Relevant bibliographies by topics / And Textile printing

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

Academic literature on the topic 'And Textile printing'

Author: Grafiati
Published: 7 June 2025
Last updated: 16 July 2025

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Journal articles on the topic "And Textile printing"

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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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Dissertations / Theses on the topic "And Textile printing"

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Miah, A. S. "Capillarity effects in textile printing." Thesis, University of Manchester, 1985. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.377639.

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Mrad, Mona. "Transfer Printing and Cellulose Based substrates for modern Textile Printing." Thesis, Linköpings universitet, Institutionen för fysik, kemi och biologi, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-159745.

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Digital printing technology is a technique that has been growing since the 1990s and has a high growth potential when it comes to using different ink types and transfer printing techniques. In comparison to screen printing, digital transfer printing techniques have shown to consume less ink and water and are therefore considered to be a more environmentally friendly alternative for textile printing. Therefore, a digital printing technique called sublimation transfer printing was studied in this thesis. In a sublimation transfer printing process, an image is printed on a paper and then the image is transferred to a textile by using heat and pressure. Suitable coating of the paper surface has shown to improve the printing properties on the paper and therefore the paper samples used in the thesis were coated with three different coating formulas. The coating formulas used in this thesis were polyvinyl alcohol (PVOH) of a type A, PVOH A with ground calcium carbonate (GCC) and PVOH type B with GCC. PVOH A has a higher degree of hydrolysis than PVOH B. Results showed that there was no significant difference between optical densities between textiles and paper samples of different coat weights and coating formulas. The colour bleeding and colour penetration decreased in the printed paper samples for PVOH A + GCC and PVOH B + GCC when the coat weight increased, and the porosity of the coating decreased to some extent. As a conclusion, paper samples coated with PVOH A + GCC with coat weights above 15 g/m2 showed to give the best properties since the colour bleeding was minimal in those printed coated paper samples.
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Kooroshnia, Marjan. "On textile printing with thermochromic inks." Doctoral thesis, Högskolan i Borås, Akademin för textil, teknik och ekonomi, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:hb:diva-11896.

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This thesis describes an exploration of the principles of applying leuco dye-based inks to textile design practice. The main motivation has been to explore the design properties and potentials of leuco dye-based thermochromic inks when printed on textiles in order to obtain an understanding and facilitate the design of dynamic surface patterns. The significance of this is related to the development of a methodology to assist designers in seeing possibilities, making informed decisions, and predicting colour transitions at different temperatures when designing a dynamic surface pattern. The research was conducted by undertaking a series of design experiments using leuco dye-based thermochromic inks, which resulted in various working methods and two pedagogical tools. This process offered the insight and depth of understanding required to design dynamic surface patterns, in that it highlighted the different colour-changing properties of leuco dye-based thermochromic inks, which have the potential to create a more complex and dynamic range of patterns on textiles than those that exist today. There is much to explore beyond the current design possibilities offered by thermochromic inks, and it is hoped that designers and researchers can apply the knowledge that has been obtained during the work of this thesis to their practical explorations so as to move towards new ways of thinking and designing, and further innovation in textile design.
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Failor, Brian Jay. "Xerographic printing of textiles." Thesis, Georgia Institute of Technology, 1993. http://hdl.handle.net/1853/9482.

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Needham, Meredith O. "A survey of digital printing in home décor textiles : 3 case studies /." Online version of thesis, 2008. http://hdl.handle.net/1850/6430.

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Shi, Songhua. "Interfacial studies on xerographic textile prints." Thesis, Georgia Institute of Technology, 1997. http://hdl.handle.net/1853/9196.

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Fredin, Lisa. "(Un)Perfect : Breaking the rules in textile printing." Thesis, Högskolan i Borås, Akademin för textil, teknik och ekonomi, 2016. http://urn.kb.se/resolve?urn=urn:nbn:se:hb:diva-10286.

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This work explores the techniques of printing and preparation, in combination with technical mistakes. It aims to show how to use technical mistakes in different printing and preparation techniques as a design method to find accidental aesthetic expressions using the stripe as a tool to enhance and clarify the methods modification. The method confronts today’s textile industry by showing how these mistakes could develop into new expressions within textile design when fast -fashion is no longer an obligation. The stripe is a common shape, and is explored to clarify the method ans show how different techniques can change the stripes in various ways. This resulted in to three pieces each representing a technique; one transfer printed, one digital printed and one with the starting point in screen print. They present examples of how more time for developing mistakes in textile design can lead to development of the common shape of a stripe, broaden the technical limitations, and give a value to mistakes in the textile industry. By taking the method further more mistakes could be developed, and how to produce the developed designs in the industry could be investigated.
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Viziteu, Diana-Roxana, and Antonela Curteza. "3D printing technology in textile and fashion industry." Thesis, Київський національний університет технологій та дизайну, 2020. https://er.knutd.edu.ua/handle/123456789/16807.

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This papers aims to explore the applicability of 3D printing materials using thermoplastic polyurethane (TPU) for the development of protective gear. In the fashion industry, three-dimensional (3D) printing has been used by designers and engineers to create everything from accessories to clothing, but only a few studies have investigated its applicability in personal protective equipment. One of the most significant technologies of the fourth industrial revolution is 3D printing. Additive manufacturing and 3D printing are the subject of intensive research and development (methods, materials, new techniques, application areas, etc.). The purpose of this study is to develop 3D printing samples and study conditions related to TPU.
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Wang, Lejun. "Studies on toner properties and fabric performance properties for xerographic textile printing." Thesis, Georgia Institute of Technology, 1996. http://hdl.handle.net/1853/8693.

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Mhetre, Shamal Kamalakar. "Effect of fabric structure on liquid transport, ink jet drop spreading and printing quality." Diss., Atlanta, Ga. : Georgia Institute of Technology, 2009. http://hdl.handle.net/1853/28244.

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Thesis (M. S.)--Polymer, Textile and Fiber Engineering, Georgia Institute of Technology, 2009.<br>Committee Chair: Dr. Radhakrishnaiah Parachuru; Committee Member: Dr. Dong Yao; Committee Member: Dr. Fred Cook; Committee Member: Dr. Wallace Carr; Committee Member: Dr. Yehia El Mogahzy
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Books on the topic "And Textile printing"

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Inc, Barron's Educational Series. Textile printing. Barron's Educational Series, 2012.

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C, Miles L. W., and Society of Dyers and Colourists., eds. Textile printing. 2nd ed. Society of Dyers and Colourists, 2003.

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Khandelwal, M. K. Dyeing printing and textile. Ritu Publications, 2005.

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Heeswijk, A. M. Van. Photocromic pigments in textile printing. UMIST, 1997.

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Pushpa, M. N. Catalogue of textiles & textile blocks in the collections of government museums in Tamilnadu. Published by Dir. of Museums, Govt. of Tamil Nadu, 2006.

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Murugesh Babu, K., M. Selvadass, Megha Shisodiya, and Abera Kechi Kabish. Abstract Pattern Illustrations for Textile Printing. Springer Singapore, 2022. http://dx.doi.org/10.1007/978-981-16-5975-1.

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American Association of Textile Chemists and Colorists. Printing Technology Committee., ed. AATCC glossary of printing terms. The Association, 1992.

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O'Reilly, Susie. Block printing. Thomson Learning, 1993.

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McMillan, Reed. Imagery in copperplate-printed textiles from the Helen Allen Textile Collection. University of Wisconsin, Helen Allen Textile Collection, 1990.

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Ellena, Bérénice. India sutra: On the magic trail of textiles = Bhārata sūtra. Shubhi Publications, 2007.

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Book chapters on the topic "And Textile printing"

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Mahapatra, Nanda Nandan. "Digital textile printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-8.

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Mahapatra, Nanda Nandan. "Screen printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-5.

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Mahapatra, Nanda Nandan. "Garment printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-10.

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Mahapatra, Nanda Nandan. "Discharge printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-6.

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Mahapatra, Nanda Nandan. "Block printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-7.

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Mahapatra, Nanda Nandan. "Transfer printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-9.

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Mahapatra, Nanda Nandan. "Resist printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-4.

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Mahapatra, Nanda Nandan. "Direct printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-2.

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Mahapatra, Nanda Nandan. "Roller printing." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-3.

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Mahapatra, Nanda Nandan. "Introduction." In Textile Printing. CRC Press, 2023. http://dx.doi.org/10.1201/9781032630113-1.

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Conference papers on the topic "And Textile printing"

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Wang, Hai-Yang, Long Wu, Jing Qi, Jun-Tao Ding, and Yue Wang. "Optimising 3D Printing Bra Cup Structure Design Using Lattice Structure." In 17th Textile Bioengineering and Informatics Symposium. Textile Bioengineering and Informatics Society Limited (TBIS), 2024. https://doi.org/10.52202/076989-0041.

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Zang, Yi-Lei, and Jie Chen. "Peking Opera Mask Patterns Design in Clothing Printing with AIGC." In 17th Textile Bioengineering and Informatics Symposium. Textile Bioengineering and Informatics Society Limited (TBIS), 2024. https://doi.org/10.52202/076989-0050.

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Zhao, Wei-Hua, and Meng-Jia Ge. "Automatic Pattern Generation of Xinjiang Stamp Printing Based on Neural Network." In 17th Textile Bioengineering and Informatics Symposium. Textile Bioengineering and Informatics Society Limited (TBIS), 2024. https://doi.org/10.52202/076989-0039.

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Kawamura, Harumi, Yuya Amo, Naoko Tosa, and Ryohei Nakatsu. "Kimono Fashion Development Based on the Fusion of Digital Art and Digital Textile Printing." In 2024 Nicograph International (NicoInt). IEEE, 2024. http://dx.doi.org/10.1109/nicoint62634.2024.00026.

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Gichuhi, Tony, and David Tarjan. "Corrosion Control without the Use of Toxic Heavy Metals." In SSPC 2013 Greencoat. SSPC, 2013. https://doi.org/10.5006/s2013-00068.

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Abstract Until recently heavy metal based corrosion inhibitors were widely accepted as the best materials that could provide the corrosion protection needed in coatings. Corrosion inhibitors provide an indispensable function in protective coatings. The performance of a coating under corrosive conditions requires that corrosion inhibitors provide sustainable protection during the coatings lifetime. The coating industry however is challenged to be more cognizant of the impact toxic metals have on human health and the environment. In response to a REACH (Registration, Evaluation, Authorization and Restriction of Chemicals) mandate, products now containing zinc, zinc oxide, zinc phosphate (both ortho and dihydrogen), zinc sulfate, zinc chloride require hazardous dead fish and dead tree labeling due to their environmental toxicity. The list of chemicals considered Carcinogenic, Mutagenic or Reproductive (CMR) toxics continues to grow with the inclusion of most chromate and cobalt salts used in coatings. The Occupational Safety and Health Administration (OSHA) estimated that across all industries, approximately one million workers are exposed to hexavalent chromium on a regular basis. Workers are potentially exposed to hexavalent chromium compounds when involved in the production and/or use of chromate pigments, chromium catalysts, chromate paints and coatings, printing inks, plastic colorants, electroplating chemicals, wood preserving chemicals, leather tanning chemicals, textile dyes, and industrial water treatment products. The growing pressure to replace chromium, zinc, barium, and other heavy metals has shifted the coatings pendulum to more eco-friendly alternatives. This paper captures specific technologies reflecting the new paradigm shift based on heavy-metal free inorganic pigments as well as non-toxic organic corrosion inhibitors.
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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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Dragović, Njegoš, Snežana Urošević, and Milovan Vuković. "Innovation of using 3D printing for textile fibers." In 7th International Scientific Conference Contemporary Trends and Innovations in Textile Industry – CT&ITI 2024. Union of Engineers and Technicians of Serbia, Belgrade, 2024. http://dx.doi.org/10.5937/ct_iti24031d.

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Textile fibers are produced in a natural way, and more and more often we have the opportunity to see impossible textile structures that retain desirable properties, such as non-creasing, long-term coloring, temperature stability, resistance to insects and the like. For the expansion of the use of printed textiles, a well-organized system in which technology is connected with economy, ecology, resources, informatics and marketing will have a great merit. Many filament (material) input methodologies are similar, and the difference is in the materials used, as well as in the process of general application and combining and joining of materials, so that the product is used for a long time. Fashion trends are something that negatively affects products, but this is solved by recycling and refurbishing clothes or shoes. The key moment for the development of 3D printing in the textile industry will be widely available printing technology, broadband internet and broad social acceptance of innovative materials. This paper presents the technologies that use different filaments in the production of textile fibers, and then also final products that do not have to be only clothing, but also for the needs of construction, defense and agriculture. The reason that every industry is looking for the use of artificial material that has similar characteristics to natural ones, where some properties will be improved and competitive in the market.
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Connelly, Sr., Roland L. "Instrumental color control in textile printing." In Electronic Imaging: Science & Technology, edited by Jan Bares. SPIE, 1996. http://dx.doi.org/10.1117/12.236958.

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Guerineau, Julia, Jollan Ton, Merieme Bassaoui, and Mariia Zhuldybina. "Electronic textile printing for sensing wearables." In 2024 IEEE International Conference on Flexible and Printable Sensors and Systems (FLEPS). IEEE, 2024. http://dx.doi.org/10.1109/fleps61194.2024.10604036.

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Ковалева, О. В., and А. Е. Третьякова. "REPRODUCTION OF ORNAMENT COLOR IN TEXTILE PRINTING." In Цвет в пространственных искусствах и дизайне. Crossref, 2024. http://dx.doi.org/10.54874/9785605245766.2024.04.22.

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Расцвечивание текстильных изделий узорами в декоративном направлении — древнее искусство. Существует множество способов, и один из них — печатание. Печать — создание рисунка на ткани — по видам исполнения весьма разнообразна, ее основы легли в другой вид печати — полиграфию. С появлением цифровых технологий грани между видами печати стираются и остается широкая возможность воспроизведения цвета во всем его многообразии. Существует ряд параметров, которые необходимо соблюдать: композиционная гармоничность изображения, стойкость окраски к эксплуатационным параметрам, цветосочетание и цветовоспроизведение как вектор модных трендов сезона. Decorative coloring of textiles with patterns is an ancient art. There are many methods, and one of them is printing. Printing – creating a pattern on fabric – is very diverse in types of execution, its foundations were laid in another type of printing – polygraphy. With the advent of digital technology, the boundaries between types of printing are erased, and there are still ample opportunities to reproduce color in all its diversity. It is necessary to observe a number of parameters: compositional harmony of an image, stability of coloring to operational parameters, combination of colors and color rendering as a vector of fashion trends of the season.
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Reports on the topic "And Textile printing"

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Sun, Lushan. Daring to Sprint: 3D printing textile. Iowa State University, Digital Repository, 2017. http://dx.doi.org/10.31274/itaa_proceedings-180814-247.

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Kays, Lauren, Helen S. Koo, Karla Simmons, and Paula Peek. Assimilation and Transformation: Application of Digital Textile Printing. Iowa State University, Digital Repository, 2014. http://dx.doi.org/10.31274/itaa_proceedings-180814-898.

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Zhang, Ling. Action Research in Apparel Design Using Digital Textile Printing Technology. Iowa State University. Library, 2019. http://dx.doi.org/10.31274/itaa.8378.

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Raj, Deepika, and Kristen Morris. Disruptive Potential of 3D Printing for Clothing and Textile Sector. Iowa State University, Digital Repository, 2016. http://dx.doi.org/10.31274/itaa_proceedings-180814-1520.

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Shamey, Renzo, Traci A. M. Lamar, and Uikyung Jung. Digital Textile Printing with Laser Engraving: Surface Contour Modification and Color Properties. Iowa State University. Library, 2019. http://dx.doi.org/10.31274/itaa.9459.

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Sun, Lushan, and Sheng Lu. The 3D Printing Era: A Conceptual Model for the Textile and Apparel Industry. Iowa State University, Digital Repository, 2015. http://dx.doi.org/10.31274/itaa_proceedings-180814-1171.

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Plummer, Brianna, Eulanda A. Sanders, and Fatma Baytar. The Rise of Online Digital Textile Printing Services and its Impact on Costume Design Practice. Iowa State University, Digital Repository, 2017. http://dx.doi.org/10.31274/itaa_proceedings-180814-1900.

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Plummer, Brianna, Eulanda A. Sanders, and Fatma Baytar. Developing a Trend Analysis Instrument to Establish a Taxonomy of Digital Textile Printing Attributes for Costume and Theatrical Fashion Design Use. Iowa State University, Digital Repository, 2017. http://dx.doi.org/10.31274/itaa_proceedings-180814-1899.

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Wongkasemjit, Sujitra. Treatment of dye containing in textile wastewater using TS-1, Ti-MCM-41 and Bismuth Titanate Catalysts : final report. Chulalongkorn University, 2007. https://doi.org/10.58837/chula.res.2007.94.

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This research was to study the photocatalytic activity of three different metal oxide catalysts, namely MCM-41, TS-1, and bismuth titanate (Bi[subscript 12]TiO[subscript 20]) in the reactive black 5 dye solution and the waste water obtained from a dye industry. These catalysts were synthesized using silatrane, titanium glycolate and bismuth nitrate precursors. The degradation process was first studied in the reactive black 5 dye model. The parameters in this study were pH, amounts of H[subscript 2]O[subscript 2] and Ti-loading in zeolite structure while fixing the organic dye at 40 ppm. At pH3, all three catalysts showed high photocatalytic activity. The higher amount of H[subscript 2]O[subscript 2] resulted in the higher photocalytic activity. The decoloration and the percent of mineralization increased with the higher Ti-content. The carbon reduction reached 79% using MCM-41 as catalyst, 65% for TS-1 and 35% for bismuth titanate, respectively. In the real wastewater obtained from Thanakul Dyeing And Printing Co., Ltd., it was found that all the three catalysts showed promising activity results. Moreover, in the case of using MCM-41 as catalyst, the carbon reduction reached 16% with respect to the initial carbon content. The results are very satisfying since the catalysts can oxidize non-pretreated-wastewater from industries under a mild condition.
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Goncu-Berk, Gozde. 3D Printing of Conductive and Phosphorescent Filaments onto Textiles. Iowa State University. Library, 2019. http://dx.doi.org/10.31274/itaa.8454.

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