Journal articles: 'Printing industry'

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Park, Sehwan. "3D Printing Industry Trends." International Journal of Advanced Culture Technology 2, no. 1 (June 30, 2014): 30–32. http://dx.doi.org/10.17703/ijact.2014.2.1.030.

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Kitayama, Takuo. "Trends of Printing Industry." JAPAN TAPPI JOURNAL 55, no. 12 (2001): 1722–30. http://dx.doi.org/10.2524/jtappij.55.1722.

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Ainul, Amri Lala Hucadinota, Noor Azly Mohammed Ali, and Rusmadiah Anwar. "Indonesian Printing Industry Profile." Environment-Behaviour Proceedings Journal 7, SI7 (August 31, 2022): 221–25. http://dx.doi.org/10.21834/ebpj.v7isi7.3786.

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This study aims to determine the profile of the printing industry from the point of view of the factors that influence the success of the industry. The influencing factors are marketing and sales and government regulations. Data were collected using the documentation method from literature and regulatory studies and analyzed by using qualitative data triangulation techniques. The results show that the profile of the printing industry in Indonesia is unique in terms of industrial classification. This is following applicable government regulations. Marketing and sales aspects show good results based on empirical studies of government reports. From the analysis, it can be seen that clarity of government regulations is needed for the sustainability and success of this industry to support the national agenda. Keywords: Printing; Industry; Profile; Industry Classification. eISSN: 2398-4287 © 2022. The Authors. Published for AMER ABRA cE-Bs by e-International Publishing House, Ltd., UK. This is an open access article under the CC BYNC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer–review under responsibility of AMER (Association of Malaysian Environment-Behaviour Researchers), ABRA (Association of Behavioural Researchers on Asians) and cE-Bs (Centre for Environment-Behaviour Studies), Faculty of Architecture, Planning & Surveying, Universiti Teknologi MARA, Malaysia. DOI: https://doi.org/10.21834/ebpj.v7iSI7%20(Special%20Issue).3786

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Tsukada, Masuo. "The view of the printing industry and relationship between the papermaking industry and the printing industry." JAPAN TAPPI JOURNAL 45, no. 3 (1991): 317–28. http://dx.doi.org/10.2524/jtappij.45.317.

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Schwartz, Kathryn A. "THE POLITICAL ECONOMY OF PRIVATE PRINTING IN CAIRO AS TOLD FROM A COMMISSIONING DEAL TURNED SOUR, 1871." International Journal of Middle East Studies 49, no. 1 (January 20, 2017): 25–45. http://dx.doi.org/10.1017/s0020743816001124.

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AbstractThis article examines the political economy of Cairo's emerging Arabic private printing industry during the third quarter of the 19th century. I use the constituent texts of the industry to demonstrate that it developed upon the speculative model of commissioning, whereby individuals paid printers to produce particular works of their choosing. Commissioning indicates that Egyptian private printing grew from local traditions for producing handwritten texts. Nevertheless, print commissioning differed from manuscript commissioning by requiring individuals to assume great financial risk. I explore the nature and implications of this divergence through a treatise published in 1871 by Musa Kastali, a particularly prolific printer who helped to professionalize Cairene printing. Musa's treatise details his legal battle with a famous Azhari commissioner, and is unique for describing a printer's business practices. It demonstrates the importance of situating printings within their socioeconomic contexts in addition to their intellectual ones, a task which cannot be done without an appreciation for the functioning of the printing industry at a local level.

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Pawlak, Dariusz, and Piotr Boruszewski. "Digital printing in wood industry." Annals of WULS, Forestry and Wood Technology 109 (March 31, 2020): 109–15. http://dx.doi.org/10.5604/01.3001.0014.3419.

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Digital printing in wood industry. The article presents modern techniques for surface finishing of wood-based panels, including the dynamically developing digital printing technology. The basic technological factors affecting the result of the digital printing process are discussed, and advantages and disadvantages of different types of this technology are presented.

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Ghosh, B., and S. Karmakar. "3D Printing Technology and Future of Construction: A Review." IOP Conference Series: Earth and Environmental Science 1326, no. 1 (June 1, 2024): 012001. http://dx.doi.org/10.1088/1755-1315/1326/1/012001.

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Abstract Historically characterised by its labour-intensive nature and low productivity, the construction industry is witnessing a technological revolution. Among these advancements, 3D printing stands out as a frontrunner, offering the potential to automate construction processes, reduce material waste, shorten project timelines, and mitigate risks associated with manual labour. This study explores the transformative capacity of large-scale 3D printing in construction, examining current progress, potential trajectories, and inherent limitations. Furthermore, it assesses the impact of expanded 3D printing adoption on the construction labour market. Our findings highlight 3D printing’s potential to significantly diminish the need for manual labour, addressing labour shortages, particularly in countries reliant on immigrant labour forces. However, its effectiveness may vary in regions with competitive labour costs where manual labour remains prevalent. Integrating 3D printing in construction necessitates cultivating a specialised workforce with expertise in this innovative technology. In conclusion, this study underscores the transformative influence of 3D printing in construction, offering increased efficiency, reduced labour dependency, and solutions to industry challenges. Adapting 3D printing adoption to regional labour dynamics and workforce upskilling is essential for maximising its benefits. As the construction industry evolves, embracing 3D printing emerges as a pivotal factor in shaping its future landscape.

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Gu, Wen Juan, Ying Li, and Xiao Hui Zhang. "Printing Industry and the Environment." Advanced Materials Research 663 (February 2013): 759–62. http://dx.doi.org/10.4028/www.scientific.net/amr.663.759.

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Development of green economy is the only way to relieve the restriction of resource, which is the effective and important way to improve economical benefit radically. Only in this way can continuable development be achieved. The research on pollution in printing industry was reported in this paper. The general pollutant such as solvents, exhaust gas, ink, and etc were summarized. The existing methods, measures and technologies which could solve or relieve the pollution of the printing industry on the environment were brought forward. The suggestions were advanced from country, enterprise, individual to science development aspects. The prospect would be fine with the efforts of the government, enterprise and human being.

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MATSUOKA, Riki. "Printing Inks for Electronics Industry." Journal of Japan Oil Chemists' Society 35, no. 10 (1986): 835–42. http://dx.doi.org/10.5650/jos1956.35.835.

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Nethercott, James R. "Dermatitis in the Printing Industry." Dermatologic Clinics 6, no. 1 (January 1988): 61–66. http://dx.doi.org/10.1016/s0733-8635(18)30690-9.

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Kiurski, J. S., B. B. Marić, S. M. Aksentijević, I. B. Oros, and V. S. Kecić. "Occupational hazards in printing industry." International Journal of Environmental Science and Technology 13, no. 3 (January 25, 2016): 955–72. http://dx.doi.org/10.1007/s13762-016-0937-z.

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Koo, Jing Wee, Jia Shin Ho, Jia An, Yi Zhang, Chee Kai Chua, and Tzyy Haur Chong. "3D Printing in the Water Treatment Industry." Diffusion Foundations and Materials Applications 31 (November 30, 2022): 1–5. http://dx.doi.org/10.4028/p-s3n109.

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The advancement of 3D printing in the past few decades propelled many ground-breaking developments in the water treatment industry. More specifically, 3D printing has the unique advantage of prototyping parts of high complexity with acute precision within a short period of time. Innovative feed spacers and membranes, which could not be fabricated using conventional methods, can now be 3D printed and evaluated in actual filtration experiments. However, there are still limitations to 3D printing such as the printing resolution, build volume and printing speed which poses some problems, especially in the fabrication of membranes. This paper presents a comprehensive and critical discussion on the 3D printed feed spacer and membrane prototypes from a 3D printing perspective.

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Khristiani Suhari, Dian, and Peni Pujiastuti. "Chemical Oxygen Demand (COD) Analysis Ink Printing Waste Water Using Titrimetry Method." Jurnal Kimia dan Rekayasa 1, no. 1 (July 8, 2020): 24–31. http://dx.doi.org/10.31001/jkireka.v1i1.9.

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The printing industry produces wastewater from the ink used. Contains organic and inorganic pollutants such as lead, cadmium, chromium and zinc. Having a quality that exceeds the quality standards for wastewater. If it is discharged into the environment it can pollute the receiving water body. Need to do an analysis of organic pollutant content, by measuring the parameters of Chemical Oxygen Demand (COD). Determination of COD numbers in printing industry wastewater ink using titrimetry method (SNI 6989.73: 2009). Perform oxidation-reduction titration using Ferro Ammonium Sulfate (FAS) solution in printing industry ink wastewater. This study conducted three sampling replications. The results of the first day research obtained a COD rate of 33,088 mg /L; second day 69,694.6 mg /L; third day 67,830.4 mg /L. All three samples had COD figures exceeding the printing industry wastewater quality standard of 125 mg / L. Printing industry wastewater is not suitable to be discharged into the environment. Abstrak Industri percetakan menghasilkan limbah cair dari tinta yang digunakan. Mengandung polutan organik dan anorganik seperti timbal, kadmium, kromium, dan zink. Memiliki kualitas yang melebihi baku mutu air limbah. Apabila dibuang ke lingkungan dapat mencemari badan air penerima. Perlu dilakukan analisis kandungan polutan organik, dengan mengukur parameter Chemical Oxygen Demand (COD). Penentuan angka COD pada air limbah tinta industri percetakan dengan menggunakan metode titrimetri (SNI 6989.73:2009). Melakukan titrasi oksidasi-reduksi menggunakan larutan Ferro Amonium Sulfat (FAS) pada sampel air limbah tinta industri percetakan. Penelitian ini melakukan tiga kali ulangan sampling. Hasil penelitian hari pertama diperoleh angka COD sebesar 33.088 mg/L; hari kedua sebesar 69.484,6 mg/L; hari ketiga sebesar 67.830,4 mg/L. Ketiga sampel memilik angka COD melebihi baku mutu air limbah industri percetakan sebesar 125 mg/L. Air limbah tinta industri percetakan tidak layak dibuang ke lingkungan.

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Husni, Husni Mubarat, Heri Iswandi, and Bobby Halim. "Pelatihan Industri Kreatif Melalui Sablon Manual Bagi Mahasiswa Desain Komunikasi Visual Uinversitas Indo Global Mandiri Palembang." Lumbung Inovasi: Jurnal Pengabdian kepada Masyarakat 7, no. 4 (December 20, 2022): 517–27. http://dx.doi.org/10.36312/linov.v7i4.942.

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Pelatihan industri kreatif melalui sablon melibatkan mahasiswa DKV UIGM sebagai mitra pengabdian. Adapun jumlah anggota mitra yang terlibat sebanyak 32 orang mahasiswa. Pelatihan ini berangkat dari permasalahan dasar yaitu masih kurangnya keterampilan yang dimilki oleh mahasiswa DKV tentang sablon kaos manual. Sementara mahasiswa memilki minat yang tinggi untuk dapat menguasai teknik sablon manual sehingga mahasiswa dapat mengekspresikan ide kreatifnya sebagai seorang DKV. Pelatihan ini bertujuan untuk mengenalkan jenis-jenis alat dan bahan sablon (plastisol) agar mahasiswa dapat menguasai teknik sablon manual sehingga dapat diterapkan sebagai peluang usaha mandiri di bidang industri kreatif. Adapun metode yang digunakan pada kegiatan pelatihan sablon adalah sosialisasi, demonstrasi, praktikum, bimbingan dan metode evaluasi. Adapun hasil kegiatan pelatihan sablon bagi mahasiswa DKV UIGM diantaranya adalah menghasilkan produk fisik sablon baju kaos, peserta mendapatkan ilmu pengetahuan tentang jenis-jenis alat dan bahan sablon, mahasiswa dapat mempraktikkan cetak sablon secara langsung serta dapat memahami proses pembuatan desain menjadi film sablon. Pengetahuan dan pengalaman yang diperoleh mahasiswa DKV UIGM selama pelatihan sablon manual, tentunya menjadi modal berharga untuk membuka usaha mandiri di bidang industri kreatif. Creative Industry Training Through Manual Screen Printing for Visual Communication Design Students at Indo Global Mandiri University Palembang Creative industry training through screen printing for DKV UIGM students departs from a basic problem, namely the lack of skills possessed by DKV students regarding manual t-shirt screen printing. While students have a high interest in being able to master the manual screen printing technique so that students can express their creative ideas as DKV. This training aims to introduce the types of screen printing tools and materials (plastisol) so that students can master manual screen printing techniques so that they can be applied as independent business opportunities in the creative industry sector. The methods used in screen printing training activities are socialization, demonstrations, practicum, guidance and evaluation methods. The results of screen printing training activities for DKV UIGM students include producing physical products for screen printing t-shirts, participants gain knowledge about the types of screen printing tools and materials, students can practice screen printing directly and can understand the process of making designs into screen printing films. The knowledge and experience gained by UIGM DKV students during manual screen printing training is of course a valuable asset to open an independent business in the creative industry.

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Hyun, Eunjung. "The Diffusion of 3D Printing Technology in Korean Industry: Implications for Outdoor Advertising and Sculpture Art Industry." Korean Society of Culture and Convergence 45, no. 3 (March 30, 2023): 523–40. http://dx.doi.org/10.33645/cnc.2023.03.45.03.523.

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This study examines the direction and extent of the diffusion of 3D printing technology in various industries by conducting a comprehensive analysis of domestic 3D printing patents and bibliographic research from 2000 to 2019. 3D printing technology has the potential to revolutionize the way products are designed, developed and manufactured across a wide range of industries. We show that it is likely to have a significant impact on the sculpture art and outdoor advertising sector as 3D printing technology is increasingly being used in product design, architecture, and art. Overall, this study highlights the breadth and depth of the impact that 3D printing technology is likely to have across a wide range of industries, and the potential for it to drive innovation and growth in the coming years.

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S, Hussain. "Overview of 3D Printing Technology." Bioequivalence & Bioavailability International Journal 5, no. 1 (2021): 1–3. http://dx.doi.org/10.23880/beba-16000149.

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The pharmaceutical industry is advancing at an incredible rate. Novel drug formulations for targeted therapy have been developed all thanks to advances in modern sciences. Even so, the manufacturing sector of novel dosage forms is minimal, and the industry continues to rely on traditional drug delivery systems, particularly modified tablets. The use of 3D printing technologies in pharma companies has opened up new possibilities for printed products and device research and production. 3D Printing has slowly progressed from its original use as pre-surgical imaging templates and tooling molds to produce one-of-a-kind instruments, implants, tissue engineering scaffolds, testing platforms, and drug delivery systems. The most significant advantages of 3D printing technologies include the ability to produce small batches of drugs with custom dosages, forms, weights, and drug release profiles. The production of medicines in this manner could eventually contribute to the realization of the principle of personalized medicine. The biomedical industry and academia have also embraced 3D printing in recent years. It offers commercially available medical devices as well as a forum for cutting-edge studies in fields such as tissue and organ printing. This mini-review provides an overview of 3D printed technology in medicines.

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Qu, Zhen Cai. "Innovation in Low Carbon Printing & Packaging." Applied Mechanics and Materials 423-426 (September 2013): 2257–60. http://dx.doi.org/10.4028/www.scientific.net/amm.423-426.2257.

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The connotation of green printing and packaging was discussed, the fact was clarified that green printing and packaging was the inevitable trend of the sustainable development of printing and packaging industry in a low-carbon economy. The major problem faced with the current printing and packaging industry was analysed, effective measures were provided to actively promote the development of green printing and packaging industry, which gives some theoretical guidance to accelerate the development of green printing and packaging.

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Deepak Kumar Sharma, Ambrish Pandey, and Jitender Pal. "Study of VOC emission in printing industries, impact, and its reduction by formulation of guidelines." international journal of engineering technology and management sciences 6, no. 6 (November 28, 2022): 96–99. http://dx.doi.org/10.46647/10.46647/ijetms.2022.v06i06.015.

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Printing industry is a revolutionary field and expanding industry. This research paper gives the description of various operations, performed in gravure, flexography printing industry. Solvent based inks used for these printing processes, and cleaning solvents contain high concentration of VOC. This research examines the effects of VOCs, inks and solvents used in the printing industry. Measures to reduce and manage these impacts are outlined and guidelines have been formulated.

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Talyosef, Orly. "Perspectives on BIM-Based 3D Printing for Sustainable Buildings." Architext 9 (2021): 36–52. http://dx.doi.org/10.26351/architext/9/3.

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Three-dimensional (3D) printing, also called additive manufacture (AM), is a novel, automated method of printing a structure layer-by-layer directly from a 3D digital design model. Its potential ability to build complex shapes in a less costly and more sustainable manner may revolutionize the construction industry. There are three main 3D printing techniques: (a) contour crafting; (b) concrete printing, and (c) D-shape. As a disruptive technology, 3D printing creates a new market and value network, thus disturbing the established market. Building information modeling (BIM) is a comprehensive management approach encompassing the entire life cycle of the architecture and construction (A&C) process, including architectural planning, geometrical data, scheduling, material, equipment, resource and manufacturing data, and post-construction facility management. By maintaining safety and productivity in large-scale digital processes, BIM is critical to 3D printing’s success in construction. Integrating BIM and 3D printing techniques into A&C can potentially lead to an ecological architectural process that reduces waste and energy inefficiency, and prevents injuries and fatalities on construction sites, while increasing productivity and quality. This paper examines BIM-based 3D printing of sustainable buildings, which may revolutionize the construction industry and contribute to a sustainable environment

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Lizunova, I. V., and E. A. Stepanov. "Activities of the Publishing and Printing Enterprises of the Siberian-Far East Region at the Early XXI Century." Bibliosphere, no. 4 (February 4, 2022): 50–58. http://dx.doi.org/10.20913/1815-3186-2021-4-50-58.

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The article concerns the problems of functioning the publishing and printing industry in Siberia and the Far East at the early XXI century: peculiarities of its infrastructure forming, entering the country’s printing services market, the place of a region in it. The paper objective is to represent the modern publishing and printing industry in Siberia and the Far East, its structural components, and determine the likely directions for further development of the regional market to printing product and service producers. The article reveals that, at the region territory, there are printing enterprises of various forms of ownership, production scale, printing technologies used, producing practically all types of publishing products of a wide range – from text editions to special ones. The leaders of the modern printing industry in the region are still the largest regional/area printing houses/media holdings - the flagships of the printing industry of certain territories in terms of provided products and services. At the same time, small printing enterprises start to play an increasing role, responding more flexibly and quickly to changes in consumer demand, changes and challenges of the printing services market. Their number in the region is quite large. The basis of small printing enterprises are district/city printing houses, print shops, advertising agencies, mini-printing houses, publishing centers. One can observe the continuation of the activity diversification of the largest printing houses in the region and the general digitalization of the activities of enterprises in the industry.

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Kotlyarevskyy, Ya V. "Innovative Process Development Trend in the Publishing and Printing Industry." Science and innovation 11, no. 2 (March 30, 2015): 5–18. http://dx.doi.org/10.15407/scine11.02.005.

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Guo, Ling Hua, Mei Yun Zhang, Xin Hua Guo, and Qian Zhu. "Research on the Color Models of the Heat Transfer Printing Paper." Advanced Materials Research 236-238 (May 2011): 1332–35. http://dx.doi.org/10.4028/www.scientific.net/amr.236-238.1332.

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The heat transfer printing is a new application of printing to textile industry. At present, there are no unified standards and parameters. In this paper, The parameters such as printing density, printing color gamut, the color efficiency of heat transfer printing papers and fabrics are tested. The evaluated printing quality parameters are put forward, therefore the reference standards are provided the reliable guidance for the heat transfer printing industry.

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Kvam, Bård MN, Pål Rikard Romundstad, Paolo Boffetta, and Aage Andersen. "Cancer in the Norwegian printing industry." Scandinavian Journal of Work, Environment & Health 31, no. 1 (February 2005): 36–43. http://dx.doi.org/10.5271/sjweh.846.

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Deaky, Bogdan, and Luminița Pârv. "ERP system for 3D printing industry." MATEC Web of Conferences 94 (2017): 06005. http://dx.doi.org/10.1051/matecconf/20179406005.

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TAKAYAMA, Michio. "The Trend of Printing Ink Industry." Journal of Japan Oil Chemists' Society 41, no. 9 (1992): 992–95. http://dx.doi.org/10.5650/jos1956.41.992.

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Mundschenk, Martin, and Andreas Drexl. "Workforce planning in the printing industry." International Journal of Production Research 45, no. 20 (August 31, 2007): 4849–72. http://dx.doi.org/10.1080/00207540600813238.

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Burke, Gerry. "Using Ergonomics in the Printing Industry." AAOHN Journal 56, no. 1 (January 2008): 41–43. http://dx.doi.org/10.1177/216507990805600105.

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Davis, Ronnie H. "Business Economics and the Printing Industry." Business Economics 49, no. 2 (April 2014): 122–26. http://dx.doi.org/10.1057/be.2014.9.

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Dubrow, Robert. "Malignant melanoma in the printing industry." American Journal of Industrial Medicine 10, no. 2 (1986): 119–26. http://dx.doi.org/10.1002/ajim.4700100203.

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Mclaughlin, Joseph K., Hans S. R. Malker, William J. Blot, Jan L. E. Ericsson, Gosta Gemne, and Joseph F. Fraumeni. "Malignant melanoma in the printing industry." American Journal of Industrial Medicine 13, no. 2 (August 31, 2010): 301–4. http://dx.doi.org/10.1002/ajim.4700130211.

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Urban, Wiesław, and Krzysztof Łukaszewicz. "Towards a Self-Service Approach in the Printing Industry. An Investigation of State of the Art Technologies Along with Industry 4.0 Changes." Multidisciplinary Aspects of Production Engineering 4, no. 1 (September 1, 2021): 232–44. http://dx.doi.org/10.2478/mape-2021-0021.

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Abstract It is commonly believed that the current economic state of many countries is at the stage of the fourth industrial revolution. The changes resulting from this revolution are affecting all sectors of the economy, including the printing sector. The aim of this article is to analyse the state of the art technology in sheetfed printing and then to identify the challenges for further changes in the technology of this type of printing as well as technological and organisational changes in the processes of preparation and realisation of printing products. The article uses case studies of selected technologies offered by key technology suppliers in this area and case studies of selected business entities – manufacturers of printing products. The research approach adopted in this article also takes conceptual work into account. It was found that the observed changes in the printing industry are consistent with the assumptions of the Industry 4.0 concept in the aspect of the digitisation and mass personalisation of products, which leads to the thesis that in the future personalised digital printing ordered through self-service will play a dominant role.

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Makatora, Alona V., Dmytro A. Makatora, and Ruslan A. Kubanov. "Using ICT in Printing: Economic Transformation, Evolution and Prospects." Business Inform 12, no. 551 (2023): 106–13. http://dx.doi.org/10.32983/2222-4459-2023-12-106-113.

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The purpose of the study is to determine the peculiarities of the use of information and communication technologies in the printing industry; to substantiate the feasibility of technological transformation in terms of the prospects for economic development of the selected industry. Processing of primary data to provide the user with the necessary information is the main task of using information technology in the printing industry. Three main blocks – knowledge base, decision-making and intellectual interface – make up the structure of an intelligent printing system. In terms of decision-making, an intelligent printing system is defined as an information and computer system with artificial intelligence that solves problems without human intervention, in contrast to an intelligent system where the operator is involved in the decision-making process. The following types of intelligent systems are identified: intelligent information systems, expert printing systems, computational and logical systems, hybrid intelligent systems, reflex intelligent systems. It is noted that taking into account market trends, adapting to the environment and quickly adjusting their development strategy to occupy their niche in the market is important for the successful functioning of publishing and printing companies. According to the authors, this is possible based on using ICT in printing. Integrating modern technologies into the printing industry can positively influence efficiency and competitiveness. Adopting digital technologies will allow printing companies to be more flexible and respond quickly to changing market conditions, which is important for its development. In conclusion, it can be said that information and communication technologies have a great potential for the transformation of the printing industry in Ukraine. Companies will be able to automate and optimise production processes, reduce costs and improve product quality through the introduction of modern technologies. In addition, by introducing new print formats and creating specialised products for the digital market, the development of information technology will expand the range of services. According to the authors, this approach will help Ukrainian companies to compete internationally and take their products to new markets, helping to develop the whole industry. In addition, there will be a stimulus for innovation and the development of new services, which in turn will contribute to the growth of the industry as a whole

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Abiodun, D. A., and R. O. R. Kalilu. "AN ANALYSIS OF THE STRENGTHS AND CHALLENGES OF DIRECT IMAGING AND COMPUTER TO PLATE OFFSET PRINTING TECHNOLOGIES: THE NIGERIAN EXPERIENCE." Art and Design, no. 2 (August 10, 2023): 40–52. http://dx.doi.org/10.30857/2617-0272.2023.2.4.

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The aim of this study is to explore Direct Imaging (DI) and Computer to Plate (CtP) printing technologies in Nigeria with a view to determining sustainability of DI printing standard. Methodology: Content analysis through direct field investigation, which included participant observation and key informant interview was engaged. The data collected for the comparative analysis of the strengths and challenges of DI and CtP printings were between May 2014 and June 2021. Results: This study identified high start-up cost and unavailability of spare parts and technicians as the main challenges in the use of the two technologies in Nigeria and consequent upon which there is no longer functional offset DI press in Nigeria. The CtP presses that survived continue to provide the super quality printing standard set up by the DI technology. Scientific novelty: The study discovered CtP print quality as equivalent to DI super print standard, thereby providing basis for sustainable development of DI standard in Nigerian printing industry. Practical Significance: The findings of this research have practical implications on printing industry, delivery of communication design and the Nigerian economy. The identified strength of CtP indicates availability of super print quality this far in the country, as a result create avenue for sustainable development in the affected sectors in Nigeria.

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Asad, Hassan, Khan Ihsanullah, and Muhammad Javaid. "Applications and Prospects of 3D Printing in the Packaging Industry." International Journal of Advanced Engineering Research and Science 10, no. 1 (2023): 055–61. http://dx.doi.org/10.22161/ijaers.101.9.

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In this paper four 3D printing technologies fused deposition modeling (FDM), selective laser sintering (SLS), stereo lithography appearance (SLA), and laminated object manufacturing (LOM) were examined for their characteristics its applications. Technology for 3D printing Since the 1980s, when the field of applications first began to take off, rapid advancement has been made. Materials for 3D printing have been introduced. In order to build items with a variety of shape, size, rigidity, and color, it entails layering materials such as plastics, composites, or biomaterials. Another innovation was the use of 3D printing in the engineering of packaging. It has been noted that the benefits of 3D printing technology in the packaging business are unmatched by other comparable packaging production technologies, and that 3D printing technology has a very broad range of competitive advantage through innovation in the future packaging industry. The development of 3D printing raw material technology determines the development of 3D printing technology Development boundary. It has high requirements on the purity, sphericity, particle size distribution, bulk density, oxygen content, fluidity and other properties of metal powder materials.

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Pirozhkova, Tatyana. "Typographers of the Crimean ASSR in the 1920s and 1930s: Personnel Characteristics." Journal of Economic History and History of Economics 23, no. 1 (March 18, 2022): 84–107. http://dx.doi.org/10.17150/2308-2488.2022.23(1).84-107.

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The article uncovers some questions of the labor history of printing production workers in the Crimean ASSR in 1920–1930s. The aim of the article is investigation of the staff structure of the Crimean ASSR printing industry workers in comparison with the national structure. The objectives of the study are to examine the dynamics of the number of workers in the printing industry of the Crimea, to analyze the proportion of women, national personnel (Crimean Tatars), adolescents, skilled workers in the overall structure of the printing industry workers of the Crimean ASSR, and to compare the obtained results with the national indicators. The study is based on published statistics, reports and archival sources. As a result, the author concludes that the labor force of the Crimean ASSR printing industry developed in line with nationwide trends, but with certain specifics. The growth in the number of printing workers, typical for the country as a whole, was uneven in Crimea and its rate was somewhat lower than in the rest of the country. The increase in the proportion of women in the Crimean printing industry at the beginning of the considered period was somewhat lower than the statistical average; in the 1930s it generally corresponded to the national and industry averages. The personnel policy was based on the requirements of indigenization and implied the recruitment of workers of Crimean Tatar nationality; however, the level of indigenization in the printing industry did not reach the required indicators. Work on the involvement of adolescents was carried out, but there were problems with the training organization. The number of qualified personnel in the republic's printing industry was insufficient, which had an impact on the product quality. In conclusion, the author forms the tasks for further research into the labor history of printing production workers in the Crimean ASSR.

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Ulrikh, E. V., and V. V. Verkhoturov. "Features of food design on a 3D printer. A review." Food systems 5, no. 2 (July 11, 2022): 100–106. http://dx.doi.org/10.21323/2618-9771-2022-5-2-100-106.

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3D printing technology attracts considerable attention due to its versatility and possibility of using in different industries such as the aerospace industry, electronics, architecture, medicine and food industry. In the food industry, this innovative technology is called food design. 3D printing is a technology of additive manufacturing, which can help the food industry in the development of new and more complex food products and potentially help manufacture products adapted to specific needs. As a technology that create foods layer by layer, 3D printing can present a new methodology for creating realistic food textures by precise placement of structuring elements in foods, food printing from several materials and design of complex internal structures. In addition to appearance and taste, food consistency is an important factor of acceptability for consumers. The elderly and people with dysphagia not infrequently suffer from undernutrition due to visual or textual unattractiveness of foods. The aim of this review is to study the available literature on 3D printing and assess recent developments in food design technologies. This review considers available studies on 3D food printing and recent developments in food texture design. Advantages and limitations of 3D printing in the food industry, possibilities of printing based on materials and consistency based on models as well as future trends in 3D printing including technologies of food preparation by printing on food printers are discussed. In addition, key problems that prevent mass introduction of 3D printing are examined in detail.

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Malik, Abrar, Mir Irfan Ul Haq, Ankush Raina, and Kapil Gupta. "3D printing towards implementing Industry 4.0: sustainability aspects, barriers and challenges." Industrial Robot: the international journal of robotics research and application 49, no. 3 (January 18, 2022): 491–511. http://dx.doi.org/10.1108/ir-10-2021-0247.

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Purpose Environmental degradation has emerged as one of the major limitations of industrial revolution and has led to an increased focus towards developing sustainable strategies and techniques. This paper aims to highlight the sustainability aspects of three-dimensional (3D) printing technology that helps towards a better implementation of Industry 4.0. It also aims to provide a brief picture of relationships between 3D printing, Industry 4.0 and sustainability. The major goal is to facilitate the researchers, scholars, engineers and recommend further research, development and innovations in the field. Design/methodology/approach The various enabling factors for implementation of Industry 4.0 are discussed in detail. Some barriers to incorporation of 3D Printing, its applications areas and global market scenario are also discussed. A through literature review has been done to study the detailed relationships between 3D printing, Industry 4.0 and sustainability. Findings The technological benefits of 3D printing are many such as weight savings, waste minimization and energy savings. Further, the production of new 3D printable materials with improved features helps in reducing the wastage of material during the process. 3D printing if used at a large scale would help industries to implement the concept of Industry 4.0. Originality/value This paper focuses on discussing technological revolution under Industry 4.0 and incorporates 3D printing-type technologies that largely change the product manufacturing scenario. The interrelationships between 3D printing, Industry 4.0 and sustainability have been discussed.

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Najmuddin, Faiz. "Sistem Informasi Online Pemesanan Dan Penyedia Informasi Jasa Percetekan Bersasis Web." INTECH 4, no. 1 (May 29, 2023): 13–17. http://dx.doi.org/10.54895/intech.v4i1.1964.

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The printing industry has both positive and negative impacts on customers. One of the negative impacts is the inconsistent quality of printed products. To address this issue, the team developed the Web Nugraha Offset application, designed using Canva, Visual Studio Code, Notepad++, Figma, MySQL, HTML, CSS, PHP, JavaScript, and Bootstrap. This web-based application aims to help customers access information about the printing industry and its services before physically visiting the printing industry. This application's primary feature isprovidinge information on printing tools andallowing customers to orderg products online. The target audience for this application is customers who want to easily access information about printing services and products. The team's methodology involved developing a web-based application that integrates customer needs, printing industry standards, and modern web design techniques. The conclusion is that Web Nugraha Offset is an effective solution for customers seeking reliable printing services and an improved customer experience.

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Richardson, Victoria. "3D printing becomes concrete: exploring the structural potential of concrete 3D printing." Structural Engineer 95, no. 10 (October 2, 2017): 10–17. http://dx.doi.org/10.56330/qvsi5222.

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Three-dimensional (3D) printing is celebrated as part of the next Industrial Revolution, in which automation and artificial intelligence will transform the construction industry. It is at the forefront of building innovation and has the potential to have a revolutionary effect on how structures are built. We are not the first industry to seek the benefits of robotically controlled, free-form manufacture: the medical, automotive and aeronautical industries are just some areas where 3D printed parts are now offered as standard products or component parts. 3D printing has proved particularly successful where rapidly produced, low-cost, unique products are needed. A recent surge in mass customisation has enabled industry to produce custom-made shoes printed to the form of one’s foot or to tailor a life-changing prosthesis adapted to one’s individual shape and size. In this article, Victoria Richardson, winner of the Institution's Pai Lin Li Travel Award 2016, discusses her research to explore how structural engineering and the construction industry can benefit from 3D printing.

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Mike, FM Chungu. "Impacts of new printing technology on old conventional technologies." i-manager’s Journal on Future Engineering and Technology 19, no. 3 (2024): 17. http://dx.doi.org/10.26634/jfet.19.3.20679.

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The movable type printing press was the signal innovation in early modern information technology, but economists have found no evidence of its impact on measures of aggregate productivity or income per person. This paper examines the impact technological advancement has brought to the printing industry. The printing industry has witnessed drastic changes in the machines used in this industry, such as automation and the elimination of other processes previously done. Additionally, it explores how the emergence of electronic media has affected the production of print media, leading to a decline in print media production. New technologies have benefited printing companies by reducing expenditures through the employment of fewer staff, but this also minimizes job opportunities in the printing industry. The paper also investigates whether printing companies and printers are satisfied with the new technologies being introduced.

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Viziteu, Diana-Roxana, and Antonela Curteza. "3D PRINTING TECHNOLOGY IN TEXTILE AND FASHION INDUSTRY." Fashion Industry, no. 3 (January 14, 2021): 41–44. http://dx.doi.org/10.30857/2706-5898.2020.3.2.

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The extraordinary thing about the application of 3D printing technology is that it can be used to create accessible items customized to personal needs. In the fashion industry, there is a need for individualized protective equipment. The possibility of applying new technologies such as 3D modelling of protective elements that can be made by using 3D printers is presented in this paper. 3D modelling and additive technologies (3D printing) can be used in the development of protective work clothing. The fabrication process only requires the digital fi le with the 3D model and the right material - we chose to use thermoplastic polyurethane (TPU).The design samples were constructed and modelled using a software program called Rhinoceros. The samples can be integrated into the clothing item, in order to follow the body shape and to provide the necessary protection. Purpose. This paper aims to explore the applicability of 3D printing materials using thermoplastic polyurethane (TPU) for the development of protective gear. Scientifi c novelty. 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. Practical value. One of the most signifi cant 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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Koshechkin, K. A., O. L. Lebed, and Yu A. Levushkina. "The possibilities of using 3D printing in pharmaceutical industry." Farmacevticheskoe delo i tehnologija lekarstv (Pharmacy and Pharmaceutical Technology), no. 3 (June 20, 2023): 19–27. http://dx.doi.org/10.33920/med-13-2303-02.

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This article discusses the possibilities of using 3D printing technologies in the pharmaceutical industry, including concrete examples that are already applied in practice. The advantages and problems that arise with active spread of these technologies are described. In addition, after the emergence of any new technology, its introduction into social and public life is crucial, therefore, this article provides specific examples of the legal status and regulation of 3D printed products and discusses its general principles. The importance of the development of 3D printing in the medical and pharmaceutical industries is highlighted from various perspectives, including medical and economic ones. This article is devoted to the use of 3D printing technology for medical purposes. It considers the potential of using 3D printing in various pharmaceutical fields. The paper describes some examples of various applications of 3D printing in medicine and examines the advantages and disadvantages of this technology. Finally, we suggest a prognosis for the future use of 3D printing in medicine and the principles of designating its legal status, with specific examples.

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Cheng, Chang Xian. "Defense the Green Position of Graphic Communications Industry and Find Ways to Make it Greener." Advanced Materials Research 910 (March 2014): 410–14. http://dx.doi.org/10.4028/www.scientific.net/amr.910.410.

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Graphic communications industry, or printing industry, has a tradition of more than one thousand years. Putting ink on paper, or on some other substrates, is the basic form of printing, although the industry has been modernizing by the up-to-date science and technology such as internet communication and digital printing, etc., since the info-tech revolution of recent decades. Printing jobs are still in much need today and printing presses everywhere are keeping busy with a steady influx of orders everyday. As a professor working in the graphic communications field, facing some perception and confusions among everyone from government and corporations to environmental groups and mums and dads that paper and print is 'bad' for the environment and that printed communications aren't effective, we have responsibilities to study the present situation of this industry in the environment-oriented world and try as much as possible to find ways to make our industry become greener. Firstly, we need to answer if the printing communication is not a green medium comparing to other methods of communication. If the answer is positive, we need to defense the green position of the graphic communications industry. Secondly, to troubleshoot the pollution problems of the printing production processes, so that, thirdly, to find ways to make the industry become an environment-friendly one.

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Gorbunova, Nataliya A. "POSSIBILITIES OF ADDITIVE TECHNOLOGIES IN THE MEAT INDUSTRY. A REVIEW." Theory and practice of meat processing 5, no. 1 (April 16, 2020): 9–16. http://dx.doi.org/10.21323/2414-438x-2020-5-1-9-16.

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Three-dimensional printing (3D printing) is a rapidly developing market of digital technologies with a huge potential for food production, which gives an opportunity to create new food products with the improved nutritional value and sensory profile, and adapted for a particular consumer. The review presents historical aspects of the development of the additive technologies and their classification, examines advantages and drawbacks of the 3D food printing, discusses key aspects of safety of three-dimensional food printing and probable peculiarities of their labeling, analyzes potential possibilities of using the 3DP technology for meat processing and aspects influencing the possibility of printing and following processing of 3D printed meat products.

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Sardanto, Rino, and Dani Rahman. "Strategi Inovasi Sablon Shift Untuk Meningkatkan Daya Saing Pasca Covid-19 Di Industri Sablon Kaos." Jurnal Ilmiah Ekonomi Global Masa Kini 14, no. 1 (July 12, 2023): 44–50. http://dx.doi.org/10.36982/jiegmk.v14i1.3127.

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Screen Printing Shift Nganjuk is an industry engaged in screen printing and printing services which was founded in 2016. Screen Printing Shift Nganjuk is now competing for business profits through one of the superior products found in the business or has its own uniqueness from a business that makes the screen printing industry in Nganjuk Regency has great potential to be developed in the development of its potential. the obstacle faced by Sablon Shift Nganjuk and at the same time the weakness of an industry is the lack of market information and the need for new innovations to gain new market share. The purpose of this study is to find out SWOT analysis to improve new innovation strategies that can be applied to Nganjuk Shift Screen Printing to be developed in the t-shirt screen printing industry, as well as to find out the implementation of the 4P marketing mix strategy that can help Nganjuk Shift Screen Printing in increasing competitiveness in the t-shirt screen printing industry. . Data was collected through interviews with informants who had been selected by the researcher. The results of this research are expected to be one of the references and inputs for developing innovation strategies and marketing strategies in order to increase sales after the Covid-19 pandemic. Innovation strategies to increase competitiveness in Screen Printing Shift can be carried out through new innovations in SWOT analysis and marketing mix. By creating new innovations, it is hoped that it can help increase competitiveness after COVID-19. Keywords: SWOT, Marketing Mix, Innovation, Marketing

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Alabi, Micheal Omotayo. "Big Data, 3D Printing Technology, and Industry of the Future." International Journal of Big Data and Analytics in Healthcare 2, no. 2 (July 2017): 1–20. http://dx.doi.org/10.4018/ijbdah.2017070101.

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This article describes how 3D printing technology, also referred to as additive manufacturing (AM), is a process of creating a physical object from 3-dimensional digital model layers upon layers. 3D printing technologies have been identified as an emerging technology of the 21st century and are becoming popular around the world with a wide variety of potential application areas such as healthcare, automotive, aerospace, manufacturing, etc. Big Data is a large amount of imprecise data in a variety of formats which is generated from different sources with high-speed. Recently, Big Data and 3D printing technologies is a new research area and have been identified as types of technologies that will launch the fourth industrial revolution (Industry 4.0). As Big Data and 3D printing technology is wide spreading across different sectors in the era of industry 4.0, the healthcare sector is not left out of the vast development in this field; for instance, the Big Data and 3D printing technologies providing needed tools to support healthcare systems to accumulate, manage, analyse large volume of data, early disease detection, 3D printed medical implant, 3D printed customized titanium prosthetic, etc. Therefore, this article presents the recent trends in 3D printing technologies, Big Data and Industry 4.0; including the benefits and the application areas of these technologies. Emerging and near future application areas of 3D printing, and possible future research areas in 3D printing and Big Data technologies as relating to industry 4.0.

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Geng, Songyuan, Wujian Long, Qiling Luo, Junen Fu, Wenya Yang, Huanzhou He, Qiubing Ren, and Chuanglian Luo. "Intelligent Prediction of Dynamic Yield Stress in 3D Printing Concrete Based on Machine Learning." Advances in Engineering Technology Research 6, no. 1 (July 19, 2023): 468. http://dx.doi.org/10.56028/aetr.6.1.468.2023.

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Applying 3D printing technology to the construction industry can bring many benefits. However, due to the specificity of 3D printing technology, its application in the construction industry has not yet been promoted. Machine learning (ML) techniques, which are popular at this stage, are expected to provide solutions to these problems. Rheological properties have been a key parameter for the quality of 3D printing concrete, and its accurate prediction can help to integrate 3D printing technology into the construction industry. In this study, a GA-RF model for predicting the dynamic yield stress (DYS) of 3D printing concrete is proposed for the first time, and the hyperparameters of the RF model are intelligently tuned during the training process. In addition, the importance analysis of the input parameters is performed. The results show that the developed prediction model has a high accuracy and the SF content has the most significant effect on DYS. The research results help to advance the construction industry to mass production of 3D printing concrete.

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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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C., Juan José Encinas, and Mario Chauca. "Radial Precision Printing for the Textile Industry Controlled by Fuzzy Logic." International Journal of Materials, Mechanics and Manufacturing 7, no. 2 (April 2019): 72–76. http://dx.doi.org/10.18178/ijmmm.2019.7.2.433.

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Rastogi, Mohit, Vipul Pancholi, K. N. Anantha Subramanya Iyer, and Yamini Kaushik. "A systematic review of the variety of printing in the construction industry and its effect on the labor market." Multidisciplinary Reviews 6 (March 24, 2024): 2023ss027. http://dx.doi.org/10.31893/multirev.2023ss027.

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The construction sector is one of the main employers worldwide and requires a lot of labor. For decades, the industry had little technological advancement and low output. In recent decades, there has been an increasing interest in various automation technologies, such as 3D printing, by the construction sector. It has been discovered that 3D printing holds great promise for automating building processes. It can reduce dangerous human operations, labor-intensive tasks, wasteful material use, construction time and more. A substantial amount of research has been done to comprehend the most recent developments, potential benefits and difficulties associated with the widespread use of 3D printing in construction projects. In this study, we review the labor-intensive industry of construction and any possible implications for the labor market from the increasing use of 3D printing. Empirical studies have indicated that 3D printing might mitigate the labor shortage by reducing the manpower needed, especially in countries where immigration is a major factor in the construction industry. However, in nations where labor is less expensive and construction is the primary industry, 3D printing cannot be advantageous. The findings indicate that the construction industry might benefit from 3D concrete/construction printing (3DCP) in terms of labor-intensive requirements, worker safety, as well as quicker construction and less wasteful material use.

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Journal articles on the topic 'Printing industry'

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