tested at the Scientific Laboratory of Mechanics and Bio-textiles of the Institute of Mechanics and Mechanical Engineering, Riga Technical University. The study was financially supported by the EUREKA project E!11170 “Innovative multifunctional bio-textile, integrated with silica dioxide and succinate development, and its impact on biosystems” (IFSITEX).
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Radulescu, Ionrazvan, Carmen Ghituleasa, Emilia Visileanu, Radu Popescu, Marius Iordanescu, and Ladislava Zaklova. "BRANCH-RELATED TERMS FOR TEXTILE PROFESSIONALS IN BUSINESS AND TRADE." In eLSE 2013. Carol I National Defence University Publishing House, 2013. http://dx.doi.org/10.12753/2066-026x-13-275.

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Proper adaptation to industry trends represents nowadays one of the key success factors. The textile industry is one of the most dynamic industries, with strong market requirements and links to tradition in Europe. Due to the harsh international competition a shift in the textile industry in Europe has been produced from clothing-apparel sector to technical textiles sector. The technical textiles are meant for various applications (like agriculture, personal protection, medicine, environment etc.) and involve a high level of knowledge in textile machinery and high added value for the finished products. One of the main issues stated in the Strategic Research Agenda of the European Technology Platform for Textiles and Clothing (EURATEX*, 2006) is the move from commodities to specialty products with flexible high-tech processes, which is a development direction for the future of the European textile industry. The strong developments of textile international business bring new demand ? to have a Multilanguage flexible tool for branch-related terms. Businessman are often good in trade but without professional knowledge. They have to describe technical aspects, but do not know the proper expression. In order to help them were accomplished the Leonardo da Vinci-TOI projects Fashion School I and II and a new proposal is in preparation for the 2013 Call ? GUIDETEX. Within the Fashion School projects I and II an on-line explanatory dictionary in 16 European language versions was accomplished (www.texsite.info). This dictionary includes 2000 branch expressions with definitions in the textile-clothing field. A brief summary of the projects results show that after 3 years form the project end, the average visitation of the portal is of 49109 visits each month. As target group of the project were firstly businessman who deal with textiles and clothes, students of vocational education and professionals who export their products. The 2013 GUIDETEX proposal envisages the enlargement of the portal with branch-related terms in technical textiles. Several professionals in the textile industry do need a re-orientation of their business towards high-added-value products in technical textiles, as set by the EURATEX strategy. This is one of the means for supporting the knowledge-based European industry business and trade.
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Hertleer, Carla, Johanna Louwagie, Cedric Cochrane, and Marilyne Rochery. "AN E-LEARNING COURSE ON SMART TEXTILES ENABLED BY TRITEX." In eLSE 2013. Carol I National Defence University Publishing House, 2013. http://dx.doi.org/10.12753/2066-026x-13-268.

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The TRITex project (Transfer of Research and Innovations in Textiles)frames in the Interreg IV programme which stimulates cross-regional cooperation between France, the Walloon provinces and Flandres. The TRITex partners are the Flemish Department of Textiles of Ghent University and ENSAIT, a French engineering school.They collaborate to promote the use of communication and information technologies for teaching in order to diffuse knowledge in the field of smart textiles. The main goal of the TRITexproject is to develop ane-learningcourse which is remotelyavailable through a digital platform from Ghent University. The e-learning course consists of two modules, the first one on Functional and Smart Textile Materials, and the second one, building on the knowledge acquired in the first module, on Smart Textile Systems. The entire course gives the trainee a profound insight in the working principals of smart textiles and is completed with examples of prototypes and commercially available products. Throughout the course, online interaction with the teachers of the course is possible. At the end, the acquired information is tested through an extensive assessment at the end of each module. To our knowledge, there is no equivalent resource available on the net in this research area, while there is a need to it because of the continuous emergence of smart textiles. The target group for this e-learning course on smart textiles is people working in the textile industry wanting to sharpen their knowledge on new and advanced technologies. The first module has been officially launched in December 2012, while the second module is to be launched in April 2013.
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Granberry, Rachael, Brad Holschuh, and Julianna Abel. "Experimental Investigation of the Mechanisms and Performance of Active Auxetic and Shearing Textiles." In ASME 2019 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/smasis2019-5661.

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Abstract Anisotropic textiles are commonly used in wearable applications to achieve varied bi-axial stress-strain behavior around the body. Auxetic textiles, specifically those that exhibit a negative Poisson’s ratio (v), likewise exhibit intriguing behavior such as volume increase in response to impact or variable air permeability. Active textiles are traditional textile structures that integrate smart materials, such as shape memory alloys, shape memory polymers, or carbon nanotubes, to enable spatial actuation behavior, such as contraction for on-body compression or corrugation for haptic feedback. This research is a first experimental investigation into active auxetic and shearing textile structures. These textile structures leverage the bending- and torsional-deformations of the fibers/filaments within traditional textile structures as well as the shape memory effect of shape memory alloys to achieve novel, spatial performance. Five textile structures were fabricated from shape memory alloy wire deformed into needle lace and weft knit textile structures. All active structures exhibited anisotropic behavior and four of the five structures exhibited auxetic behavior upon free recovery, contracting in both x- and y-axes upon actuation (v = −0.3 to −1.5). One structure exhibited novel shearing behavior, with a mean free angle recovery of 7°. Temperature-controlled biaxial tensile testing was conducted to experimentally investigate actuation behavior and anisotropy of the designed structures. The presented design and performance of these active auxetic, anisotropic, and shearing textiles inspire new capabilities for applications, such as smart wearables, soft robotics, reconfigurable aerospace structures, and medical devices.
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Immanuel, Sophia, and Baskar K. "Flexural Behaviour of Carbon Textile Reinforced Concrete (CTRC) Panel." In IABSE Congress, New Delhi 2023: Engineering for Sustainable Development. Zurich, Switzerland: International Association for Bridge and Structural Engineering (IABSE), 2023. http://dx.doi.org/10.2749/newdelhi.2023.1547.

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<p>Textile-reinforced concrete (TRC) is novel high performance composite material blooming in the 21st century globally. It can be used as not only strengthening material but as a structural load bearing component. This paper aims to investigate the flexural behaviour of carbon textile- reinforced concrete (CTRC) panel through four-point bending test. Optimising the mix using particle packaging for the TRC with grade of mix as M50 using binders were used for the study. Flexural strength and toughness were observed to improve with the increase of the number of textile layers. The textiles were manually prestressed the first-crack flexural stress and pre- cracking flexural stiffness of the CTRC. The results highlight that the behaviour of carbon textile reinforcement under pure flexure performs well with flexural cracks forming only at the pure bending zone. The flexural behaviour of only 4-layer textiles were limited to this study considering the over reinforced design criteria. Further, the performance can be enhanced while optimising the no of layers of textiles(i.e.) the minimum textile reinforcement percentage required in further research.</p>
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Čuk, Marjeta, Matejka Bizjak, Deja Muck, and Tanja Nuša Kočevar. "3D printing and functionalization of textiles." In 10th International Symposium on Graphic Engineering and Design. University of Novi Sad, Faculty of technical sciences, Department of graphic engineering and design,, 2020. http://dx.doi.org/10.24867/grid-2020-p56.

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3D printing is used to produce individual objects or to print on different substrates to produce multi-component products. In the textile industry, we encounter various 3D printing technologies in fashion design, functional apparel manufacturing (protective, military, sports, etc.), including wearable electronics, where textile material is functionalized. 3D printing enables the personalization of the product, which in the apparel industry can be transformed into the production of clothing or parts of clothing or custom accessories. Additive technology allows a more rational use of the material than traditional technologies. In the textile industry we meet different uses of it, one is the printing of flexible structures based on rigid materials, another is the printing with flexible materials and the third is the printing directly on textile substrate. All rigid, hard and soft or flexible materials can be integrated into the final design using 3D printing directly on the textile substrate. We speak of so-called multi-material objects and systems, which have many advantages, mainly in the increasing customization and functionalization of textiles or clothing. The article gives a broader overview of 3D printing on textiles and focuses mainly on the influence of different parameters of printing and woven fabric properties on the adhesion of 3D printed objects on the textile substrate. In our research we investigated the influence of twill weave and its derivate as well as different weft densities of the woven fabric on the adhesion of printed objects on textile substrate. Therefore, five samples of twill polyester/cotton fabrics were woven and their physical properties measured for this research. 3D objects were printed on textile substrates using the extrusion based additive manufacturing technique with polylactic acid (PLA) filament. Preliminary tests were carried out to define printing parameters and different methods of attaching the fabric to a printing bed were tested. T - Peel adhesion tests were performed on the Instron dynamometer to measure the adhesion between 3D printed objects and textile substrates.
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Palaniappan, Elavarasan. "Electric Mobility and Technical Textile Necessity." In WCX SAE World Congress Experience. 400 Commonwealth Drive, Warrendale, PA, United States: SAE International, 2023. http://dx.doi.org/10.4271/2023-01-0874.

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<div class="section abstract"><div class="htmlview paragraph">E-mobility is creating more challenges and great opportunities for automotive textile industries to bring out new textiles for light weight, more aesthetic, better feel, sustainable and biomaterial to meet the customer perception. Textiles allows a more design freedom to in terms of construction, weaving and wrapping solutions. A hard rough plastic surface could be transferred into a more pleasant soft touch surface by a simple wrapping with textiles. The introduction of electric vehicle will convert the car as more silent as it replaces the engine by motor and battery mechanism. The more silent is the car, the more silent is the BSR behavior of the material. This work discloses of a polyester textile developed to meet automotive lightweight to strength requirements with its new nonwoven construction for seat insert and bolster application which demands for high breaking strength, abrasion resistance, stretch and set and soiling resistance. This textile also studied for thermal resistance and sound dampening and results were analyzed using DSC, TGA and DMA analysis techniques. This paper also demands the requirements of advanced textiles for future mobility.</div></div>
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Zhang, Mei, Rebecca Stewart, and Nick Bryan-Kinns. "Empowering Textile and Fashion Designers with E-Textiles for Creative Expression." In E-Textiles 2023. Basel Switzerland: MDPI, 2024. http://dx.doi.org/10.3390/engproc2023052022.

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Reports on the topic "Textiles":

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Harmsen, Paulien, Carolijn Slottje, Michelle Baggerman, and Ellen Sillekens. Biological degradation of textiles : And the relevance to textile recycling. Wageningen: Wageningen Food & Biobased Research, 2021. http://dx.doi.org/10.18174/557073.

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Nikam, Jaee. Gaps, challenges and drivers for environmentally sustainable textile and garment manufacturing in India. Stockholm Environment Institute, May 2023. http://dx.doi.org/10.51414/sei2023.033.

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This paper provides an overview of the country’s manufacturing value chain of textiles and garments, and the status of sustainable manufacturing throughout these so-called upstream processes, from raw material procurement to ready-made garment production. After outlining the regulatory structure that influences the upstream textile and garments value chain in India, the author explores the challenges and drivers faced by textile manufacturers in India, along with providing policy suggestions and highlighting the opportunities for sustainable transitions.
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Oh, Ju Hyun, Aimee Martinez, Huaixuan Cao, Garrett George, Jared Cobb, Poonam Sharma, Lauren Fassero, et al. Radio frequency heating of washable conductive textiles for bacteria and virus inactivation. Engineer Research and Development Center (U.S.), January 2024. http://dx.doi.org/10.21079/11681/48060.

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The ongoing COVID-19 pandemic has increased the use of single-use medical fabrics such as surgical masks, respirators, and other personal protective equipment (PPE), which have faced worldwide supply chain shortages. Reusable PPE is desirable in light of such shortages; however, the use of reusable PPE is largely restricted by the difficulty of rapid sterilization. In this work, we demonstrate successful bacterial and viral inactivation through remote and rapid radio frequency (RF) heating of conductive textiles. The RF heating behavior of conductive polymer-coated fabrics was measured for several different fabrics and coating compositions. Next, to determine the robustness and repeatability of this heating response, we investigated the textile’s RF heating response after multiple detergent washes. Finally, we show a rapid reduction of bacteria and virus by RF heating our conductive fabric. 99.9% of methicillin-resistant Staphylococcus aureus (MRSA) was removed from our conductive fabrics after only 10 min of RF heating; human cytomegalovirus (HCMV) was completely sterilized after 5 min of RF heating. These results demonstrate that RF heating conductive polymercoated fabrics offer new opportunities for applications of conductive textiles in the medical and/or electronic fields.
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Bye, Elizabeth. We Are Textiles and Apparel. Ames: Iowa State University, Digital Repository, November 2015. http://dx.doi.org/10.31274/itaa_proceedings-180814-1159.

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King, William T. MURI/ARO Functionally Tailored Textiles. Fort Belvoir, VA: Defense Technical Information Center, August 2002. http://dx.doi.org/10.21236/ada412609.

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Nicolaisen, Karl-Oskar, and Heidi Belinda Bugge. Ecolabelled Textiles in the Nordic Countries. Nordic Council of Ministers, September 2018. http://dx.doi.org/10.6027/na2018-909.

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none,. Textiles Footprint, December 2010 (MECS 2006). Office of Scientific and Technical Information (OSTI), June 2010. http://dx.doi.org/10.2172/1218603.

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Dorado, Marianne C. TRIBE: Translating Tribal Tattooing into Textiles. Ames: Iowa State University, Digital Repository, 2014. http://dx.doi.org/10.31274/itaa_proceedings-180814-1026.

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Lee, Seung-Eun, and Jaeil Lee. Coauthorship in Clothing and Textiles Research. Ames: Iowa State University, Digital Repository, November 2016. http://dx.doi.org/10.31274/itaa_proceedings-180814-1519.

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Watson, David, David Palm, Frode Syversen, Olav Skogesal, and Jakob Pedersen. Fate and Impact of Used Textiles Exports. Nordic Council of Ministers, April 2016. http://dx.doi.org/10.6027/na2016-905.

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