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1
Xiao, Ya-Qian, and Chi-Wai Kan. "Review on Development and Application of 3D-Printing Technology in Textile and Fashion Design." Coatings 12, no. 2 (2022): 267. http://dx.doi.org/10.3390/coatings12020267.
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Three-dimensional printing (3DP) allows for the creation of highly complex products and offers customization for individual users. It has generated significant interest and shows great promise for textile and fashion design. Here, we provide a timely and comprehensive review of 3DP technology for the textile and fashion industries according to recent advances in research. We describe the four 3DP methods for preparing textiles; then, we summarize three routes to use 3DP technology in textile manufacturing, including printing fibers, printing flexible structures and printing on textiles. In addition, the applications of 3DP technology in fashion design, functional garments and electronic textiles are introduced. Finally, the challenges and prospects of 3DP technology are discussed.
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Li, Hong Mei. "New Technology of Ecological Textile Printing." Applied Mechanics and Materials 401-403 (September 2013): 856–58. http://dx.doi.org/10.4028/www.scientific.net/amm.401-403.856.
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As textile printing technology continues to improve, fabric printing changes from in a technical workshop into a science hall. Hitherto unknown achievement is being made. Printing technology is going towards environmental protection, saving energy and reducing consumption. Ecological printing is not only the status what textile development needs, but also the development trend of textiles in future. This paper focuses on the ecological printing and special printing technology.
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Özev, Mahmut-Sami, and Andrea Ehrmann. "Sandwiching textiles with FDM Printing." Communications in Development and Assembling of Textile Products 4, no. 1 (2023): 88–94. http://dx.doi.org/10.25367/cdatp.2023.4.p88-94.
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3D printing on textile fabrics has been investigated intensively during the last years. A critical factor is the adhesion between the printed polymer and the textile fabric, limiting the potential areas of application. Especially safety-related applications, e.g. stab-resistant textile/polymer composites, need to show reliable adhesion between both components to serve their purpose. Here we investigate the possibility of sandwiching textiles between 3D-printed layers, produced by fused deposition modeling (FDM). We show that adding nubs to the lower 3D-printed layers stabilizes the inner textile fabric and suggest future constructive improvements to further enhance the textile-polymer connection.
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Ntim, Charles K., Sophia P. Ocran, and Richard Acquaye. "Digital Textile Printing: A New Alternative to Short-Run Textile Printing in Ghana." International Journal of Technology and Management Research 2, no. 1 (2020): 60–65. http://dx.doi.org/10.47127/ijtmr.v2i1.51.
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This paper is a part of a broader research into textile design technology and trends across the world and their reflection on the local Ghanaian textile industry. It places conventional manual screen printing and digital textile printing technologies side by side and discusses the various drawbacks of screen printing as against the advantages of digital textile printing to illustrate a path for a wider consideration of the latter in Ghanaian small to medium scale textile production. Short-run textile printing commissions are the main source of jobs for small to medium scale textile producers in Ghana. And manual screen printing is the main process employed by these small-scale textile printers. However, screen printing has various layers of limitations such as poor registration of the design, stains, pinholes, colour correctness, colour consistency, colour smear, dye migration, scorching, improper curing, amongst others. These layers of limitations negatively affect the overall outcome of the prints. So, as it stands now, short-run textile printing commissions are either produced manually, of course, with several inconsistencies or outsourced to China and other countries at a higher production cost. This is because, the large-scale textile factories in Ghana could print a minimum of 2400 yards due to their machine settings, calibration and running cost to make the least returns. This study highlights some of the milestones in the development of digital textiles print machines and examines some of the key aspects of their tremendous production aptitudes for short-run textile commissions. The case study research method is used because data comes largely from documentation, archival records, interviews and physical artefacts.
 Keywords: Textile Design, Digital Textile Printing, Screen Printing, Short-run Prints.
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Mežinska, Silvija, Ilmārs Kangro, Edgars Zaicevs, and Gunta Salmane. "THE EFFECT OF 3D PRINTING ON A TEXTILE FABRIC." SOCIETY. INTEGRATION. EDUCATION. Proceedings of the International Scientific Conference 5 (May 20, 2020): 729. http://dx.doi.org/10.17770/sie2020vol5.5012.
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3D printing capabilities are also used in the fashion and textile industries. 3D printed textiles are a new opportunity to create an individual design. Traditional textile structures can be interpreted using 3D printing technologies and materials. One of the most important factors associated with the use of 3D printing technology is to reduce the impact of processing on the physical properties of textile fabrics. Availability of 3D printers at Rezekne Academy of Technologies (RTA) provides experimental work with fabrics of different thickness and fibres as well as different filaments. This study is based on the analysis of synthetic fibre cloth processing and the effect of 3D printing parameters on textile materials. By applying successive layers of materials, the interaction between 3D printing and textiles is studied. In terms of adhesion and stability, the best adhesion parameters for a particular type of fabric are determined by analysing the type of the fabric. The variance analysis method is used to process the research results.
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Goncu-Berk, Gozde. "3D Printing of Conductive Flexible Filaments for E-Textile Applications." IOP Conference Series: Materials Science and Engineering 1266, no. 1 (2023): 012001. http://dx.doi.org/10.1088/1757-899x/1266/1/012001.
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Electronic textiles (e-textiles) can incorporate conductive materials at all levels of integration, from fibers to yarns to fabric itself. There are many ways to connect the textile elements to electronic components with interconnect mechanisms from mechanical gripping to welding, to gluing, to printing, to embroidery, knitting, and weaving. 3D printing method offers the possibility of creating flexible and stretchable interconnects for e-textiles applications. This study explored 3D printing of flexible conductive filaments on fabric to create interconnects for hard electrical components as well as transmission lines and switches for electronic textile applications. NinjaTek Eel and Palmiga TPU based conductive filaments were printed on polyester knit fabric. Electrical characterization measurements as well as visual and haptic analysis of printed samples were conducted. The results showed that TPU based flexible conductive filaments offer possibilities of direct 3D printing onto textiles for electronic textile applications.
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Riello, Giorgio. "Asian knowledge and the development of calico printing in Europe in the seventeenth and eighteenth centuries." Journal of Global History 5, no. 1 (2010): 1–28. http://dx.doi.org/10.1017/s1740022809990313.
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AbstractFrom the seventeenth century, the brilliance and permanence of colour and the exotic nature of imported Asian textiles attracted European consumers. The limited knowledge of colouring agents and the general absence of textile printing and dyeing in Europe were, however, major impediments to the development of a cotton textile-printing and -dyeing industry in Europe. This article aims to chart the rise of a European calico-printing industry in the late seventeenth and eighteenth centuries by analysing the knowledge transfer of textile-printing techniques from Asia to Europe.
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Yong, Sheng, Meijing Liu, Abiodun Komolafe, John Tudor, and Kai Yang. "Development of a Screen-Printable Carbon Paste to Achieve Washable Conductive Textiles." Textiles 1, no. 3 (2021): 419–32. http://dx.doi.org/10.3390/textiles1030022.
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Conductive tracks are key constituents of wearable electronics and e-textiles, as they form the interconnective links between wearable electrical devices/systems. They are made by coating or printing conductive patterns or tracks on textiles or by weaving, knitting, or embroidering conductive yarns into textiles. Screen printing is a mature and cost-effective fabrication method that is used in the textile industry. It allows a high degree of geometric freedom for the design of conductive patterns or tracks. Current screen-printed conductive textiles have the limitations of low durability when washed or when placed under bending, and they typically require encapsulation layers to protect the printed conductor. This paper presents a printable paste formulation and fabrication process based on screen printing for achieving a flexible and durable conductive polyester-cotton textile using an inexpensive carbon as the conductor. The process does not require an interface, the smoothing of the textile, or an encapsulation layer to protect the conductor on the textile. A resistivity of 4 × 10−2 Ω·m was achieved. The textile remains conductive after 20 standard washes, resulting in the conductor’s resistance increasing by 140%. The conductive textile demonstrated less than ±10% resistance variation after bending for 2000 cycles.
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Savić, Luka, Anja Ludaš Dujmić, and Sanja Ercegović Ražić. "3D printed thermoplastic polymer screen for textile printing." Koža & obuća 74, no. 1 (2025): 16–20. https://doi.org/10.34187/ko.74.1.4.
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This study investigate the application of 3D printing technology in the design of textile printing screens using a thermoplastic polyurethane polymer (TPU, trade name Filaflex Gold), known for its flexibility, durability and adhesion properties. These properties make it suitable for the production of reusable screens that meet the requirements of modern textile printing. The process involves designing the printing screen using CAD software’s, preparing the file for 3D printing and optimizing parameters such as extruder temperature (215 – 250 °C) and printing speed. Using a 3D printer equipped for flexible filaments ensures accurate and reliable results. TPU printing screens are compatible with techniques such as screen-printing and hand painting. Thanks to their elasticity, they adapt to curved or irregular surfaces such as textiles, while their durability ensures multiple uses with minimal wear and tear. The method is cost-effective, sustainable and easy to implement on a range of production scales, from small workshops to industrial applications. This approach demonstrates the potential of combining 3D printing and advanced polymers to improve customization, reduce waste and increase efficiency in the design and manufacture of textiles.
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Jangra, Sakshi Verma Mona and Rani Navita. "Emerging Trends in Textile Auxiliaries." Science world a Monthly e magazine 5, no. 1 (2025): 6099–105. https://doi.org/10.5281/zenodo.14759953.
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The textile industry is facing important change due to technological innovations and a rising focus on sustainability. Textile auxiliaries, chemical substances that improve fabric properties, are increasingly important in this progression. Emerging in textile auxiliaries, including nanotechnology, digital printing, and smart textiles, are improving the properties of textiles while simultaneously reducing their environmental footprint. Manufacturers are switching to biodegradable and non-toxic materials, as well as nanotechnology for water repellent and antimicrobial qualities, and digital printing for efficient design. Smart fabrics are coming, including electronics that monitor moisture and temperature, increasing usefulness. This move not only enhances product quality but also tackles environmental problems, demonstrating a commitment to responsible production. The future of textile auxiliaries appears bright, as the industry continues to innovate, balancing consumer needs with environmental care.
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Sabyrkhanova, S. Sh, G. K. Yeldiyar, and B. Abzalbekuly. "Overview of plant extracts from the flora of the Kazakhstan for dyeing and printing textile materials." Mechanics and Technologies, no. 2 (June 30, 2024): 360–68. https://doi.org/10.55956/aitd1583.
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The use of natural raw materials in the process of production and sale of textiles represents such a promising direction, which is based on the principles of environmental sustainability, innovation and quality. The results of research show that rare extracts have a potential for application in textile industry not only for painting, but also for application of unique properties and design of textile materials, as well as environmental improvement characteristic production of textiles, reduction of the average volume and increase the price of finished products in the eyes of buyers. Currently, attention is paid to environmentally friendly and sustainable methods of dyeing and printing textile materials. In the Republic of Kazakhstan, interest in dyes obtained from plant extracts for dyeing and printing textiles has become an urgent problem, as the preservation and efficient use of natural resources is a priority task. This work is aimed at analyzing the main types of flora of Kazakhstan, their characteristics, possible advantages and limitations, and at understanding the possibilities and prospects of using plant extracts in the textile industry, studying the potential
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Eutionnat-Diffo, Prisca Aude, Yan Chen, Jinping Guan, Aurelie Cayla, Christine Campagne, and Vincent Nierstrasz. "Study of the Wear Resistance of Conductive Poly Lactic Acid Monofilament 3D Printed onto Polyethylene Terephthalate Woven Materials." Materials 13, no. 10 (2020): 2334. http://dx.doi.org/10.3390/ma13102334.
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Wear resistance of conductive Poly Lactic Acid monofilament 3D printed onto textiles, through Fused Deposition Modeling (FDM) process and their electrical conductivity after abrasion are important to consider in the development of smart textiles with preserved mechanical and electrical properties. The study aims at investigating the weight loss after abrasion and end point of such materials, understanding the influence of the textile properties and 3D printing process parameters and studying the impact of the abrasion process on the electrical conductivity property of the 3D printed conductive polymers onto textiles. The effects of the 3D printing process and the printing parameters on the structural properties of textiles, such as the thickness of the conductive Poly Lactic Acid (PLA) 3D printed onto polyethylene terephthalate (PET) textile and the average pore sizes of its surface are also investigated. Findings demonstrate that the textile properties, such as the pattern and the process settings, for instance, the printing bed temperature, impact significantly the abrasion resistance of 3D printed conductive Poly Lactic Acid (PLA) onto PET woven textiles. Due to the higher capacity of the surface structure and stronger fiber-to-fiber cohesion, the 3D printed conductive polymer deposited onto textiles through Fused Deposition Modeling process have a higher abrasion resistance and lower weight loss after abrasion compared to the original fabrics. After printing the mean pore size, localized at the surface of the 3D-printed PLA onto PET textiles, is five to eight times smaller than the one of the pores localized at the surface of the PET fabrics prior to 3D printing. Finally, the abrasion process did considerably impact the electrical conductivity of 3D printed conductive PLA onto PET fabric.
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Vodyashkin, Andrey A., Mstislav O. Makeev, and Pavel A. Mikhalev. "Inkjet Printing Is a Promising Method of Dyeing Polymer Textile Materials." Polymers 17, no. 6 (2025): 756. https://doi.org/10.3390/polym17060756.
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Inkjet printing is a universal method of direct application and application of various substances to the surface of materials. This technology is gaining popularity in various fields, from textile printing to microelectronics and biomedicine. In the textile industry, inkjet printing has been widely used for many years. In our approach, we systematized the main approaches to maintaining the quality of inkjet printing on various components of materials. We reported and analyzed methods for optimizing the rheological properties of paint to improve the colorimetric characteristics and color fastness on various fabrics. The paper presents surface tension and viscosity regulators, with the help of which the colorimetric indicators of the image on textiles can be improved. For each type of textile, individual modifiers were demonstrated that could most effectively improve the quality of the pattern. Particular attention was paid to the methods of modifying the surface of products, including both physical and chemical approaches. This section discusses an effective method of plasma treatment, which allows you to control the surface free energy for textile polymer materials. By controlling the surface tension of inkjet paints and the surface energy of the material, it is possible to achieve maximum adhesion, thereby significantly increasing the amount of paint per unit area of textile. Additionally, for similar purposes, the principles of chemical modification of the surface with various substances were considered. These methods enable control over the wettability of ink and adhesion to textiles of consistent composition. Additionally, we highlight the potential of thin, optically transparent polymer coatings as a promising strategy to enhance the efficiency of dyeing textile materials. The textile industry is rapidly developing, and the functionality of clothing is improving every year. Inkjet printing methods optimized for maximum accuracy and quality can serve as a significant alternative for applying images.
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MONTEIRO, Eva, Helder CARVALHO, Ana Maria ROCHA, Derya TAMA BIRKOCAK, and Helder PUGA. "ALGILAMA VE ELEKTRİK BAĞLANTISI İÇİN TEKSTİL ÜZERİNE ESNEK İLETKEN POLİMERLERİN 3D BASKISI." Tekstil ve Mühendis 29, no. 128 (2022): 315–21. http://dx.doi.org/10.7216/teksmuh.1222553.
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Additive manufacturing (AM) is a 3D printing technology that works by deposition of a material, layer by layer, creating 3D objects. The growth of these technologies has been exponential and the application of AM in the textile industry has also been a subject of increased interest in the past few years. The applications are not only for decorative purposes, but also for biomedical and other uses in e-textiles. However, a crucial point for making such assembly is the adhesion between the material and the textile substrate, as well as the premise of meeting demanding wash resistance requirements. This work aims to investigate the possibility of creating sensors by combining textiles with conductive polymeric filaments used in 3D printing. Merging the flexibility of use, mechanical properties and electrical conductivity of the polymeric filaments with the comfort and physical properties of the textiles can be a promising approach to create novel sensing structures. In this document, we give an overview of the recent state of the art of experimental research on adhesion in textile and polymer composites as well as an optimization of the printing parameters with a conductive filament, PI-ETPU. Some results from the printed samples in terms of print quality and electrical resistance are presented. Combining both topics, further work will include printing with conductive filament on textile substrates to study the possibly of creating sensing and electrical connections.
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FOBIRI, George Kwame, Adelaide TAKYIWAA, Charles FRIMPONG, Ebenezer Kofi HOWARD, and Solomon Marfo AYESO. "Dabbing Technique as a Means of Acquiring Images for Hand-screen Printing." International Journal of Conservation Science 15, no. 1 (2024): 801–14. http://dx.doi.org/10.36868/ijcs.2024.02.04.
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The art of screen printing largely depends on images captured from both natural and artificial sources. Obviously, with the upsurge of technology in the 21st century, images are easily captured with different kinds of cameras. Notwithstanding, creativity is propelled by a shift from normalcy from the artistic point of view. Innovative approaches to image acquisition for the conservation of textiles printing techniques, especially hand screen printing, can never be overemphasised. This study explores dabbing as an innovative image-capturing technique from found objects for textile printing with inspiration from the Rayograph technique by Man Ray. The Art studio-based research design under the Qualitative research method was employed for the study. Two approaches (Direct and Indirect dabbing) became significant. The studio exploration yielded to four articles comprising two printed fabrics for apparel purposes and two wall hangings for decorative purposes. A complement of the dabbing technique with screen printing was observed to be an innovative approach to the conservation of textile printing. It gives artists a great opportunity to utilise found objects in their surroundings that go a long way to minimize waste. The study recommends the Dabbing technique to textile design practitioners/learners as a technique worth-considering in textile design and printing.
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Weiser, Juergen, Friedrich-Wilhelm Raulfs, and Karl Siemensmeyer. "Digital Textile Printing." NIP & Digital Fabrication Conference 16, no. 1 (2000): 529–32. http://dx.doi.org/10.2352/issn.2169-4451.2000.16.1.art00030_2.
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Sitotaw, Dereje Berihun, Dustin Ahrendt, Yordan Kyosev, and Abera Kechi Kabish. "Additive Manufacturing and Textiles—State-of-the-Art." Applied Sciences 10, no. 15 (2020): 5033. http://dx.doi.org/10.3390/app10155033.
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The application of additive manufacturing, well known as 3D printing, in textile industry is not more totally new. It allows is giving significant increase of the product variety, production stages reduction, widens the application areas of textiles, customization of design and properties of products according to the type of applications requirement. This paper presents a review of the current state-of-the-art, related to complete process of additive manufacturing. Beginning with the design tools, the classical machinery building computer-aided design (CAD) software, the novel non-uniform rational B-spline (NURBS) based software and parametric created models are reported. Short overview of the materials demonstrates that in this area few thermoplastic materials become standards and currently a lot of research for the application of new materials is going. Three types of 3D printing, depending on the relation to textiles, are identified and reported from the literature—3D printing on textiles, 3D printing of flexible structures and 3D printing with flexible materials. Several applications with all these methods are reported and finally the main advantages and disadvantages of the 3D printing in relation to textile industry are given.
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Gorjanc, Marija, Ana Gerl, and Mateja Kert. "Screen Printing of pH-Responsive Dye to Textile." Polymers 14, no. 3 (2022): 447. http://dx.doi.org/10.3390/polym14030447.
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The development of pH-responsive textile sensors has attracted much interest in recent decades. Therefore, the aim of this study was to show that screen printing could be one of the possible techniques for development of pH-responsive textile. Several parameters that could influence the pH sensitivity and responsivity of a screen-printed textile with bromocresol green dye were studied, such as textile substrate (cotton, polyamide), printing paste composition, and type of fixation (heat and steaming). The change in mechanical and physical properties of the printed fabrics was tested according to the valid ISO, EN, or ASTM standards. The responsiveness of the printed samples to different pH values with the change in colour was evaluated spectrophotometrically. In addition, the colour fastness of the printed textiles to rubbing, washing, and light was also investigated. The results show that the textile responsiveness to pH change was successfully developed by flat screen-printing technique, which proves that the printing process could be one of the methods for the application of indicator dye to textiles. The application of the printing paste to cotton and polyamide fabrics resulted in an expected change in the mechanical and physical properties of the fabrics studied. The responsiveness of printed fabrics to the change of pH value depends on the type of fibres, the strength of dye–fibre interactions, and the wettability of the fabric with buffer solutions. The colour fastness of the printed fabrics to dry and wet rubbing is excellent. Printed polyamide fabric is more resistant to washing than printed cotton fabric. Both printed fabrics have poor colour fastness to light.
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Lemi, Muleta Tiki, Hirpa Gelgele Lemu, and Endalkachew Mosisa Gutema. "Review of Recent Advancements in 3D Printing Technologies for Textile Applications." Textile & Leather Review 8 (February 18, 2025): 72–104. https://doi.org/10.31881/tlr.2024.169.
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3D printing (3DP) ranks as one of the more advanced methods in the manufacturing sector. All of the industrial sectors, including automobiles, medical services, aviation, athletics, fabrics, apparel, and fashion industries, have noticed an increase in the use of this approach for prototyping. In the past decade, 3DP technology has been applied in several industries by academics, textile technologists, designers of apparel, manufacturers, and suppliers. Textiles perform numerous purposes in addition to meeting the basic human need to protect the body. The textile industry has expanded its horizons with the incorporation of 3DP technology. This paper's goal is to present an integrated overview of the recent state of research to identify the most advanced 3DP techniques, materials, and applications currently used in the clothing and textile sectors. Fundamentals of basic textile substrates, numerous textile-related 3DP technologies, printing methods, materials for print inks, direct printing of 3D elements on different textile surfaces, and the impacts, benefits and limitations of 3D printed textile structure fabrication techniques are all addressed. It also emphasizes the ways 3DP technology will be used in the textile sector moving forward. Overall, the purpose of this issue of Textile Progress is to identify the potential of 3DP, which, despite certain limits, may improve the products of the fashion and textile sectors and encourage future scientists and designers to continue additional research.
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Choi, Hak-Jong, Hyungjun Lim, Junhyoung Ahn, et al. "Fabrication of Laser-Induced 3D Porous Graphene Electrodes for High-Performance Textile Microsupercapacitors." ECS Meeting Abstracts MA2022-02, no. 9 (2022): 2535. http://dx.doi.org/10.1149/ma2022-0292535mtgabs.
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In recent decades, form factor of electronic devices is continuously evolving from flat device to curved and foldable devices to rollable devices. Electronic textile (E-textile) or electronic skin (E-skin) is attracting a lot of attention as one of the ultimate form factor devices. Many researchers have tried to change the form factor as E-textiles or E-skin for lots of electronics such as sensors, actuators, energy harvesting applications, displays, and even energy storage devices. Unlike devices such as displays and sensors that have practical applications, reliable energy storage devices in the form as E-textile and E-skin have not yet been for practical applications. Microsupercapacitors (MSCs) has received a lot of attention as power sources for wearable, textile or stretchable electronic devices due to their fast charging capability, long life cycle, and good safety. Most of electrode patterns for textile MSCs have been fabricated using inking based printing techniques such as screen printing, inkjet printing, and 3D printing. Although the ink printing techniques are considered to be compatible with large-scale production, the preparation of inks based on high performance namaterials requires a costly, time-consuming and complicated process including high temperature synthesis or dispersion in an toxic organic solvent. A robust textile MSC fabrication process with low cost, large-area, and high-performance is thus required Laser-induced graphene (LIG), acquired by the direct laser synthesis of various types of carbon precursors, have widely investigated as electrode materials of MSCs with the advantages of 3D porous electrodes with hierarchical porosity, high crystallinity, and high surface area. However, these superior properties of LIG electrode were not adopted in textile energy storage devices yet. In this work, LIG-based MSCs were fabricated by thermal transfer printing on textile. A LIG electrode directly laser-written on a PI film was transferred onto the adhesive film area of textile substrates during thermal transfer printing. The electrochemical performances of the as-fabricated textile LIG-MSCs were investigated. Especially, LIG-MSCs based on LIG-metal composite electrodes exhibit fast ion transport for high-rate performance with capacitive rectangular shapes at high scan rates of up to 20V/s, suggesting outstanding rate capability among graphene-based textile MSCs. Moreover, LIG-MSCs demonstrated the possibility of practical usage as textile energy storage devices such as cyclic stability, a waterproof property, and control of the working voltage or capacitance by series or parallel connection.
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Lempa, Evelyn, Maike Rabe, and Lieva Van Langenhove. "Dispenser Printing with Electrically Conductive Microparticles." Solid State Phenomena 333 (June 10, 2022): 31–38. http://dx.doi.org/10.4028/p-zs1155.
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Electrically conductive textiles for wearable smart devices are in increasing demand [1]. The advantages of flexible fabric structures are combined with electronic functions, such as sensing or actuating, energy harvesting or illuminating, for the design of a multitude of smart textiles. Those functions are often created by applying conductive layers or patterns onto the textile surface with two-phase systems based on conductive filler particles in polymeric binders. However, those systems alter the textile-typical properties regarding haptic, drape, flexibility or weight, depending on the type of conductive particle used, i.e., metal-or carbon-based ones. Generally, electrical conductivity increases with the increase of conductive filler concentration. The relation between the various factors determining the electrical behavior as well as the percolation threshold for some dispersions and in particular the size and shape of the filler particles were previously assessed for planar coatings [2]. In this research work electrically, conductive patterns were printed with dispenser printing technology using such two-phase dispersions based on polyurethane and polyacrylate binders and various metal microparticle flakes. With this application method linear resistance of approx. 25 to 100 Ohm per 100 cm depending on the textile structure could be realized, which was not even significantly reduced by household washing at 40°C or abrasion by Martindale.
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Dehghani, Mohaddesa, and Pratima Goyal. "Design and Development of Textile Fabrics Using 3D Printing Technology." ECS Transactions 107, no. 1 (2022): 19313–23. http://dx.doi.org/10.1149/10701.19313ecst.
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The Quality Management System (ISO 9000) compelled manufacturers to consider the environment by reducing the use of raw materials and energy in processes and to adopt clean energy sources. The $2.5 trillion textile sector is the world's second-largest user of water, accounting for 20% of global water waste during the processes. In terms of waste, 85 percent of textiles are disposed of in landfills and only a part of the wastage is recycled. The researcher has worked on additive manufacturing technology using 3D printers for the cleaner production of textile fabrics. It uses less material than the traditional manufacturing methods as it allows to melt/fuse/bind only the required amount of filament to develop the textile products using zero-waste sustainable design strategies. A pilot study was conducted to understand the viability of the use of 3D printing technology for the production of textile material. Based on the feedback, the researcher developed 12 textile samples using different raw materials and 3D printing machines which was further evaluated. It was seen that the most suitable materials to manufacture textiles are thermoplastic polyurethane and thermoplastic polyethylene and the most suitable machine used to manufacture them is FDM and SLA technology. This technology fulfills the Sustainable Development Goal for cleaner production of textile products. It can be concluded that the use of additive manufacturing technology in the textile industry will be a promising production process to meet various requirements especially as the path from an idea to the finished fabric becomes quite easy and fast.
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Utami, Sri, Igb Bayu Baruna Ariesta, and Nyoman Ayu Permata Dewi. "Kesenian Eco-print Hapazome pada Tekstil sebagai Antitesis Environmentally Unfriendly Textile Dyestuff." Abdi Seni 13, no. 2 (2022): 91–97. http://dx.doi.org/10.33153/abdiseni.v13i2.4230.
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Today’s fashion business is concerned about the environmentally unfriendly or ecologically unfavorable problem of textile industry waste. It is well recognized that dyes have hazardous effects on living organisms, and industrial textile waste in general can be in the form of effluents (liquid waste) including dye residual substances. Because it contaminates the water, textile dye waste is particularly unfavorable to the environment. Based on this, researchers design a textile using the Hapazome dyeing technique, which is an eco-friendly method of dying. This method falls under the category of eco-printing or natural printing. Hapazome technical art is one of the Japanese art which means leaf-dye. By hitting the leaf’s top surface against a piece of fabric, researchers apply Hapazome technique which can create a copy of the leaf’s motif form on fabric. The motifs designed by researchers in the creation of textiles were chosen from one of Balinese cultures, that is, Balinese script. The choice of Balinese script as the primary theme for creating textile designs attempts to demonstrate one of Balinese local identities. Thus, the nuances and characteristics of the local Balinese are built into the fabrics that researchers created. Using the approach of art creation, research is done on the art of eco-printing Hapazome on textiles as the antithesis of environmentally unfriendly textile dyestuff. The method of art creation is a way of systematically putting a work of art into real.
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Syakir, Bandi Sobandi, Tjetjep Rohendi Rohidi, et al. "Digital Textile Printing and Batik Preservation: A Bibliometric Analysis via VOSviewer." Journal of Advanced Research in Applied Sciences and Engineering Technology 58, no. 1 (2024): 181–203. https://doi.org/10.37934/araset.58.1.181203.
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This study examines digital textile printing as an opportunity and, simultaneously, a threat to batik preservation. The study used a bibliometric approach through VOSviewer computational mapping analysis. Article data is obtained from the Google Scholar database using the Publish or Perish reference manager application. The title and abstract of the article are used to guide the search process by referring to the keywords "digital textile printing" and "batik preservation." From the search results of 1000 articles, we found 771 articles that were considered relevant. The study period used as study material is Google Scholar-indexed articles for the last 5 years (2018–2023). The results showed that research related to textile digital printing and batik preservation identified several terms: study, batik, batik preservation development, ink, textile, technology, fabric, digital printing, digital textile printing, and application. From the clusters contained in the network visualization, it can be known: Cluster 1 has 37 items and is marked in red; Cluster 2 has 33 items and is marked in green; Cluster 3 has 27 items and is marked in blue; Cluster 4 has 21 items and is marked in yellow; Cluster 5 has 19 items and is marked in purple; Cluster 6 has 14 items and is marked in light blue; Cluster 7 has 14 items and is marked in orange; Cluster 8 has 12 items and is marked in brown; and Cluster 9 has 2 items and is marked in light purple. Based on the analysis of the development of digital printing, textile publications in the last 5 years show frequent fluctuations. In 2018–2019, it experienced a significant increase from 116 to 200, and then in 2020, the condition decreased to 167. From 2021 to 2022, there was a significant increase of 198 and 238, respectively. We examined how many articles have been published about digital textile printing and its relation to the issue of batik preservation using VOSviewer. This review can serve as a starting point for research related to other materials, especially technological developments related to textiles and batik.
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Vorkapić, Miloš, Ivana Mladenović, Teodora Vićentić, Dragan Tanasković, and Dušan Nešić. "The manufacturing technology of 3D printed models on various materials using the fused deposition modeling process." Advanced Technologies 12, no. 2 (2023): 50–56. http://dx.doi.org/10.5937/savteh2302049v.
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The joining of thermoplastic and textile materials is gaining more and more importance today. New combinations of materials and new structures that change fashion trends are obtained. The paper presents the technology of joining thermoplastic materials with different fabrics. For example, the realization of a button on textiles and the description of 3D printing were taken. This pioneering venture describes the technology, fabric model-making process, and materials melting bond analysis. Unfortunately, available thermoplastic materials have many limitations regarding durability, aging, and service life according to the defined requirements. The idea of this paper is the application of 3D printing in the fashion industry as an emerging topic for discussion. The experimental part of this investigation will provide a new guideline for designers of PLA/ABS printing elements on textile substrates and possibility for application in modern textile design.
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Sąsiadek-Andrzejczak, Elżbieta, and Marek Kozicki. "Multi-Color Printed Textiles for Ultraviolet Radiation Measurements, Creative Designing, and Stimuli-Sensitive Garments." Materials 16, no. 16 (2023): 5622. http://dx.doi.org/10.3390/ma16165622.
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This work concerns the new idea of textile printing with a multi-color system using pastes containing compounds sensitive to ultraviolet (UV) radiation. A screen printing method based on a modified CMYK color system was applied to a cotton woven fabric. Aqueous printing pastes were prepared from thickening and crosslinking agents and UV-sensitive compounds: leuco crystal violet (LCV), leuco malachite green (LMG), and 2,3,5-triphenyltetrazolium chloride (TTC) instead of the system’s standard process colors: cyan, magenta, and yellow. Depending on the number of printed layers and the type of UV radiation (UVA, UVB, and UVC), the modified textile samples change color after irradiation from white to a wide range of colors (from blue, red, and green to purple, brown, and gray). Based on reflectance measurements, the characteristic parameters of the one-, two-, and three-color-printed samples in relation to absorbed dose were determined, e.g., dose sensitivity, linear and dynamic dose response, and threshold dose. This printing method is a new proposal for UV dosimeters and an alternative standard for textile printing. Furthermore, the developed method can be used for the securing, marking, and creative design of textiles and opens up new possibilities for such stimulus-sensitive reactive printing.
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Guo, Ling Hua, Mei Yun Zhang, and Xin Hua Guo. "Research on the Application of G7 in the Gravure Printing Products." Advanced Materials Research 331 (September 2011): 314–17. http://dx.doi.org/10.4028/www.scientific.net/amr.331.314.
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The heat transfer printing is a new application in the textile industry. Gravure printing is the most common method in the heat transfer printing. The Gravure printing qualities of the paper play a decisive role in the textiles. GRACoL7 breaks with tradition by raising gray balance to a more important status to realize the different printing materials with the same appearance. GRACoL 7 process is accorded with human observation rule .In this paper, We introduce the process, the principle and the parameters of G7 .The purpose was to provide reference for printing industry.
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Azar, Golnaz Taghavi Pourian, Sofya Danilova, Latha Krishnan, Yirij Fedutik, and Andrew J. Cobley. "Selective Electroless Copper Plating of Ink-Jet Printed Textiles Using a Copper-Silver Nanoparticle Catalyst." Polymers 14, no. 17 (2022): 3467. http://dx.doi.org/10.3390/polym14173467.
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The electroless copper plating of textiles, which have been previously printed with a catalyst, is a promising method to selectively metallise them to produce high-reliability e-textiles, sensors and wearable electronics with wide-ranging applications in high-value sectors such as healthcare, sport, and the military. In this study, polyester textiles were ink-jet printed using differing numbers of printing cycles and printing directions with a functionalised copper–silver nanoparticle catalyst, followed by electroless copper plating. The catalyst was characterised using Transmission Electron Microscopy (TEM) and Ultraviolet/Visible (UV/Vis) spectroscopy. The electroless copper coatings were characterised by copper mass gain, visual appearance and electrical resistance in addition to their morphology and the plating coverage of the fibres using Scanning Electron Microscopy (SEM). Stiffness, laundering durability and colour fastness of the textiles were also analysed using a stiffness tester and Launder Ometer, respectively. The results indicated that in order to provide a metallised pattern with the desired conductivity, stiffness and laundering durability for e-textiles, the printing design, printing direction and the number of printing cycles of the catalyst should be carefully optimised considering the textile’s structure. Achieving a highly conductive complete copper coating, together with an almost identical and sufficiently low stiffness on both sides of the textile can be considered as useful indicators to judge the suitability of the process.
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Rodes-Carbonell, Ana María, Josué Ferri, Eduardo Garcia-Breijo, Ignacio Montava, and Eva Bou-Belda. "Influence of Structure and Composition of Woven Fabrics on the Conductivity of Flexography Printed Electronics." Polymers 13, no. 18 (2021): 3165. http://dx.doi.org/10.3390/polym13183165.
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The work is framed within Printed Electronics, an emerging technology for the manufacture of electronic products. Among the different printing methods, the roll-to-roll flexography technique is used because it allows continuous manufacturing and high productivity at low cost. Nevertheless, the incorporation of the flexography printing technique in the textile field is still very recent due to technical barriers such as the porosity of the surface, the durability and the ability to withstand washing. By using the flexography printing technique and conductive inks, different printings were performed onto woven fabrics. Specifically, the study is focused on investigating the influence of the structure of the woven fabric with different weave construction, interlacing coefficient, yarn number and fabric density on the conductivity of the printing. In the same way, the influence of the weft composition was studied by a comparison of different materials (cotton, polyester, and wool). Optical, SEM, color fastness to wash, color measurement using reflection spectrophotometer and multi-meter analyses concluded that woven fabrics have a lower conductivity due to the ink expansion through the inner part of the textile. Regarding weft composition, cotton performs worse due to the moisture absorption capacity of cellulosic fiber. A solution for improving conductivity on printed electronic textiles would be pre-treatment of the surface substrates by applying different chemical compounds that increase the adhesion of the ink, avoiding its absorption.
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Abe, Takao. "Present State of Inkjet Printing Technology for Textile." Advanced Materials Research 441 (January 2012): 23–27. http://dx.doi.org/10.4028/www.scientific.net/amr.441.23.
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nkjet printing technology can produce beautiful images not only on plain paper, but also on various kinds of printing media including a piece of cloth. Some Japanese companies have already stepped into the textile inkjet printer market, but making a profit is not easy so long as we look upon the inkjet printing technology as an alternative means of textile dyeing. Cost reduction is necessary as a whole for the inkjet printing systems to come into wide use in the textile dyeing industry. This paper describes current textile inkjet printing technology.
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Franco Urquiza, Edgar Adrian. "Advances in Additive Manufacturing of Polymer-Fused Deposition Modeling on Textiles: From 3D Printing to Innovative 4D Printing—A Review." Polymers 16, no. 5 (2024): 700. http://dx.doi.org/10.3390/polym16050700.
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Technological advances and the development of new and advanced materials allow the transition from three-dimensional (3D) printing to the innovation of four-dimensional (4D) printing. 3D printing is the process of precisely creating objects with complex shapes by depositing superimposed layers of material. Current 3D printing technology allows two or more filaments of different polymeric materials to be placed, which, together with the development of intelligent materials that change shape over time or under the action of an external stimulus, allow us to innovate and move toward an emerging area of research, innovative 4D printing technology. 4D printing makes it possible to manufacture actuators and sensors for various technological applications. Its most significant development is currently in the manufacture of intelligent textiles. The potential of 4D printing lies in modular manufacturing, where fabric-printed material interaction enables the creation of bio-inspired and biomimetic devices. The central part of this review summarizes the effect of the primary external stimuli on 4D textile materials, followed by the leading applications. Shape memory polymers attract current and potential opportunities in the textile industry to develop smart clothing for protection against extreme environments, auxiliary prostheses, smart splints or orthoses to assist the muscles in their medical recovery, and comfort devices. In the future, intelligent textiles will perform much more demanding roles, thus envisioning the application fields of 4D printing in the next decade.
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Safitri, Dewi Diana, and Tiwi Bina Affanti. "PERANCANGAN TEKSTIL PAKAIAN DENGAN PEWARNA DARI SAMPAH MANGROVE DAN PENERAPAN MOTIFNYA DENGAN PADUAN TEKNIK IKAT CELUP DAN ECO PRINTING." Ornamen 19, no. 2 (2022): 121–31. http://dx.doi.org/10.33153/ornamen.v19i2.4590.
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The background of this design, there is an exploration of manual textile techniques among textile designers, this is in line with the demands of the times, namely, the development of existing trends in order to meet the needs of consumers and the market. The combination of tie-dying and eco-printing techniques attracts attention to be explored again using natural dyes with the addition of embroidery techniques on Bemberg cloth media, which will produce textiles with novelty in their aesthetic motifs. The purpose of this design is to produce clothing textiles with novelty in their unique motif aesthetics among textile designers to meet the needs of consumers and the market. The novelty value offered in this design is the design of clothing textiles according to fashion patterns with a combination of dyeing and eco printing techniques with embroidery techniques. Natural coloring using extraction from mangrove waste. Composing motifs using natural dyes from mangrove waste with two fixations of quicklime and tunjung to obtain varied visual aesthetics in one natural coloring. The media used in this blend of tie-dying and eco-printing techniques is bemberg cloth. Bemberg cloth material was chosen because it has very good absorption. The design method uses the SP Gustami theory. This design produces 6 unique designs with visual ideas of line, plane and color, which can be achieved by a combination of tritik, jumputan tie-dyed and eco printing techniques, three of which are applied to sheets of cloth measuring 200cm long and 120cm wide. It is hoped that the "Design of Clothing Textiles with Dye from Mangrove Waste and the Application of its Motifs with a Combination of Ikat Dip and Eco Printing Techniques" can add variety to fashion products that have unique, distinctive and limited edition characters.
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Yong, Sheng, Nicholas Hillier, and Stephen Paul Beeby. "Phase-Inverted Copolymer Membrane for the Enhancement of Textile Supercapacitors." Polymers 14, no. 16 (2022): 3399. http://dx.doi.org/10.3390/polym14163399.
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This paper presents a universal fabrication process for single-layer textile supercapacitors, independent of textile properties such as weave pattern, thickness and material. To achieve this, an engineered copolymer membrane was fabricated within these textiles with an automated screen printing, phase inversion and vacuum curing process. This membrane, together with the textile yarns, acts as a porous, flexible and mechanically durable separator. This process was applied to four textiles, including polyester, two polyester-cottons and silk. Carbon-based electrodes were subsequently deposited onto both sides of the textile to form the textile supercapacitors. These supercapacitors achieved a range of areal capacitances between 3.12 and 38.2 mF·cm−2, with energy densities between 0.279 and 0.681 mWh·cm−3 with average power densities of between 0.334 and 0.32 W·cm−3. This novel membrane facilitates the use of thinner textiles for single-layered textile supercapacitors without significantly sacrificing electrochemical performance and will enable future high energy density textile energy storage, from supercapacitors to batteries.
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Ferri, Josue, Clara Perez Fuster, Raúl Llinares Llopis, Jorge Moreno, and Eduardo Garcia‑Breijo. "Integration of a 2D Touch Sensor with an Electroluminescent Display by Using a Screen-Printing Technology on Textile Substrate." Sensors 18, no. 10 (2018): 3313. http://dx.doi.org/10.3390/s18103313.
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Many types of solutions have been studied and developed in order to give the user feedback when using touchpads, buttons, or keyboards in textile industry. Their application on textiles could allow a wide range of applications in the field of medicine, sports or the automotive industry. In this work, we introduce a novel solution that combines a 2D touchpad with an electroluminescent display (ELD). This approach physically has two circuits over a flexible textile substrate using the screen-printing technique for wearable electronics applications. Screen-printing technology is widely used in the textile industry and does not require heavy investments. For the proposed solution, different layer structures are presented, considering several fabric materials and inks, to obtain the best results.
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Kozior, Tomasz, and Andrea Ehrmann. "First Proof-of-Principle of PolyJet 3D Printing on Textile Fabrics." Polymers 15, no. 17 (2023): 3536. http://dx.doi.org/10.3390/polym15173536.
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Possibilities of direct 3D printing on textile fabrics have been investigated with increasing intensity during the last decade, leading to composites which can combine the positive properties of both parts, i.e., the fast production and lateral strength of textile fabrics with the flexural strength and point-wise definable properties of 3D printed parts. These experiments, however, were mostly performed using fused deposition modeling (FDM), which is an inexpensive and broadly available technique, but which suffers from the high viscosity of the molten polymers, often impeding a form-locking connection between polymer and textile fibers. One study reported stereolithography (SLA) to be usable for direct printing on textile fabrics, but this technique suffers from the problem that the textile material is completely soaked in resin during 3D printing. Combining the advantages of FDM (material application only at defined positions) and SLA (low-viscous resin which can easily flow into a textile fabric) is possible with PolyJet modeling (PJM) printing. Here, we report the first proof-of-principle of PolyJet printing on textile fabrics. We show that PJM printing with a common resin on different textile fabrics leads to adhesion forces according to DIN 53530 in the range of 30–35 N, which is comparable with the best adhesion forces yet reported for fused deposition modeling (FDM) printing with rigid polymers on textile fabrics.
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Korger, Michael, Alexandra Glogowsky, Silke Sanduloff, et al. "Testing thermoplastic elastomers selected as flexible three-dimensional printing materials for functional garment and technical textile applications." Journal of Engineered Fibers and Fabrics 15 (January 2020): 155892502092459. http://dx.doi.org/10.1177/1558925020924599.
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Three-dimensional printing has already been shown to be beneficial to the fabrication of custom-fit and functional products in different industry sectors such as orthopaedics, implantology and dental technology. Especially in personal protective equipment and sportswear, three-dimensional printing offers opportunities to produce functional garments fitted to body contours by directly printing protective and (posture) supporting elements on textiles. In this article, different flexible thermoplastic elastomers, namely, thermoplastic polyurethanes and thermoplastic styrene block copolymers with a Shore hardness range of 67A–86A are tested as suitable printing materials by means of extrusion-based fused deposition modelling. For this, adhesion force, abrasion and wash resistance tests are conducted using various knitted and woven workwear and sportswear fabrics primarily made of cotton, polyester or aramid as textile substrates. Due to polar interactions between thermoplastic polyurethane and textile substrates, excellent adhesion and high fastness to washing is observed. While fused-deposition-modelling-printed polyether-based thermoplastic polyurethane polymers keep their abrasion–resistant properties, polyester-based thermoplastic polyurethanes are more prone to hydrolysis and can be partially degraded if presence of moisture cannot be excluded during polymer processing and printing. Thermoplastic styrene compounds generally exhibit lower adhesion and abrasion resistance, but these properties can be sufficient depending on the requirements of a particular application. Soft thermoplastic styrene filaments can be processed down to a Shore hardness of 70A resulting in three-dimensional printed parts with good quality and comfortable soft-touch surface. Finally, three demonstrator case studies are presented covering the entire process to realize the customized and three-dimensional printed textile. This encompasses product development and fabrication of a textile integrated custom-fit back protector and knee protector as well as customized functionalization of a technical interior textile for improved acoustic comfort. In the future, printing material modifications by compounding processes have to be taken into account for optimized functional performance.
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Hu, Lulu. "Design and Application of Splicing Patterns based on Rotary Screen Printing in Modern Home Textiles." BCP Social Sciences & Humanities 15 (March 13, 2022): 92–95. http://dx.doi.org/10.54691/bcpssh.v15i.367.
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Patchwork is a very popular classical aestheticism handicraft in the world. Patchwork is an art form developed from patchwork under a certain social economy and cultural background. Patchwork is a modern printing and dyeing of patchwork art. Contemporary form from the perspective of technology. With rotary screen printing as a technical support, the pattern design, textile fabrics and home textiles are organically combined, thus giving birth to a spliced pattern style. This article introduces the application of splicing patterns in the field of modern home textiles to obtain a unique and integrated effect of the finished product appearance. Due to the development of new materials and new technology, splicing design is "intercepting" and "integrating" to inject new vitality into modern home textile design visually. Therefore, this article explores and summarizes the innovative design and application prospects of splicing design in modern home textile design, and guides design thinking and creative methods in practice.
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Spahiu, Tatjana, Zlatin Zlatev, Elita Ibrahimaj, Julieta Ilieva, and Ermira Shehi. "Drape of Composite Structures Made of Textile and 3D Printed Geometries." Machines 10, no. 7 (2022): 587. http://dx.doi.org/10.3390/machines10070587.
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Applications of 3D printing in the fashion industry have continued to attract interest from academia and industry in order to improve and add functionalities to products. Among these applications, an interesting one is 3D printing on textile fabric. Composite structures created by 3D printing and textile fabric change a drape by improving or worsening its appearance. The scope of this work is to evaluate the effect of various 3D printed geometries on textile fabric regarding fabric drapes. The drape coefficient of the created composite structure is evaluated using a drape tester built according to EN ISO 9073-9. The results taken are compared with an algorithm developed for determining drape parameters and 3D form representation using color digital images and their image histograms. The measured values of the drape coefficient are close, with a minimal difference, up to 4%. The 3D printed patterns show a significant effect on the drape coefficient of textile fabrics by depicting another way to modify fabric drapes and create complex shapes by using less material. This can be seen as an advantage in the fashion industry where complex geometries can be added to textile fabrics, while changing fabric drape and product personalization and adding functionalities for garments and technical textiles.
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Tyler, David J. "Textile Digital Printing Technologies." Textile Progress 37, no. 4 (2005): 1–65. http://dx.doi.org/10.1533/tepr.2005.0004.
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Schofield, J. S. "Textile Printing 1934-1984." Review of Progress in Coloration and Related Topics 14, no. 1 (2008): 69–77. http://dx.doi.org/10.1111/j.1478-4408.1984.tb00046.x.
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Desai, R. L., T. N. Mehta, and V. B. Thosar. "Diazosulphonates in Textile Printing." Journal of the Society of Dyers and Colourists 54, no. 8 (2008): 371–81. http://dx.doi.org/10.1111/j.1478-4408.1938.tb02022.x.
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Ferri, Josue, Raúl Llinares Llopis, Jorge Moreno, Jose Vicente Lidón-Roger, and Eduardo Garcia-Breijo. "An investigation into the fabrication parameters of screen-printed capacitive sensors on e-textiles." Textile Research Journal 90, no. 15-16 (2020): 1749–69. http://dx.doi.org/10.1177/0040517519901016.
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The design and development of textile-based capacitive sensors requires the implementation of textile capacitors with a determined capacitance. One of the main techniques to obtain these sensors is the screen-printing of conductive and dielectric inks on textiles. This paper investigates the fabrication parameters that have the most influence when designing and implementing a screen-printed capacitive sensor. In this work, a textile has been used directly as the dielectric part, influencing sensitively the value of the permittivity and the thickness of the dielectric of the capacitor. These are two fundamental parameters for the estimation of its capacitance. The choice of the conductive ink, its viscosity and solid content, as well as printing parameters, such as printing direction, also impact on the manner for obtaining the electrodes of the capacitive sensor. Although the resulting electrodes do not represent an important parameter for the estimation of the capacitance, it determines the selection of fabrics that can be printed. As a result of the investigation, the paper provides a guideline to choose the materials, such as fabrics or inks, as well as the printing parameters, to implement e-textile applications based on projected capacitive technologies. The experiments carried out on different fabrics and inks have provided results with capacities of less than 60 pF, the limit where the sensors based on capacitive technologies are located.
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Ehrmann, Guido, and Andrea Ehrmann. "Shape memory textiles – technological background and possible applications." Communications in Development and Assembling of Textile Products 2, no. 2 (2021): 162–72. http://dx.doi.org/10.25367/cdatp.2021.2.p162-172.
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While shape memory alloys (SMAs) and shape memory polymers (SMPs) can already be found in diverse applications, shape memory textiles are less often used. Nevertheless, they are regularly investigated. Typical ways to produce shape memory textiles (SMTs) are introducing shape memory wires, printing shape memory polymers on them (“4D printing”), or using textile materials such as poly(lactic acid) (PLA) which show shape memory properties on their own. This review gives a brief overview of these technological possibilities and possible applications of shape memory textiles.
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Jaworski, Armen, and Kees Heil. "Inkjet Printing on Textiles: Software Package for Textile Designers." NIP & Digital Fabrication Conference 26, no. 1 (2010): 676–79. http://dx.doi.org/10.2352/issn.2169-4451.2010.26.1.art00078_2.
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Behary, Nemeshwaree, and Nicolas Volle. "Durable Textile Dyeing/Printing Using Natural Indigo Dyes and Leaves, and Mayan-Inspired Blue Indigo Pigments." Colorants 4, no. 1 (2025): 2. https://doi.org/10.3390/colorants4010002.
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Indigo leaves from various plant species are sources of dyes/pigments, not fully exploited for making sustainable textiles. Blue indigo vat dye extracted from indigo leaves yields high wash color fastness but fades slowly with light, and is not easily used for direct printing. Indigo leaves can be used to produce textiles of various color shades, while light-resistant Mayan-inspired hybrid pigments have not yet been used for textile coloring. Using blue indigo dyes from three plant species, with exhaustion dyeing, intense wash-resistant blue-colored textiles are produced, and in the case of Indigofera Persicaria tinctoria, textiles have antibacterial activity against S. epidermis and E. coli. A 100% natural Mayan-inspired blue indigo pigment, made from sepiolite clay and natural indigo dye, was used both in powdered and paste forms to perform pigment textile dyeing by pad cure process, and direct screen printing on textiles. A water-based bio-binder was used efficiently for both padding and printing. Bio-based Na Alginate thickener allowed to produce prints with good color-fastness on both polyester and cotton fabrics, while bio-based glycerin produced excellent print color fastness on polyester only: wash fastness (5/5), dry and wet rub fastness (5/5) and light fastness (7/8).
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Tuvshinbayar, Khorolsuren, Nonsikelelo Sheron Mpofu, Thomas Berger, Jan Lukas Storck, Alexander Büsgen, and Andrea Ehrmann. "Comparison of FDM and SLA printing on woven fabrics." Communications in Development and Assembling of Textile Products 5, no. 2 (2024): 169–77. http://dx.doi.org/10.25367/cdatp.2024.5.p169-177.
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Possibilities to perform 3D printing directly on textile fabrics have been investigated intensively during the last decade. Usually, fused deposition modeling (FDM) printing with often inexpensive 3D printers is applied in these experiments. Several studies revealed the influence of textile fabrics, FDM polymers and printing parameters, indicating that not all combinations of fabrics and printing materials are suitable for this task. Recently, first approaches to use stereolithography (SLA) or PolyJet Modeling (PJM) directly on textile fabrics have been reported. Here, the first comparison of the adhesion forces reached by FDM and SLA printing on different woven fabrics is shown, revealing significantly better adhesion for SLA printing.
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Kiran P. Kolkar, Ravindra B. Malabadi, Raju K. Chalannavar, et al. "Industrial Cannabis sativa (Fiber or Hemp): Hemp Cottonization-Advantages and Current Challenges." International Journal of Science and Research Archive 14, no. 3 (2025): 1233–67. https://doi.org/10.30574/ijsra.2025.14.3.0755.
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Industrial Cannabis sativa (hemp or fiber type) has many applications particularly to produce paper, ropes, food, medicines, cosmetics, hempcrete, leather, bioplastic, biochar, 3D printing and textiles. Hemp fibers are used to create durable and eco-friendly fabrics for clothing, upholstery, and accessories. Hemp clothing is valued for its durability, breathability, and biodegradability, making it a preferred choice for conscious consumers. Hemp has been the mostly blended with cotton and synthetic fibers due to barriers in the industrial process of the production of full hemp-based textiles. India is the second-largest textile producer in the world. Digital, 3D Printing and 3D textile printing are emerging as game-changers in the Indian textile industry. Textile designers in India are already using 3D printing to create intricate patterns and textures on fabric, offering consumers a unique, personalized experience. One such major challenge is non-compatibility of hemp with modern textile machinery. The best way to process hemp is ‘cottonization’ of hemp. Cottonization is defined as the process of converting the hard bark of a hemp plant into a cotton like structure so that it can be used on dry spinning systems. Methods of hemp fiber extraction include dew retting, water retting, osmotic degumming, enzymatic retting, steam explosion and mechanical decortication to decompose pectin, lignin and hemicellulose to remove them from the stem with varying efficiency. However, there are several challenges associated with hemp processing as the fiber is coarse, stiff and it has comparatively poor spinnability particularly when 100% hemp is processed in ring spinning system. India has the potential to lead the global hemp revolution, there are challenges to overcome. The Indian hemp clothing market faces challenges related to regulatory issues, public perception, and sourcing of hemp fibers. However, as more research highlights the environmental and economic benefits of hemp, the stigma is gradually fading. The lack of production of specialized industrial machines dedicated to hemp fibers results in the high diversity of technological lines used and makes it impossible to evaluate the universal economic aspects of hemp yarn manufacturing.
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Pardie, S. P., B. K. Asinyo, E. K. Howard, and R. Acquaye. "Analysis of Design Concepts in Printed Fabrics: A Comparative Study of Pre- And Post-2000 Textile Printing Industry in Ghana." AFRICAN JOURNAL OF APPLIED RESEARCH 9, no. 1 (2023): 257–72. http://dx.doi.org/10.26437/ajar.v9i1.539.
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Purpose: The paper aims to analyze and compare the design concepts in printed fabrics between the pre- and post-2000 periods in Ghana. By examining the changes in design trends, techniques, and motifs, the study also aims to identify the factors that have influenced the evolution of printed fabric designs over time. Methods: This research adopts a concurrent embedded mixed method design, combining qualitative and quantitative methods. Primary data is collected through interviews with textile designers, manufacturers, and industry experts. A comprehensive analysis of printed fabric samples from pre- and post-2000 periods is conducted. The data collected is then analyzed using thematic analysis and statistical techniques. Findings: This research provides insights into the changes in design concepts in the printed fabric industry in Ghana. The study reveals shifts in design trends, such as the adoption of digital printing techniques, the incorporation of contemporary motifs, and the influence of global fashion trends. Research Limitation/Implications: The study's limitations include small sample size, limited representation of Ghana's textile printing industry's diverse design concepts, and insufficient exploration of production processes or market dynamics. Practical Implication: Research highlights design changes in Ghanaian textiles, enabling designers to create innovative, marketable printed fabrics and manufacturers to adapt production processes. Social Implication: The textile printing industry in Ghana significantly impacts cultural identity and economic development. Originality/Value: This research adds value to the existing literature on the textile printing industry by comprehensively analysing the design concepts in printed fabrics in Ghana.
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Vigneshwar, R., and S. Karthikeyan. "A Novel Study of Hazard Identification and Risk Assessment in Textile Industry." International Journal for Research in Applied Science and Engineering Technology 11, no. 3 (2023): 1646–85. http://dx.doi.org/10.22214/ijraset.2023.49709.
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Abstract: The work environment of textiles is risky and portrayed by different simultaneous chemical, physical and mechanical hazard exposure, which would prompt wounds of textile labourers. Health risks from working in the textile industry. This manuscript contains the details on the hazards and risk level present in one of south India's leading textile industry. This study also briefs about the need, method and result of the HIRA technique. The HIRA technique is adopted in the old rotary printing department and dyeing department to assess the risk levels in terms of quantified values. The control measures were also developed for each area and activities identified with potential safety issues. It is found that the identified hazards majorly categorized under Physical, chemical, ergonomics, material handling, health and electrical hazards. The risk level is quantified for all the hazards in the printing and dyeing department by multiplying the values of severity and probability.
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Patti, Antonella, and Domenico Acierno. "Towards the Sustainability of the Plastic Industry through Biopolymers: Properties and Potential Applications to the Textiles World." Polymers 14, no. 4 (2022): 692. http://dx.doi.org/10.3390/polym14040692.
Full textAbstract:
This study aims to provide an overview of the latest research studies on the use of biopolymers in various textile processes, from spinning processes to dyeing and finishing treatment, proposed as a possible solution to reduce the environmental impact of the textile industry. Recently, awareness of various polluting aspects of textile production, based on petroleum derivatives, has grown significantly. Environmental issues resulting from greenhouse gas emissions, and waste accumulation in nature and landfills, have pushed research activities toward more sustainable, low-impact alternatives. Polymers derived from renewable resources and/or with biodegradable characteristics were investigated as follows: (i) as constituent materials in yarn production, in view of their superior ability to be decomposed compared with common synthetic petroleum-derived plastics, positive antibacterial activities, good breathability, and mechanical properties; (ii) in textile finishing to act as biological catalysts; (iii) to impart specific functional properties to treated textiles; (iv) in 3D printing technologies on fabric surfaces to replace traditionally more pollutive dye-based and inkjet printing; and (v) in the implants for the treatment of dye-contaminated water. Finally, current projects led by well-known companies on the development of new materials for the textile market are presented.