Your search keyword '"Printing ink"' showing total 4,135 results

1. The role of fibre bonds in permanent curl of paper and how it is affected by crosslinking.

Author

Maaß, Alexander, Selinger, Julian, and Hirn, Ulrich

Subjects

WETTING agents, PRINTING ink, PRODUCT quality, CELLULOSE, WETTING

Abstract

Irreversible deformation of paper is a challenge for both printer operation and product quality, particularly in inkjet printing with water-based inks. Here we are investigating permanent paper curl, which is the residual curl of paper after drying of the ink (i.e., it is not the immediate paper curl due to wetting). The key aim of this work was to test the hypothesis that permanent paper curl is created by partial opening and rearrangement of the fibre–fibre bonds in the wetted paper layer. In order to test this hypothesis, we produced paper with crosslinked fibre–fibre bonds that do not open in the presence of water. Polyamideamine epichlorohydrin (PAE) and 1,2,3,4-butanetetracarboxylic acid were used as crosslinking agents and properties of the treated paper samples were analysed. Both agents led to significantly improved wet strength of the papers, furthermore we indeed found that the permanent curl of crosslinked papers was strongly reduced. Other curl related mechanisms like differences in fibre swelling, paper hydroexpansion and liquid penetration were not able to explain the reduction in curl. The finding that the creation of fibre–fibre bonds unaffected by water prevents permanent curl of paper after wetting and redrying leads to the conclusion that the mechanism for creating permanent paper curl after wetting is related to the partial opening and rearrangement of fibre–fibre bonds in the wetted paper. Possible pathways to apply these findings to paper production are discussed, for example switchable or temporary wet strength agents. [ABSTRACT FROM AUTHOR]

Published

2024

2. The application of dairy products and their derivatives as edible inks in 3D printing technology: A review.

Author

Dou, Xinyue and Ren, Junning

Subjects

*THREE-dimensional printing, *PRINTING ink, *RHEOLOGY, *NUTRITIONAL value, *DAIRY processing

Abstract

Summary: Three‐dimensional (3D) printing technology digitally designs and manufactures objects through computer‐controlled processes. It requires raw materials with specific rheological properties for extrusion and shape retention. Dairy products hold promise for 3D printing due to their ability to form structures and their nutritional value. However, the quality of 3D printing with dairy products relies on the properties of the printing ink and printer parameters, presenting challenges for practical applications. This work provided a summary of the suitability of dairy‐based 3D printed products, discussing physicochemical modifications and additives to enhance their suitability and nutritional properties. The internal structure and composition of printing inks derived from dairy products are closely linked to their printing performance. Physicochemical modifications and additives effectively improve printability and the nutritional aspects of dairy inks. The 3D printing suitability of dairy inks can be enhanced through physical, chemical or enzymatic treatments. The gel properties of dairy products can be improved by mixing them with hydrophilic gels, introducing calcium, and incorporating lipids to enhance the 3D printing performance of dairy products. 3D printing technology enables the customisation of dairy products with personalised control of nutritional content, meeting the increasing consumer and market demand for healthier foods. In the future, 3D printed dairy products are expected to constitute convenient and quick nutritious food and enter home kitchens. [ABSTRACT FROM AUTHOR]

Published

2024

3. Anomalous Temperature Effect on the Deposition Morphology in Reactive Inkjet Printing.

Author

Sreenivasan Narayanan, Sreenivasan, Bender, Tyler, Kanungo, Mandakini, and Zhao, Hong

Subjects

PRINTING ink, COPPER, PRINTED electronics, NANOPARTICLES, TEMPERATURE effect

Abstract

Reactive inkjet (RIJ) printing represents an important approach for printed electronics. Different from the traditional inkjet printing of colloidal inks with nanosized metal particles, RIJ prints the solution of metal organic compound, that is, metal‐organic decomposition (MOD) ink, and reduces it to the pure metal during the post‐treatment to form conductive electrodes. Successful RIJ printing of MOD inks has been demonstrated; however, the fundamental understanding of droplet deposition involved in RIJ printing is lacking. Herein, the effect of substrate temperature and nozzle temperature during inkjet printing of copper MOD ink on the deposition morphology is investigated. It exhibits distinct behaviors in the deposition morphology at elevated temperatures when compared with the ones at room temperature. The different deposition morphology of the copper ink at various temperatures is attributed to the generation of a localized seeding layer which attracts the copper ions to deposit. In addition, the copper MOD ink printing is compared with a silver MOD ink. The different deposition morphology between the copper ink and silver ink is due to the solvent system. Understanding the deposition mechanism for reactive inks provides valuable information and guidance in the fabrication of printed functional devices using particle‐free reactive inks. [ABSTRACT FROM AUTHOR]

Published

2024

4. Towards Photocrosslinkable Lyotropic Blends of Organosolv Lignin and Hydroxypropyl Cellulose for 3D Printing by Direct Ink Writing.

Author

Yapa, Mehmet-Talha, Lalevée, Jacques, and Laborie, Marie-Pierre

Subjects

*PRINTING ink, *THREE-dimensional printing, *HYDROXYL group, *BIOPOLYMERS, *PHOTOCROSSLINKING

Abstract

Polymer blends containing up to 70% organosolv lignin content and lyotropic cellulose derivatives have been established as "lignin inks" for direct ink writing of fully biobased 3D parts. However, a fast-crosslinking mechanism is needed to improve throughput and design space. In this paper, UV-photocrosslinkable organosolv lignin/hydroxypropyl cellulose inks are formulated through doping with common photocrosslinkers. The most potent photocrosslinkers for neat hydroxypropyl cellulose, lignin and their blends are determined through a series of DOEs. Hydroxypropyl cellulose is significantly more amenable to photocrosslinking than organosolv lignin. The optimal photocrosslinkable ink formulations are printable and exhibit up to 70% gel content, although thermal post-curing remains essential. Chemical, thermal, and mechanical investigations of the photocrosslinked 3D parts evidence efficient crosslinking of HPC through its hydroxyl groups, while lignin appears internally plasticized and/or degraded during inefficient photocrosslinking. Despite this, photocrosslinkable inks exhibit improved tensile properties, shape flexibility, and fidelity. The heterogeneous crosslinking and residual creep highlight the need to further activate lignin for homogeneous photocrosslinking in order to fully exploit the potential of lignin inks in DIW. [ABSTRACT FROM AUTHOR]

Published

2024

5. 含油量及蛋白颗粒含量对高内相Pickering乳液及其 3D打印特性的影响.

Author

吴 超, 刘 哲, 黑 雪, 李闪闪, 焦 博, 陈庆文, 赵 浩, 王 强, and 石爱民

Subjects

MICROGELS, THREE-dimensional printing, LASER microscopy, EMULSIONS, PRINTING ink

Abstract

Copyright of Shipin Kexue/ Food Science is the property of Food Science Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

6. 壳聚糖自组装颗粒与明胶-大豆分离蛋白微胶束 协同构建高内相乳液体系.

Author

石冬雪, 李悦欣, 陈 倩, 刘昊天, and 孔保华

Subjects

FAT substitutes, THREE-dimensional printing, LOW-fat foods, PRINTING ink, MEAT, SOY proteins

Abstract

Copyright of Shipin Kexue/ Food Science is the property of Food Science Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

7. Magnetic Nozzle‐Free Embedded 3D (MagNoFE3D) Printing.

Author

Piñan Basualdo, Franco N., Trikalitis, Vasileios D., Visconti, Sabrina, Ficuciello, Fanny, Goulas, Constantinos, Rouwkema, Jeroen, and Misra, Sarthak

Subjects

*PRINTING ink, *PRINTMAKING, *THREE-dimensional printing, *TISSUE engineering, *MAGNETS

Abstract

The functional principle behind extrusion‐based printing is the capability of flowing material through a nozzle on demand, which must solidify upon deposition, a behavior exhibited only by some materials. Embedded printing offers a solution to maintain shape fidelity during the deposition of a wider range of materials. However, the use of a moving nozzle in a support bath can lead to bath disturbance and the spreading of the ink. In this study, a novel embedded printing technique that eliminates the need for a nozzle by employing a magnetic sphere as the plotting moiety is introduced. The externally steered sphere creates a path by locally fluidizing the bath, allowing the simultaneously injected ink to flow into the space behind it. The method is benchmarked using water as an ink, achieving free‐form printing without additional stabilization methods. The creation of solid structures is also demonstrated by printing a photocurable ink that is crosslinked and removed from the bath. Moreover, the plotting magnet can be incorporated into the printed part during the crosslinking, thus giving place to a magnetically responsive structure. This advancement paves the way for innovations in fields such as tissue engineering and microrobotics by enabling the fabrication of intricate and functional designs. [ABSTRACT FROM AUTHOR]

Published

2024

8. Multi‐Layer LDPE Pouch Robots Enabled by Inkjet‐Printed Masking Layers.

Author

You, Yifan, Dai, Chen, Goldschmidt, Ezequiel, and Fearing, Ronald S.

Subjects

*DEGREES of freedom, *PRINTING ink, *ROBOTS, *POLYETHYLENE, *ACTUATORS

Abstract

Inflatable pouches are attractive as actuators and structural links in soft robots due to their low deflated profile and high deformation ratio. However, current pouch robot fabrication methods have relatively large minimum feature sizes and multi‐layer fabrication challenges, limiting the integration of mechanisms with many independent degrees of freedom (DoF). A new monolithic prototype fabrication method utilizes inkjet printing of a masking ink layer, which prevents film bonding and thus defines inflatable regions. Multi‐layer inflatable pouches of any planar geometry can be created using thermal fusing, with inter‐layer connections and a minimum feature resolution of 0.3 mm. The multi‐layer fabrication process enables the integration of pouches for bending actuation and structure, pneumatic channels, and external port connections. This high level of integration enables the fabrication of pouch robots with many independent DoFs. Specific examples using four layers of 38 micrometer thick Low‐density polyethylene (LDPE) include 1) a 38 mm‐wide 4‐fingered robot hand with 8 independent DoFs which rotates a cube within its palm and 2) a 138 mm‐long planar continuum manipulator with 10 independent DoFs for pick‐and‐place of a cylinder. These example designs demonstrate the capability of ink‐patterned masking to achieve new levels of functionality for thin‐film pouch robots. [ABSTRACT FROM AUTHOR]

Published

2024

9. One‐step Synthesis of UV‐Curable CsPbX3 (X = Cl, Br, and I) Nanocrystal Inks for Printing.

Author

Wang, Yixin, Yin, Yongming, Liu, Ming, Ali, Muhammad Umair, and Meng, Hong

Subjects

*VISIBLE spectra, *METAL halides, *PRINTING ink, *MOLECULAR spectra, *NANOCRYSTALS

Abstract

Metal halide perovskite nanocrystals (NCs) have garnered significant attention due to their captivating optoelectronic properties. One promising application for these materials is their use as color‐conversion layers (CCLs) in blue micro‐LED technology, enabling the realization of full‐color displays. Nonetheless, a pivotal challenge revolves around producing efficient luminescent perovskite inks and subsequently employing them for inkjet printing finely patterned CCLs. In this study, a straightforward single‐step hot‐injection method is introduced for synthesizing inks comprising CsPbX3 NCs, where X represents Cl, Br, and I, or mixed halide systems such as Cl/Br and Br/I. Through precise composition control, the emission spectra can be effortlessly adjusted across the entire visible spectrum, spanning from 410 to 710 nm. The resulting CsPbX3 NCs exhibit narrow emission line‐widths, ranging from 21 to 39 nm, an expansive color gamut encompassing up to 130% of the National Television Standards Committee color standard, and exceptional quantum yields reaching up to 100%. With their superb optical performance, facile synthesis procedure, and robust stability, these CsPbX3 NCs emerge as highly suitable candidates for their use as CCLs with blue light‐emitting devices deployed as backlights. [ABSTRACT FROM AUTHOR]

Published

2024

10. Optimization of flexographic process parameters using taguchi's grey relational analysis technique.

Author

Basak, Soumen, P. C., Saritha, and Paul, Kanai Chandra

Subjects

OPACITY (Optics), SUBSTRATES (Materials science), GREY relational analysis, CELL morphology, PRINTING ink, DECISION making

Abstract

This paper is an experimental and statistical approach to find out an optimal solution for the high print quality reproducible by flexographic printing on coated and uncoated substrate using Taguchi's Grey Relational Analysis method. The halftone image composed of round and square shaped dots with AM screening and the anilox roller with three different screen rulings are employed at different trial runs of experiment. Total of 12 numbers of experimental runs with different combinations of paper grades, halftone dot shapes and anilox roller rulings are employed in the experiment to investigate its influence on the final print quality. The print quality evaluation is based on the assessment of Optical Ink Density (solid areas), Dot Gain, Hue Error and Print Contrast using Taguchi's Grey Relational Analysis method. Based on the Taguchi's GRA score, the optimal solution for the high print quality is prioritized. This paper aims to distinguish the influence of substrate, halftone dot shape and anilox cell ruling in the final print quality of flexographic process. Also, it demonstrates the scope of applying Taguchi's Grey Relational Analysis in the printing field to find out an optimal solution for the multiple criteria-based decision-making activities. [ABSTRACT FROM AUTHOR]

Published

2024

11. Silica‐Rich Sol‐Gel Ink for Two‐Photon Direct Laser Writing of Microscale Structures and Optical Elements.

Author

Bin Nun, Moran, Gvishi, Raz, Dana, Yoav, Garcia, Yehudit, Marom, Dan M., Atar, Nurit, Porat, Omer, and Bar, Galit

Subjects

*OPTICAL elements, *LIGHT transmission, *OPTICAL devices, *PRINTING ink, *CHEMICAL resistance

Abstract

Innovative materials enable two‐photon polymerization for precise additive fabrication of intricate optical components. Existing polymeric inks suffer from poor optical performance due to their high organic content. Silica‐rich sol‐gel ink (75 wt%, under ambient conditions) is presented for high‐precision three‐dimensional (3D) printing of microscale structures and optical devices. A photoinitiator with high‐efficiency nonlinear absorption is introduced to initiate two‐photon polymerization. Utilizing a commercial direct laser writing system, 3D‐printing is demonstrated including the optimization of printing parameters and ink characterization. The optical performance of the printed microscale elements using the new sol‐gel ink surpasses commercially available polymeric inks on key metrics: Printed elements exhibit extremely low surface roughness, 3nm; visible and near‐IR light transmission is greater than 90%; Printed elements present enhanced mechanical and chemical resistance to common organic solvents; Structures exhibit low isotropic shrinkage, <10%; Elements withstand continuous‐wave laser intensities exceeding 7 × 105 W cm−2. Direct writing onto an optical fiber tip with no need for surface functionalization is presented, with the demonstration of a tall waveguide taper (≈1:5 aspect ratio) with low losses and modal crosstalk, and a freestanding photonic lantern mode multiplexer. The new ink can be utilized in a variety of applications and across many materials, requiring compact, durable, and complex optical elements. [ABSTRACT FROM AUTHOR]

Published

2024

12. Transcription of Customized Circularly Polarized Luminescence from Enantiomeric Metal–Organic Framework to Carbon Dots.

Author

Wang, Xue‐Yan, Luo, Peng, Dong, Xi‐Yan, Guan, Shan, and Zhang, Chong

Subjects

*DENSITY functional theory, *THREE-dimensional printing, *LUMINESCENCE, *PRINTING ink, *CHROMATICITY

Abstract

Chiral carbon dots (CDs) with circularly polarized luminescence (CPL) are one of the most dynamic areas of modern science. However, the design, preparation, and ambiguity mechanism of solid‐state CPL‐active CDs remains a formidable challenge. Herein, for the first time, CDs with customized chiroptical activities in the solid state, especially CPL, are transcribed from chiral metal–organic framework (CMOFs) via a bottle‐around‐ship strategy. Within these CMOFs⊃CDs assemblies, CDs inherited the chirality of the host CMOFs through host–guest interactions, which is revealed by density functional theory (DFT) simulations and experimental results, and amplified the luminescence dissymmetry factor (glum) by effective artificial chiral light‐harvesting systems. Impressively, CMOFs⊃CDs in pairs generated color‐tunable CPL and white CPL with chromaticity coordinates of (0.32, 0.32). Furthermore, benefiting from excellent processability, as luminescent coatings and 3D printing inks, a white circularly polarized light‐emitting diode, and an extended 3D model “light bulb” featuring white CPL are successfully fabricated, respectively. This strategy paves a new avenue for the synthesis and advanced application of solid‐state CPL‐active CDs‐based materials. [ABSTRACT FROM AUTHOR]

Published

2024

13. Advanced MXene/Graphene Oxide/Lignosulfonate Inks for 3D Printing Thick Electrodes with Vertically Aligned Pores to Dually Boost Mass Loading and Areal Capacitance.

Author

Ye, Haichuan, He, Yuan, You, Tingting, and Xu, Feng

Subjects

*CHEMICAL kinetics, *THREE-dimensional printing, *ENERGY density, *PRINTING ink, *ION transport (Biology)

Abstract

Direct ink writing 3D printing, using ink extrusion, promises to transform conventional 2D thin electrodes into 3D thick architectures for high‐performance supercapacitors. However, formulating 3D printing inks and designing 3D architectures for electrodes remain challenges. In this work, a novel MXene/graphene oxide/lignosulfonate (MGL) ink with excellent rheological properties is developed for 3D printing MGL thick electrodes with vertically aligned architectures. The MGL ink exhibited excellent shear‐thinning properties for smooth 3D printing and shape retention after printing. The 3D‐printed MGL thick electrode, with a thickness of up to 4 mm, achieved a breakthrough mass loading of 72.1 mg cm−2, resulting in an extremely high areal capacitance of 8.6 F cm−2 that is 9.6 times greater than the value observed for the bulk MGL electrode (0.9 F cm−2). Additionally, supercapacitors using the 3D MGL electrode achieved an energy density of 505.3 µWh cm−2, significantly surpassing the value for bulk MGL electrode (52.8 µWh cm−2). This enhancement is attributed to the efficient design of the electrodes, where vertically aligned pores in the 3D MGL electrode enhanced ion transfer and reaction kinetics. This study demonstrates an innovative approach for formulating inks and provides guidance for designing 3D thick electrodes with rapid ion transport and excellent electrochemical performance. [ABSTRACT FROM AUTHOR]

Published

2024

14. Polymer‐Regulating MXene@Dopamine Electroactive Gel‐Inks for Textile‐Based Multi‐Protective Wearables.

Author

Yan, Biaobiao, Liu, Siqi, Yuan, Yun, Hou, Xunan, Zhou, Man, Yu, Yuanyuan, Wang, Qiang, He, Chaobin, and Wang, Ping

Subjects

*TRANSITION metal carbides, *TEXTILE exhibitions, *ELECTRONIC structure, *DOPING agents (Chemistry), *PRINTING ink

Abstract

2D transition metal carbide/nitride (MXene) show significant potential for fabricating flexible wearables due to its outstanding electroactive characteristic. However, the complex processes in rheology regulation and easy agglomeration of MXene nanosheets hinder their applications as inks for homogeneous printing and coating. Herein, an electroactive gel‐ink with a low concentration of MXene (20 mg mL−1) using poly(3,4‐ethylenedioxythiophene):poly(sodium 4‐styrenesulfonate) (PEDOT:PSS) as a dopant and conductive binder is developed. The dopamine‐involved modification and PEDOT:PSS doping together promote the formation of ordered lamellar structure of MXene nanosheets, and in turn the nanosheets can regulate the interconnected electronic structure of PEDOT:PSS, which enables the transition from micellar to linear structures. Through adjusting the combination ratio of dopamine‐modified MXene (MD) to PEDOT:PSS, the viscosity of MXene inks (MDP) is tunable within 1–104 Pa·s to realize scalable printing and other processing. Screen‐printing with MDP gel‐ink endows textiles with excellent conductive stability while retaining the inherent wearability of the original fabric. With high conductivity (109.6 S m−1) and low mid‐infrared emissivity (0.34), the decorated textiles exhibit remarkable multi‐protective abilities. This work provides a novel strategy for formulating versatile MXene inks that will facilitate the large‐scale fabrication of high‐performance personal wearable multi‐protective textiles. [ABSTRACT FROM AUTHOR]

Published

2024

15. Evaluating the Piezoelectric Energy Harvesting Potential of 3D-Printed Graphene Prepared Using Direct Ink Writing and Fused Deposition Modelling.

Author

R., Hushein, Dhilipkumar, Thulasidhas, V. Shankar, Karthik, P, Karuppusamy, Salunkhe, Sachin, Venkatesan, Raja, Shazly, Gamal A., Vetcher, Alexandre A., and Kim, Seong-Cheol

Subjects

*THREE-dimensional printing, *FREQUENCIES of oscillating systems, *ENERGY consumption, *PRINTING ink, *POTENTIAL energy, *ENERGY harvesting, *FUSED deposition modeling, *PIEZOELECTRIC transducers

Abstract

This research aims to use energy harvested from conductive materials to power microelectronic components. The proposed method involves using vibration-based energy harvesting to increase the natural vibration frequency, reduce the need for battery replacement, and minimise chemical waste. Piezoelectric transduction, known for its high-power density and ease of application, has garnered significant attention. Additionally, graphene, a non-piezoelectric material, exhibits good piezoelectric properties. The research explores a novel method of printing graphene material using 3D printing, specifically Direct Ink Writing (DIW) and fused deposition modelling (FDM). Both simulation and experimental techniques were used to analyse energy harvesting. The experimental technique involved using the cantilever beam-based vibration energy harvesting method. The results showed that the DIW-derived 3D-printed prototype achieved a peak power output of 12.2 µW, surpassing the 6.4 µW output of the FDM-derived 3D-printed prototype. Furthermore, the simulation using COMSOL Multiphysics yielded a harvested output of 0.69 µV. [ABSTRACT FROM AUTHOR]

Published

2024

16. Study of quality indicators of gravure imprints obtained with fluorescent ink.

Author

Havenko, Svitlana, Czubak, Jerzy, Labetska, Marta, and Kochubei, Victoria

Subjects

*INTAGLIO printing, *SURFACE topography, *PRINTING ink, *FLUORESCENCE spectroscopy, *OPACITY (Optics)

Abstract

The peculiarities of the decoration of gravure imprints on cardboard using fluorescent inks are considered. The influence of the number of fluorescent impurities added to gravure printing ink on the optical indicators of printed image quality, particularly optical density, and gloss, is investigated. Increasing the number of fluorescent impurities added to the ink from 10 to 30% helps to increase the gloss on imprints from 2 to 15 units. Conducted thermogravimetric studies show the resistance of fluorescent imprints to the influence of temperatures during drying in the printing process. The topography of the surface of the substrates and its influence on the quality of imprints is studied. Conducted electron microscopic studies of imprints obtained with inks with different amounts of fluorescent impurities show their uniform distribution on the surface of the substrate. Studies of the fluorescence spectra of the ink and the imprints formed by it confirm the phenomenon of an increase in the intensity of the glow of printed images. The studies confirm the well-known influence of substrate roughness on the smoothness of gravure imprints. It is established that the absence of significant macro irregularities on the surface of Koppargloss FBB cardboard is due to the presence of two coating layers. Analysis of the surface profiles of FBB cardboard shows that its roughness parameter (Ra = 0.424 μm) is three times smaller compared to Incada Silk C GC1 cardboard (the roughness parameter Ra = 1.28 μm), with a single-layer coating. Such a pattern is also preserved on the imprints, which is reflected in their quality accordingly. Studies show that for imprints on GC1 cardboard, the average ΔE value is 2.23, for imprints on FBB cardboard, the average ΔE value is 3.71, which is due to the presence of double coating. The factors that can influence the process of fluorescence of printed images are outlined. The technological characteristics of inks for gravure printing on packaging are described. [ABSTRACT FROM AUTHOR]

Published

2024

17. Lessons to Learn for 3D Printing of Drug Products by Semisolid Extrusion (SSE).

Author

Sun, Weining, Rantanen, Jukka, and Genina, Natalja

Subjects

*THREE-dimensional printing, *RHEOLOGY, *PRINTING ink, *DRUG factories, *THEOPHYLLINE

Abstract

Semisolid extrusion (SSE) 3D printing (3DP) technology is emerging due to its simplicity and potential for on-site manufacturing of personalized drug products with tailored functionality (dose, release profile), as well as recognizability (size, shape, color). However, even a minor change in the composition of the ink (the feedstock material) and the printing process parameters can largely influence the outcome of printing. This paper summarizes the recent SSE 3DP studies, where the important factors affecting the quality of the printed drug products are discussed. Further challenges are showcased by introducing a case study focusing on the design of oral theophylline immediate-release drug products. The identified crucial factors, such as the printing hardware and connected software, printing parameters, and composition of the ink are discussed. Especially, the rheological properties of the ink during the printing process, together with solidification, mechanical properties, and morphology studies of already printed products are deliberated to gain more understanding of the printability of drug products by SSE. This work aims to provide an overview of design aspects related to SSE-based fabrication of personalized drug products. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

18. Influence of selected sheet-fed offset printing conditions on primary mottling.

Author

Kowalczyk, Jan

Subjects

*OFFSET printing, *SUBSTRATES (Materials science), *FOURIER analysis, *OPACITY (Optics), *PRINTING ink

Abstract

The key parameter in the printing process is the evenness of applying the ink layer on the printing substrate. It determines the quality of the produced prints. One of the many factors affecting the final evenness of the ink layer on the print is the phenomenon of mottling, which is caused by the non-uniform internal structure of the paper. The aim of this work was to analyze the influence of basic printing parameters on the value of the mottling index. The research showed a significant effect of the pressure in the printing unit of the offset machine and the thickness of the ink layer on the printing substrate on the value of the primary mottling index. In addition, the research revealed that the properties of the printing substrate have a significant impact on the value and nature of changes in the mottling index. In this work, using the Fourier analysis, the frequency of optical density fluctuations in solid tone area related to the mottling phenomenon was also studied. No influence of pressure changes in the Nip of the printing unit on this print parameter was found. [ABSTRACT FROM AUTHOR]

Published

2024

19. MATHEMATICAL MODEL OF NICKEL-GRAPHENE COMPOSITE INKS FOR JETTING PROPERTIES IN INKJET PRINTING.

Author

Thakur, Neha, Swaminathan, Parasuraman, and Murthy, Hari

Subjects

PRINTING ink, NAVIER-Stokes equations, MATHEMATICAL models, INK, NOZZLES

Abstract

The droplet formation process in inkjet printing is studied numerically and verified through a simulation model. The droplet formation process decides the printing quality of the coating, and a mathematical model is developed to understand the complete process from droplet formation to detachment. The Navier-Stokes equation is used to mathematically derive the droplet radius (rnumerical). COMSOL multiphysics is used for simulation and the radius (rsimulation) is calculated from the droplet mass. The rnumerical and rsimulation are compared for inks containing nickel, graphene, and nickel-graphene composite ink it is observed that the composite ink radiuses have the lowest difference (rsimulation - rnumerical = 0.085 µm). A droplet is formed at 1.47 mm from the nozzle inlet, for nickel-graphene ink, and after 1.5mm for other pristine inks. The results are verified through Z number, velocity profile, and droplet mass. The droplet formation observed from the velocity profile is earliest at 120 µs. It is seen that a stable droplet is generated at 100µs for nickel-graphene ink and at 200 µs for individual inks. [ABSTRACT FROM AUTHOR]

Published

2024

20. 3D Printing MXene‐Based Electrodes for Supercapacitors.

Author

Jiang, Xudong, Bai, Juan, Wijerathne, Binodhya, Zhou, Qianqin, Zhang, Fan, Liao, Ting, and Sun, Ziqi

Subjects

*CLEAN energy, *THREE-dimensional printing, *ENERGY storage, *RAW materials, *PRINTING ink

Abstract

3D printing, as an advanced and promising strategy for processing electrode for energy storage devices, such as supercapacitors and batteries, has garnered considerable interest in recent decades. The interest in 3D printed electrodes stems from its exceptional performance and manufacturing features, including customized sizes and shapes and the layer‐by‐layer processing principle, etc., especially integrating with MXene which allows the manufacturing of electrodes from different raw materials and possessing desired electrochemical properties. Herculean challenges, such as material compatibility of the printing inks, nondurable interfacial or bulk mechanical strength of the printed electrodes, and sometimes the low capacitance, lead to inferior electrochemical performance and hinder the practical applications of this promising technology. In this review, we firstly summarize the representative 3D printing methods, then, review the MXene‐based 3D printing electrodes made from different materials, and last, provide electrochemical performance of 3D printing MXene‐based electrodes for supercapacitors. Furthermore, based on a summary on the recent progress, an outlook on these promising electrodes for sustainable energy devices is provided. We anticipate that this review could provide some insights into overcoming the challenges and achieving more remarkable electrochemical performance of 3D printing supercapacitor electrodes and offer perspectives in the future for emerging energy devices. [ABSTRACT FROM AUTHOR]

Published

2024

21. A Strategy for Fabricating Ultra-Flexible Thermoelectric Films Using Ag 2 Se-Based Ink.

Author

Yuan, Yunhuan, Ding, Chaogang, Yin, Rui, Lu, Shun, Xu, Jie, Ren, Wei, Li, Kang, and Zhao, Weiwei

Subjects

*SCREEN process printing, *MOTION picture screenings, *WEARABLE technology, *INTERNET of things, *PRINTING ink

Abstract

Flexible thermoelectric materials have drawn significant attention from researchers due to their potential applications in wearable electronics and the Internet of Things. Despite many reports on these materials, it remains a significant challenge to develop cost-effective methods for large-scale, patterned fabrication of materials that exhibit both excellent thermoelectric performance and remarkable flexibility. In this study, we have developed an Ag2Se-based ink with excellent printability that can be used to fabricate flexible thermoelectric films by screen printing and low-temperature sintering. The printed films exhibit a Seebeck coefficient of −161 μV/K and a power factor of 3250.9 μW/m·K2 at 400 K. Moreover, the films demonstrate remarkable flexibility, showing minimal changes in resistance after being bent 5000 times at a radius of 5 mm. Overall, this research offers a new opportunity for the large-scale patterned production of flexible thermoelectric films. [ABSTRACT FROM AUTHOR]

Published

2024

22. Flexible and Stretchable Liquid‐Metal Microfluidic Electronics Using Directly Printed 3D Microchannel Networks.

Author

Yamagishi, Kento, Ching, Terry, Chian, Nicole, Tan, Martin, Zhou, Wenshen, Huang, Shao Ying, and Hashimoto, Michinao

Subjects

*LIQUID metals, *THREE-dimensional printing, *ELECTRIC circuits, *PRINTED circuits, *PRINTING ink

Abstract

This paper describes a method for fabricating microfluidic electronics with 3D interconnected networks by direct ink writing (DIW)‐based 3D printing. Existing 3D printing technologies have yet to simultaneously realize 1) direct printing of interconnected multilayered microchannels without supporting materials or post‐processing and 2) integration of electronic elements with microchannels during the process of printing. This research aims to develop a method to fabricate support‐free microchannels consisting of silicone sealant without the collapse of the extruded structure while integrating electronic elements during the fabrication by DIW. The injection of liquid metal into 3D‐printed microchannels allows the formation of electrical connections between 3D conductive networks and the embedded electronic elements, enabling the fabrication of flexible and stretchable liquid metal antenna coils. To demonstrate a practical application, 1) a skin‐attachable radio‐frequency identification (RFID) tag using a commercial skin‐adhesive plaster as a substrate and 2) free‐standing flexible wireless light‐emitting devices with a small footprint (21.4 mm × 15 mm) for potential implantable applications are produced. This technology will offer a new capability to realize the automated fabrication of stretchable printed circuits with 3D configuration of electrical circuits consisting of liquid metals. [ABSTRACT FROM AUTHOR]

Published

2024

23. Print Quality Analysis of Stone Paper and Coated Sticker Paper Used in Screen Printing.

Author

Akpolat, Cem and Akgül, Ahmet

Subjects

STONE, PRINTING ink, SCREEN process printing, NATURAL resources, PRINTING industry

Abstract

The sustainable use of natural resources is becoming an increasingly important issue today. Stone paper, produced as an alternative to cellulose-based paper from the forest, is rich in minerals and produced without cellulose and water. This study focuses on the behavior of screen-printing ink on two different papers, stone paper and coated sticker paper. Properties such as ink adhesion, rubbing resistance, optical printing ink density, ink consumption, and lightfastness were measured on these surfaces. Solvent- and UV-based inks were used, and printing was carried out on cellulose-based (coated sticker paper) and mineral-based (stone paper) paper layers using three different mesh counts (90, 120, and 140 tpc). The rubbing resistance and lightfastness of the papers were also measured. The present findings revealed that stone paper had the same printability properties as cellulose-based paper. The study concluded that using a 140 tpc mesh with both types of ink results in a high-lightfastness ink layer and lower ink consumption. UV-based inks exhibited high rub resistance across all mesh counts. Additionally, when printing with stone paper, there will be a reduction in ink consumption, thereby achieving cost savings. Based on the present findings, it was concluded that water- and oil-resistant stone paper can be considered an essential alternative in many fields, including the printing industry. [ABSTRACT FROM AUTHOR]

Published

2024

24. Research and Analysis of Woodblock Printing Ink from the Qing Dynasty Used in the Shuyede Press of Shandong.

Author

Li, Jing, Dong, Qianqian, Shi, Shuxuan, and Li, Yuhu

Subjects

QING dynasty, China, 1644-1912, WOODCUTTING (Printmaking), PRINTING ink, INFRARED spectroscopy, ARCHIVAL materials

Abstract

Archival writing material is an important carrier to record and reflect archival content, and its material and durability are closely related to the life of archives. The "Shuyede" press in Shandong Province, which originated in the reign of Kangxi (1662 AD–1722 AD) in the Qing dynasty, printed many important archives and ancient books of the Qing dynasty (1644 AD–1911 AD). In order to explore the material composition of woodblock printing ink from the Shuyede press, modern analytical and detection techniques such as scanning electron microscopy–energy-dispersive spectrometry (SEM-EDS), Fourier-transform infrared spectroscopy (FTIR), gas chromatography–mass spectrometry (GC/MS), and pyrolysis gas chromatography–mass spectrometry (Py-GC/MS) were applied for the analysis and identification of the ink on woodblock plates from the Shuyede press. The results showed that two kinds of printing ink—pine soot ink and oil soot ink—used were in these woodblocks from the Shuyede press in the Qing dynasty in the collection of Shandong Museum, and the binding material in the ink was animal glue, indicating that both pine and oil soot inks were used as printing ink in the Qing dynasty. [ABSTRACT FROM AUTHOR]

Published

2024

25. Wet‐Printed Stretchable and Strain‐Insensitive Conducting Polymer Electrodes: Facilitating In Vivo Gastric Slow Wave Mapping.

Author

Zhang, Peikai, Athavale, Omkar N., Zhu, Bicheng, Travas‐Sejdic, Jadranka, and Du, Peng

Subjects

*POLYMER electrodes, *ARTIFICIAL implants, *MICROELECTRODES, *EDEMA, *PRINTING ink

Abstract

Wearable and implantable devices play a crucial role in clinical diagnosis, disease treatment, and fundamental research on the body's electrophysiology and biochemical processes. Conducting polymers are emerging as promising solutions to surpass the limitations of traditional metal‐based electrodes, offering enhanced conformability, and stretchability. However, current microfabrication techniques of CP electrodes have a number of limitations. In this study, a novel wet‐printing technique is developed for the fabrication of highly stretchable poly(3,4‐ethylenedioxythiophene): polystyrene sulfonate (PEDOT:PSS) microelectrodes. The wet‐printing, conducted in a liquid coagulation bath, has the advantages of being non‐contact, easy and fast to perform, and capable of printing low‐viscosity inks. Wet‐printing of PEDOT:PSS lines with a width of ≈20 µm is demonstrated. By adding D‐sorbitol as a plasticizer, an ultra‐high stretchability of PEDOT:PSS electrodes, of more than 720% is achieved while the electrodes remained conductive and strain‐insensitive up to high strains. The use of PEDOT:PSS wet‐printed electrode arrays for the electrophysiological recording from the stomach is demonstrated. The stretchable electrodes conformed swell to the tissue and recorded comparable electrophysiological signals to Au‐plated electrodes in porcine and rodent animal models. The wet‐printing approach to fabricating flexible and stretchable electrode arrays using low‐viscosity, conducting inks holds promise for applications in conformable electronics. [ABSTRACT FROM AUTHOR]

Published

2024

26. Formulation and optimization of copper selenide/PANI hybrid screen printing ink for enhancing the power factor of flexible thermoelectric generator: A synergetic approach.

Author

Nayak, Ramakrishna, Shetty, Prakasha, M, Selvakumar, Rao, Ashok, K V, Sriram, Wagle, Shivananda, Nayak, Sandeep, Kamath, Vinod, Shetty, Nakul, and Saquib, Mohammad

Subjects

*THERMOELECTRIC generators, *SCREEN process printing, *PRINTING ink, *POLYANILINES, *COPPER, *SEEBECK coefficient, *POWER density

Abstract

The stunning thermoelectric behavior of inorganic/organic hybrids and the lack of information on screen-printed flexible thermoelectric generators based on Cu 3 Se 2 and Polyaniline for low-temperature applications have motivated this work. The synergic influence of various acid dopants, concentration, and annealing temperature of polyaniline on the power density of Cu 3 Se 2 /PANI ink-based flexible thermoelectric generator is explored. The presence of 1.5 wt% of H 2 SO 4 -PANI, annealed at 60 °C, decreased the bandgap and electrical resistance of Cu 3 Se 2 by 11.96 % and 29.4 %, respectively. As a result, an increase of 46.06 % in the Seebeck coefficient and 242 % in the power output is achieved, which is many folds higher than the few reported works using novel materials. In addition, the Cu 3 Se 2 /H 2 SO 4 -PANI ink-based flexible thermoelectric generator with eight legs exhibited a maximum power output, power density, and power factor of 25.69 nW, 23.79 mW/m2, and 0.77 nW/m2K2 at ΔT = 100 °C, respectively under external load. [ABSTRACT FROM AUTHOR]

Published

2024

27. 3D-Printed Hydrogels as Photothermal Actuators.

Author

Ghelardini, Melanie M., Geisler, Martin, Weigel, Niclas, Hankwitz, Jameson P., Hauck, Nicolas, Schubert, Jonas, Fery, Andreas, Tracy, Joseph B., and Thiele, Julian

Subjects

*PHASE transitions, *POLY(ISOPROPYLACRYLAMIDE), *MACROMONOMERS, *PRINTING ink, *PHOTOCROSSLINKING

Abstract

Thermoresponsive hydrogels were 3D-printed with embedded gold nanorods (GNRs), which enable shape change through photothermal heating. GNRs were functionalized with bovine serum albumin and mixed with a photosensitizer and poly(N-isopropylacrylamide) (PNIPAAm) macromer, forming an ink for 3D printing by direct ink writing. A macromer-based approach was chosen to provide good microstructural homogeneity and optical transparency of the unloaded hydrogel in its swollen state. The ink was printed into an acetylated gelatin hydrogel support matrix to prevent the spreading of the low-viscosity ink and provide mechanical stability during printing and concurrent photocrosslinking. Acetylated gelatin hydrogel was introduced because it allows for melting and removal of the support structure below the transition temperature of the crosslinked PNIPAAm structure. Convective and photothermal heating were compared, which both triggered the phase transition of PNIPAAm and induced reversible shrinkage of the hydrogel–GNR composite for a range of GNR loadings. During reswelling after photothermal heating, some structures formed an internally buckled state, where minor mechanical agitation recovered the unbuckled structure. The BSA-GNRs did not leach out of the structure during multiple cycles of shrinkage and reswelling. This work demonstrates the promise of 3D-printed, photoresponsive structures as hydrogel actuators. [ABSTRACT FROM AUTHOR]

Published

2024

28. Valorization of Fruit and Vegetables Industry By-Streams for 3D Printing—A Review.

Author

Tyupova, Alona and Harasym, Joanna

Subjects

THREE-dimensional printing, FOOD waste, PRINTING ink, FRUIT industry, FOOD production, LEFTOVERS

Abstract

An energy supply crisis is impacting all the branches, including the agriculture and food industry. The wise and responsible utilization of plant raw materials already cultivated is becoming a must in the country's economy. Not only the waste of the resources included but also the environmental challenge are concerns behind the not exploited food production by-streams and leftovers' valorization. Fruits and vegetables' out of the market quality "beauty" standards are still valuable sources of nutritious compounds. The conversion of raw materials into edible products can be provided by many techniques, with three-dimensional printing being the most individualized one. The main objective of this review was to summarize the existing efforts for the valorization of fruits and vegetable residuals into edible 3D inks and then 3D printed products. The clustering analysis was used for the separation of certain research approaches in fruit and vegetable wastes exploitation for 3D printing inks' formulation. As the multilayer deposit technique is strongly dependent on the printing conditions and 3D ink formulation, therefore the tabularized description was included presenting the nozzle diameter, printing speed and other conditions specified. [ABSTRACT FROM AUTHOR]

Published

2024

29. Nanoporous, Gas Permeable PEGDA Ink for 3D Printing Organ‐on‐a‐Chip Devices.

Author

Karamzadeh, Vahid, Shen, Molly L., Shafique, Houda, Lussier, Felix, and Juncker, David

Subjects

*THREE-dimensional printing, *MICROPHYSIOLOGICAL systems, *PRINTING ink, *CELL culture, *MICROFLUIDIC devices, *ETHYLENE glycol

Abstract

Polydimethylsiloxane (PDMS), commonly used in organ‐on‐a‐chip (OoC) systems, faces limitations in replicating complex geometries, hindering its effectiveness in creating 3D OoC models. In contrast, poly(ethylene glycol)diacrylate (PEGDA‐250), favored for its fabrication ease and resistance to small molecule absorption, is increasingly used for 3D printing microfluidic devices. However, applications in cell culture have been limited due to poor cell adhesion. Here, a nanoporous PEGDA ink (P‐PEGDA) is introduced to enhance cell adhesion. P‐PEGDA is formulated with a porogen, photopolymerized, followed by the porogen removal. Utilizing P‐PEGDA, complex microstructures, and membranes as thin as 27 µm are 3D‐printed. Porogen concentrations from 10 to 30% are tested yielding constructs with increasing porosity and oxygen permeability surpassing PDMS, without compromising printing resolution. Tests across four cell lines show >80% cell viability, with a notable 77‐fold increase in MDA‐MB‐231 cell coverage on the porous scaffolds. Finally, an OoC model comprising a gyroid scaffold with a central opening filled with a cancer spheroid is introduced. This setup, after a 14 days co‐culture, demonstrates significant endothelial sprouting and integration within the spheroid. The P‐PEGDA formulation is suitable for high‐resolution 3D printing of constructs for 3D cell culture and OoC owing to its printability, gas permeability, biocompatibility, and cell adhesion. [ABSTRACT FROM AUTHOR]

Published

2024

30. Research on Spectral Measurement Method for Content of Bicolor Mixed Ink.

Author

Fang, Shuyang, Zhang, Wenhao, Zhang, Rui, Jiang, Fei, and Liu, Qiang

Subjects

*PARTIAL least squares regression, *PRINTING ink, *FEATURE extraction, *INK

Abstract

To achieve consistent color reproduction of printed products and accurate measurement the content of mixed ink has always been an important research topic in the printing industry. This paper proposes a spectral-based method for measuring the content of dual-color mixed printing ink, aiming to solve the difficulty in determining the specific content of the base color in the same ratio of dual-color ink by using spectral analysis. First, a composite filtering method combining median filtering and wavelet transform was compared and selected for spectral preprocessing. Then, three methods, namely the successive projections algorithm (SPA), competitive adaptive reweighted sampling method (CARS), and stable competitive adaptive weighted sampling method (SCARS), were used to extract feature wavelengths from the preprocessed information. Based on partial least squares regression (PLSR), four models, PLSR, SPA–PLSR, CARS–PLSR, and SCARS, were established for predictive analysis. To further test the model, the SCARS–PLSR model was used for predictive analysis of magenta-cyan, yellow-magenta, and yellowcyan binary samples with a mass fraction ratio of 0.5. The results showed that the SCARS–PLSR model has the best predictive performance, with RMSE and R2 values of 0.0052, 0.0002, 0.0004 and 0.9989, 0.9999, 0.9999, respectively. This indicates that this study can accurately determine the content of dual-color ink by spectral analysis. [ABSTRACT FROM AUTHOR]

Published

2024

31. Exploring Vacuum Compression Molding as a Preparation Method for Flexible-Dose Pediatric Orodispersible Films.

Author

Hales, Dana, Bogdan, Cătălina, Tefas, Lucia Ruxandra, Cornilă, Andreea, Chiver, Maria-Andreea, Tomuță, Ioan, Casian, Tibor, Iovanov, Rareș, Katona, Gábor, Ambrus, Rita, and Iurian, Sonia

Subjects

*COMPRESSION molding, *IMPACT (Mechanics), *CHILD patients, *PEDIATRIC therapy, *PRINTING ink, *SOLID dosage forms

Abstract

In recent years, solid dosage forms have gained interest in pediatric therapy because they can provide valuable benefits in terms of dose accuracy and stability. Particularly for orodispersible films (ODFs), the literature evidences increased acceptability and dose flexibility. Among the various available technologies for obtaining ODFs, such as solvent casting, hot-melt extrusion, and ink printing technologies, the solvent-free preparation methods exhibit significant advantages. This study investigated Vacuum Compression Molding (VCM) as a solvent-free manufacturing method for the preparation of flexible-dose pediatric orodispersible films. The experimental approach focused on selecting the appropriate plasticizer and ratios of the active pharmaceutical ingredient, diclofenac sodium, followed by the study of their impacts on the mechanical properties, disintegration time, and drug release profile of the ODFs. Additional investigations were performed to obtain insights regarding the solid-state properties. The ODFs obtained by VCM displayed adequate quality in terms of their critical characteristics. Therefore, this proof-of-concept study shows how VCM could be utilized as a standalone method for the production of small-scale ODFs, enabling the customization of doses to meet the individual needs of pediatric patients. [ABSTRACT FROM AUTHOR]

Published

2024

32. Applications of physical and chemical treatments in plant‐based gels for food 3D printing.

Author

Liu, Zhihao, Hu, Xinna, Lu, Shuyu, Xu, Bo, Bai, Chenyu, Ma, Tao, and Song, Yi

Subjects

*THREE-dimensional printing, *MAKERSPACES, *PRINTING ink, *RHEOLOGY, *CHEMICAL composition of plants, *RAW materials

Abstract

Extrusion‐based three‐dimensional (3D) printing has been extensively studied in the food manufacturing industry. This technology places particular emphasis on the rheological properties of the printing ink. Gel system is the most suitable ink system and benefits from the composition of plant raw materials and gel properties of multiple components; green, healthy aspects of the advantages of the development of plant‐based gel system has achieved a great deal of attention. However, the relevant treatment technologies are still only at the laboratory stage. With a view toward encouraging further optimization of ink printing performance and advances in this field, in this review, we present a comprehensive overview of the application of diverse plant‐based gel systems in 3D food printing and emphasize the utilization of different treatment methods to enhance the printability of these gel systems. The treatment technologies described in this review are categorized into three distinct groups, physical, chemical, and physicochemical synergistic treatments. We comprehensively assess the specific application of these technologies in various plant‐based gel 3D printing systems and present valuable insights regarding the challenges and opportunities for further advances in this field. [ABSTRACT FROM AUTHOR]

Published

2024

33. Numerical Simulation on Ink Transfer Channel of Flexography Based on Fluid–Solid-Heat Interactions.

Author

Zhu, Wanjun, Xing, Jiefang, and Zhu, Hongjuan

Subjects

INTAGLIO printing, TRANSFER printing, PRINTING ink, FLUID flow, CHANNEL flow

Abstract

Flexographic printing is widely used in the packaging field, but there are still some problems in the printing of flexographic ink on non-absorbent substrates, such as low precision and unstable quality. In this paper, the printing process of flexographic ink is simulated. The interaction of fluid flow, temperature change, and solid deformation in flexographic printing is studied systematically by using the method of fluid–solid thermal coupling for the first time. The process of ink channel formation under static extrusion and fluid–solid thermal coupling was analyzed. The influences of printing pressure, printing speed, ink layer thickness, and ink viscosity on the ink channel were explored. The results show that the printing speed increases and the temperature in the stamping area increases. The printing speed is nonlinear related to the ink flow channel, the influence on the channel is slow at a low speed, the channel increases sharply at a medium and high speed, and tends to be stable at a high speed. When the printing speed is 200 m/min, the ink temperature in the stamping area is 1.5 °C higher than that at the entrance. With an increase in printing pressure, the ink flow channel width showed a trend of decreasing first and then stabilizing, and the pressure was about 0.4 MPa, showing a small fluctuation; the greater the pressure, the higher the temperature of the ink, which will change the performance of the ink and plate, causing adverse effects on the printing belt. The channel width showed obvious nonlinear characteristics with an increase and decrease in ink thickness. When the ink thickness is 30 μm, the deformation of the plate reaches the maximum, and the width of the ink circulation channel is correspondingly the widest. The change in ink viscosity has little influence on the stability of the ink's internal flow rate and temperature field. The research results provide theoretical support for the transfer of ink printing from gravure to flexo printing. [ABSTRACT FROM AUTHOR]

Published

2024

34. FROM RAG TO WOOD GOING THROUGH CEREAL: TECHNOLOGICAL REVOLUTION AMONG THE SCHOOL MAPS IN THE ARCHIVES OF THE UNIVERSITY OF GRANADA (SPAIN).

Author

REYES PÉREZ, Ana, GÓMEZ HERNÁNDEZ, Nuria, and ESPEJO ARIAS, Teresa

Subjects

CONSERVATION & restoration, PRINTING ink, EIGHTEENTH century, TWENTIETH century, CELLULOSE

Abstract

School maps emerged as new type of document as a result of a series of technological and educational advances spanning the 18th to the 20th century. These maps originally played strictly functional and didactic roles. The passage of time has endowed them with an indisputable historical, documentary, scientific and even artistic character. Those currently housed in archives are generally poorly preserved due to issues related to their manufacture and general lack of concern for their safeguard after losing their original function. This study aims to characterise the materials serving to manufacture them by sampling a series housed in the Archives of the University of Granada, a task that is complicated by their multilayered nature (cloth, paper, printing inks and protective varnish). Preliminary identification of the fibrous elements reinforcing the papers and textiles by means of micro-invasive analytical techniques enables to subsequently define appropriate conservation and restoration protocols. [ABSTRACT FROM AUTHOR]

Published

2024

35. Manufacturing of high-conductivity carbon nanotube fibers and extensible coils by immersed extrusion.

Author

Owens, Crystal E., McKinley, Gareth H., and Hart, A. John

Subjects

*CARBON fibers, *CARBON nanotubes, *PSEUDOPLASTIC fluids, *3-D printers, *THREE-dimensional printing, *PRINTING ink, *FIBERS

Abstract

[Display omitted] • 3D printing inks into liquid bath anti-solvent forms fibers in designated locations. • Structural and electronic properties are tunable by the anti-solvent. • Coiled carbon nanotube yarns stretch up to 50 % with under 1 % change in resistance. • Printed nanotube yarns have specific conductivity on par with metals. Inspired by methods of wet fiber spinning, we introduce a process using a 3D printer to create dense carbon nanotube (CNT) fibers and extensible coils with metal-like DC specific conductivity. An extrusion-based printer with an immersed nozzle extrudes a homogeneous shear-thinning ink (with initially < 1 % CNT concentration in water) into a liquid bath of antisolvent, inducing immediate precipitation-driven solidification slightly beyond the nozzle tip. This process forms continuous fibers of CNTs with conductivity up to 3 × 105 S/m, exceeding that of dense graphite and approaching that of CNTs spun from similar inks in a continuous fiber spinning process (6 × 105 S/m). The specific conductivity is up to 1 × 103 S m2/kg, comparable with gold (2.3 × 103 S m2/kg). The printing regimes are analyzed, with consideration of the draw ratio imposed during printing. Particular focus is placed on adjusting the speed of counter-diffusion of the ink solvent and the bath liquid, which allows for tuning of fiber diameter, conductivity, and specific conductivity respectively over ranges of one, four, and five orders of magnitude. The conductivity of resulting fibers is maximized when the speed of solvent counter-diffusion is high and the radius reduction is largest. When extrusion speed is also high relative to speed of the nozzle motion, a fluid mechanical coiling instability emerges which creates filaments with periodic coils, allowing for intricate designs to be formed along a linear extrusion path. Once dried, these densely coiled structures initially maintain their shape and can subsequently undergo up to 50 % strain with under 1 % change in resistance and 170 % linear extension with 20 % increase in resistance as the coils unwind. The resulting complex coil structures have applications in lightweight circuitry and as flexible interconnects. [ABSTRACT FROM AUTHOR]

Published

2024

36. An engineering approach to the 3D printing of K‐Carrageenan/konjac glucomannan hydrogels.

Author

Russo Spena, Simona, Visone, Biagio, and Grizzuti, Nino

Subjects

*THREE-dimensional printing, *GLUCOMANNAN, *CARRAGEENANS, *HYDROGELS, *3-D printers, *KONJAK, *PRINTING ink

Abstract

Summary: Aqueous solutions of Konjac glucomannan (KGM)/κ‐Carrageenan (κ‐C) of different ratios (1:2, 1:5, 1:8 and 1:10) and a fixed κ‐C content of 1.5%, were proposed as a new 3D food printing ink. Their thermo‐responsive behaviour was evaluated by temperature ramp rheological tests. This characterisation allowed for the evaluation of the synergistic effect between KGM and κ‐C and gave indications useful to the printing performance. Both elastic (G′) and loss (G″) moduli were found to increase by increasing the KGM concentration. Samples were printed by controlling the thermally reversible sol/gel transition occurring during the process. Direct pressure and flow rate measurements in the 3D printer were used to obtain the viscosity versus shear rate curves under processing conditions, useful to validate a scaling law relating the printing filament diameter to the relevant process and material properties (inks viscosity and printing pressure). The 3D printing performance of inks was evaluated by means of a novel, integrated score system. The results obtained indicate that aqueous mixtures of KGM/κ‐C can be successfully employed as a base for 3D printing food hydrogels. The use of the score system above outlined proved to be an easy yet efficient tool for the optimisation of the gel composition. [ABSTRACT FROM AUTHOR]

Published

2024

37. All Screen Printed and Flexible Silicon Carbide NTC Thermistors for Temperature Sensing Applications.

Author

Wadhwa, Arjun, Benavides-Guerrero, Jaime, Gratuze, Mathieu, Bolduc, Martin, and Cloutier, Sylvain G.

Subjects

*SILICON carbide, *THERMISTORS, *SCREEN process printing, *BEND testing, *TEMPERATURE, *PRINTING ink

Abstract

In this study, Silicon Carbide (SiC) nanoparticle-based serigraphic printing inks were formulated to fabricate highly sensitive and wide temperature range printed thermistors. Inter-digitated electrodes (IDEs) were screen printed onto Kapton® substrate using commercially avaiable silver ink. Thermistor inks with different weight ratios of SiC nanoparticles were printed atop the IDE structures to form fully printed thermistors. The thermistors were tested over a wide temperature range form 25 °C to 170 °C, exhibiting excellent repeatability and stability over 15 h of continuous operation. Optimal device performance was achieved with 30 wt.% SiC-polyimide ink. We report highly sensitive devices with a TCR of −0.556%/°C, a thermal coefficient of 502 K (β -index) and an activation energy of 0.08 eV. Further, the thermistor demonstrates an accuracy of ±1.35 °C, which is well within the range offered by commercially available high sensitivity thermistors. SiC thermistors exhibit a small 6.5% drift due to changes in relative humidity between 10 and 90%RH and a 4.2% drift in baseline resistance after 100 cycles of aggressive bend testing at a 40° angle. The use of commercially available low-cost materials, simplicity of design and fabrication techniques coupled with the chemical inertness of the Kapton® substrate and SiC nanoparticles paves the way to use all-printed SiC thermistors towards a wide range of applications where temperature monitoring is vital for optimal system performance. [ABSTRACT FROM AUTHOR]

Published

2024

38. 可水分散性油墨聚氨酯树脂的制备 及其性能研究.

Author

张博, 石红翠, and 宋利青

Subjects

TOLUENE diisocyanate, MOLECULAR structure, PROPIONIC acid, PRINTING ink, INFRARED spectroscopy

Abstract

Copyright of Plastics Science & Technology / Suliao Ke-Ji is the property of Plastics Science & Technology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

39. Development of Gold Inks for Inkjet Printing of Gas Sensors Electrodes on Plastic Support.

Author

Le Porcher, Bastien, Rieu, Mathilde, and Viricelle, Jean-Paul

Subjects

GAS detectors, GOLD nanoparticles, PRINTING ink, NANOPARTICLE synthesis, GOLD, PLASTIC optical fibers, SURFACE tension

Abstract

Among the conventional inks used for inkjet printing, metals, oxides, or polymers have been deposited in order to form functional coatings. Gold is one of the most used metals for electrode fabrication in the gas sensor field due to its inert behavior when exposed to reactive gases and conductive properties. However, only a few commercial gold inks are commercially available, and the combination of excessive price, a high minimum purchase quantity, and an unknown composition renders the actual products unappealing. To meet these shortcomings, gold inks were formulated with different solvents in order to reach sufficient properties for the inkjet printing process, such as surface tension and viscosity. On the one hand, gold ink was developed using a gold nanoparticle (AuNP) solution as the metal. This ink was optimized from nanoparticle synthesis, with the ink formulation obtaining a 32 mN·m−1 surface tension and 11.2 mPa·s viscosity in order to be inkjet-printed onto polyimide foil. On the other hand, a particle-free ink, called a precursor based of ink, was also developed. In this case, ink was made by solubilizing gold salt in aqueous medium in order to reach jettable properties. Surface tension was measured at 32 mN·m−1 while viscosity was 14.0 mPa·s. Then, printing and deposition parameters were optimized in order to obtain a highly conductive gold coating. The measured resistivity was 2 × 10−7 Ω·m which is close to the bulk gold conductive value. These coatings could be used for the fabrication of various devices in different working fields. [ABSTRACT FROM AUTHOR]

Published

2024

40. On the cogent formulation of an elastomeric silicone ink material for direct ink write (DIW) 3D printing.

Author

Elahee, G. M. Fazley, Cheng, Xiang, Rong, Lihan, Xu, Ming‐Wei, Souza, Lucio, Advincula, Rigoberto C., and Maia, Joao

Subjects

THREE-dimensional printing, ELASTOMERS, MANUFACTURING processes, SILICONE rubber, PRINTING ink, ADHESIVES, INK, SILICONES

Abstract

Adhesives and sealants show fine rheology with good physical and mechanical properties as viscous pastes, a possible starting point for developing direct ink writing (DIW) 3D printing ink. However, many commercial adhesives and sealants take days or weeks to cure fully. DIW 3D‐printed parts made directly from these sealants are not designed for a scalable manufacturing process and high‐volume production. Moreover, most of these adhesives and sealants have volume shrinkage during cure. A systematic understanding of formulation methods and design principles for an elastomeric silicone DIW ink can overcome these issues. This study presents the cogent formulation development of a 3D printable thermoset elastomer silicone that gels and cures isotropically in minutes, reducing cycle time for rapid ink development with no shrinkage during cure. More specifically, we outline the principles of raw material selection of a formulation to achieve excellent rheology, printability, synchronized working, and gel time fitting requirements closer to scalable manufacturing. The reaction kinetics and their corresponding 3D‐printed structural properties are also described. Interest in future work is toward a rational DIW 3D printing ink material development protocol and use of machine learning (ML). Highlights: Formulation method flexibility and design principle of DIW ink.Raw material selection principle to achieve optimal rheology for DIW printing.Ink gel kinetics for large‐scale DIW manufacturing.Hydrosilylation conversion over time at different ambient temperatures.Structural properties of DIW 3D printed parts. [ABSTRACT FROM AUTHOR]

Published

2024

41. Investigation of surface free energy of palm oil-based offset printing ink on coated paper.

Author

Suryadi, Gema Sukmawati, Nikmatin, Siti, Susiani, Susiani, and Setyaningsih, Dwi

Subjects

*OFFSET printing, *PRINTING ink, *SURFACE energy, *FREE surfaces, *LINSEED oil, *VEGETABLE oils, *FATTY acid methyl esters

Abstract

The widely use of petroleum-derived mineral oils for the production of offset printing inks has resulted in several environmental impacts. The suitable approach to develop alternative resources is palm oil fatty acid methyl ester (FAME) as a substitute for petroleum-based solvent. This study aimed to investigate the surface properties of palm oil-based offset ink on gloss-coated paper surfaces in terms of printability. The "green" varnishes were prepared with palm oil FAME as solvent, rosin-modified phenolic resin, and different vegetable oils linseed oil (FAME-LO) and soybean oil (FAME-SO) have been used as drying oils. The FAME-based Cyan offset printing inks have been prepared their properties compared with standard conventional inks. Printing tests were carried out using the IGT-A2 printability tester. Contact angles of water, methanol, and hexane on the surface of printed ink were measured using Contact Angle Analyzer. The surface free energy (SFE) and its components were calculated using Girifalco-Good-Fowkes-Young, Owens-Wendt, and van Oss-Chaudhury-Good methods. The results showed that as the liquid contact angle increased, the surface energy decreased. The surface energy of FAME-SO ink printed samples 36.36 mJ/m2 was higher than the unprinted paper 35.84 mJ/m2. Since high surface energy will affect the bond strength of the ink to the substrate, this will be an advantage for multicolor prints requiring good ink adhesion, which will enlarge the acceptance of other colors to be printed on the previous color. [ABSTRACT FROM AUTHOR]

Published

2024

42. Comparison of the Quality of Ink Prints on the Market on Coated and Uncoated Paper.

Author

Rahmayanti, Handika Dany, Murniati, Riri, Supardianningsih, Hastuti, Novitri, Zulfi, Akmal, Fitriady, Yunus, Darmanto, Nova, Andayu, Haryasena Gusti, and Rafryanto, Ande Fudja

Subjects

PRINTING ink, OPACITY (Optics), ELECTRONIC paper, QUALITY control

Abstract

Printing inks of various brands are available in the field. Available colors include Cyan, Magenta, Yellow, and Black. Ink is an important parameter in determining print quality. Optical density is one of the important parameters used to control print quality. The optical density of the printed material is a form of ink-paper interaction. This research is oriented toward investigating the optical density value of Cyan printing ink on coated and non-coated paper. The main objective of this research is to analyze the effect of printing ink thickness on the optimal density value. Optical density values of Cyan prints were obtained using densitometer measurements, printed with the IGT method on coated and uncoated paper. The optical density values of several types of ink on the market that have been printed on coated and uncoated paper have never been reported before. [ABSTRACT FROM AUTHOR]

Published

2024

43. One-Pot Synthesis of Functionalised rGO/AgNPs Hybrids as Pigments for Highly Conductive Printing Inks.

Author

Belessi, Vassiliki, Koutsioukis, Apostolos, Giasafaki, Dimitra, Philippakopoulou, Theodora, Panagiotopoulou, Vassiliki, Mitzithra, Christina, Kripotou, Sotiria, Manolis, Georgios, Steriotis, Theodore, Charalambopoulou, Georgia, and Georgakilas, Vasilios

Subjects

*CONDUCTIVE ink, *PRINTING ink, *PIGMENTS, *GRAPHENE oxide, *SILVER salts, *GUMS & resins

Abstract

This work provides a method for the development of conductive water-based printing inks for gravure, flexography and screen-printing incorporating commercial resins that are already used in the printing industry. The development of the respective conductive materials/pigments is based on the simultaneous (in one step) reduction of silver salts and graphene oxide in the presence of 2,5-diaminobenzenesulfonic acid that is used for the first time as the common in-situ reducing agent for these two reactions. The presence of aminophenylsulfonic derivatives is essential for the reduction procedure and in parallel leads to the enrichment of the graphene surface with aminophenylsulfonic groups that provide a high hydrophilicity to the final materials/pigments. [ABSTRACT FROM AUTHOR]

Published

2024

44. Hydrogel Ink for 3D Printing with High and Widely Tunable Mechanical Properties via the Salting‐Out Effect.

Author

Ko, Kun Woo, Lee, Taehoon, Jeong, Jae‐Hak, Lee, Yeonteak, Kim, Ikjin, Seo, Jungmok, Park, Yong‐Hwa, Kim, Jin‐Oh, and Park, Steve

Subjects

*THREE-dimensional printing, *PRINTING ink, *BIOMIMETICS, *BLOOD substitutes, *TISSUES

Abstract

Due to the difficulty of simultaneously ensuring printability and controlling their mechanical properties, 3D printed hydrogels thus far have low modulus, far less than that of many biological tissues and organs. Therefore, their feasibility toward various biomimetic applications is currently limited. Herein, Direct‐Ink‐Writing (DIW) based 3D printable hydrogel ink with broadly adjustable mechanical properties is introduced. The salting‐out effect is utilized to effectively lower the gelation temperature of hydrogel inks with a wide range of modulus (0.193–1.072 MPa), making them all 3D printable. As a proof of concept, multi‐layered synthetic blood vessels that mimic the mechanical properties of biological blood vessels are printed, and their practicability toward surgical training is demonstrated. The versatility and simplicity of this technique make it highly promising for use in various 3D‐printed hydrogel biomaterials applications. [ABSTRACT FROM AUTHOR]

Published

2024

45. A study of the migration behavior of formaldehyde in different concentrations of ethanol in paper food materials.

Author

Cao, Yu, Zhong, Zehui, Zeng, Fanqi, and Zhou, Yang

Subjects

FORMALDEHYDE, ETHANOL, OFFSET printing, PRINT materials, LIQUID chromatography, DETECTION limit, PRINTING ink

Abstract

To ensure the safety of food contact materials, a liquid chromatography method was established to determine the migration of formaldehyde in paper packaging with various food simulants (10%, 25%, 50%, 75%, and 95% ethanol by volume) and to investigate the migration behavior of formaldehyde after various durations and with various materials. The results showed that the method has good linearity with a correlation coefficient of R2 > 0.9990, a detection limit of 0.0011 ~ 0.0027 mg L−1, and a spiked recovery of 89.7 ~ 103.2% in the range of formaldehyde determination; the migration of formaldehyde in all six paper contact materials showed a trend of gradual increase with time until equilibrium was reached. At the same time and temperature, the migration of formaldehyde in paper packaging was the highest in low-concentration ethanol. With the same food simulants and materials, the maximum migration of formaldehyde in printed materials was greater than that in nonprinted materials; with different materials and the same food simulant, the thickness value was higher, with the use of water-based ink as a printing material, and the maximum migration value of formaldehyde by offset printing technology was low. [ABSTRACT FROM AUTHOR]

Published

2024

46. Additive manufacturing of interconnected hierarchically porous zirconia: Utilizing both microspherical and filamentary pore-forming agents via direct ink printing.

Author

Wang, Feihong, Chen, Shenggui, Zheng, Ke, Shang, Xin, Li, Nan, Khan, Sadaf Bashir, Gao, Fei, and Sun, Jinxing

Subjects

*PRINTING ink, *SLURRY, *SCANNING electron microscopes, *BONE regeneration, *ZIRCONIUM oxide, *STRUCTURAL engineering, *CELL anatomy

Abstract

Osteogenic differentiation and bone regeneration can be effectively aided by porous scaffolds with multiscale cellular structures, making it easier to repair defects in bone tissue. Due to the scarcity of pore-forming agents, it is extremely challenging to fabricate interconnected hierarchically porous zirconia at multi-scale. This work described a novel and straightforward method for directly imprinting a slurry containing two pore-forming agents (microspherical and filamentary) to produce strong and highly porous zirconia (ZrO 2) ceramics with four levels of porosity ranging from nanometers to millimeters. The concentration of hemp fibers significantly affected printability when the rheological behavior of a zirconia slurry was examined. Utilizing a scanning electron microscope (SEM) to monitor the development of powder interstices under various sintering techniques. The permeability performance was assessed when simulated plasma had fully filled the scaffolds. The structure had a high compressive strength of 24.18 MPa, a porosity of 80.9 %, an apparent porosity of 55.7 %, and took just 1.11 s to fill a scaffold that was 15 mm high. It is anticipated that the proposed route will be expanded to include various engineering materials for structural and practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

47. Subtractive Patterning of Nanoscale Thin Films Using Acid‐Based Electrohydrodynamic‐Jet Printing.

Author

Cho, Tae H., Farjam, Nazanin, Barton, Kira, and Dasgupta, Neil P.

Subjects

*NANOFILMS, *ATOMIC layer deposition, *ZINC oxide films, *RAPID prototyping, *PRINTING ink, *ZINC oxide

Abstract

As an alternative to traditional photolithography, printing processes are widely explored for the patterning of customizable devices. However, to date, the majority of high‐resolution printing processes for functional nanomaterials are additive in nature. To complement additive printing, there is a need for subtractive processes, where the printed ink results in material removal, rather than addition. In this study, a new subtractive patterning approach that uses electrohydrodynamic‐jet (e‐jet) printing of acid‐based inks to etch nanoscale zinc oxide (ZnO) thin films deposited using atomic layer deposition (ALD) is introduced. By tuning the printing parameters, the depth and linewidth of the subtracted features can be tuned, with a minimum linewidth of 11 µm and a tunable channel depth with ≈5 nm resolution. Furthermore, by tuning the ink composition, the volatility and viscosity of the ink can be adjusted, resulting in variable spreading and dissolution dynamics at the solution/film interface. In the future, acid‐based subtractive patterning using e‐jet printing can be used for rapid prototyping or customizable manufacturing of functional devices on a range of substrates with nanoscale precision. [ABSTRACT FROM AUTHOR]

Published

2024

48. New thiadiazol azo disperse dyes derivatives and their application as a colored material for silk screen-printing ink for printing on polyester fabric.

Author

Abdelwahab, Hamada, A.M. Al-Zahrani, Fatimah, Ali, Ali A., Mahmoud, Ammar, and Lin, Long

Subjects

*AZO dyes, *SILK fibroin, *DISPERSE dyes, *PRINTING ink, *POLYESTERS, *NUCLEAR magnetic resonance, *TEXTILE printing

Abstract

Purpose: This paper aims to synthesize new screen-printing ink formula based on new derivatives of azo thiadiazol disperse dyes and evaluate their characteristics after being printed on polyester fabric substrates. Design/methodology/approach: New dispersed dyes based on 1, 3, 4-Thiadiazole derivatives (dyes 1 and 2) were prepared and confirmed by different analyses, infrared (IR), mass and nuclear magnetic resonance (NMR) spectroscopy, and then formulated as colored materials in the screen-printing ink formulations. Printing pastes containing the prepared dyestuffs and other ingredients were used for printing polyester using screen-printing or traditional printing. The characteristics of printed polyester fabric substrates were measured by color measurements such as a*, b*, L*, C*, E, Ho, R% and color strength, as well as light, washing, crock and alkali perspiration fastness, and finally, the depth of penetration was evaluated. Findings: The prepared 1, 3, 4-Thiadiazole derivatives (dyes 1 and 2) were obtained from the reaction of 5,5'-(1,4-phenylene)bis(1,3,4-Thiadiazole-2-amine) with resorcinol and m-toluidine as a coupling component. The suitability of the prepared dyestuffs for silk screen-printing on polyester fabrics has been investigated. The prints obtained from a formulation containing dye 1 possess high color strength as well as good overall fastness properties if compared to those obtained using dye 2. Practical implications: The method of synthesis of the new dyestuffs and screen-printing ink provides a simple and practical solution to prepare some new heterocyclic disperse azo dyes, and they are formulated in the screen-printing inks for printing on a polyester fabric substrate. Originality/value: The prepared disperse dyes based on 1,3,4-Thiadiazole derivatives (dyes 1 and 2) could be used in textile printing of polyester on an industrial scale. [ABSTRACT FROM AUTHOR]

Published

2024

49. Visible Meta‐Displays for Anti‐Counterfeiting with Printable Dielectric Metasurfaces.

Author

Gong, Jintao, Xiong, Lingxing, Pu, Mingbo, Li, Xiong, Ma, Xiaoliang, and Luo, Xiangang

Subjects

*DIELECTRICS, *VISIBLE spectra, *MASS production, *OPTICAL devices, *PRINTING ink

Abstract

Metasurfaces, 2D arrays of nanostructures, have gained significant attention in recent years due to their ability to manipulate light at the subwavelength scale. Their diverse applications range from advanced optical devices to sensing and imaging technologies. However, the mass production of dielectric metasurfaces with tailored properties for visible light has remained a challenge. Therefore, the demand for efficient and cost‐effective fabrication methods for metasurfaces has driven the continuing development of various techniques. In this research article, a high‐throughput production method is presented for multifunctional dielectric metasurfaces in the visible light range using one‐step high‐index TiO2‐polymer composite (TPC) printing, which is a variant of nanoprinting lithography (NIL) for the direct replication of patterned multifunctional dielectric metasurfaces using a TPC material as the printing ink. The batch fabrication of dielectric metasurfaces is demonstrated with controlled geometry and excellent optical response, enabling high‐performance light‐matter interactions for potential applications of visible meta‐displays. [ABSTRACT FROM AUTHOR]

Published

2024

50. Fast and Massive Pixel-Level Morphology Detection by Imaging Processing for Inkjet Printing.

Author

Zhang, Haoyang, Xu, Da, Ke, Shanrong, Huang, Meicong, Chai, Yaling, Lin, Yi, Guo, Ziquan, and Chen, Zhong

Subjects

INK, IMAGE processing, LIGHT emitting diodes, ELECTRONIC equipment, PRINTING ink, MORPHOLOGY, DETECTORS

Abstract

With the rapid development of the emerging intelligent, flexible, transparent, and wearable electronic devices, such as quantum-dot-based micro light-emitting diodes (micro-LEDs), thin-film transistors (TFTs), and flexible sensors, numerous pixel-level printing technologies have emerged. Among them, inkjet printing has proven to be a useful and effective tool for consistently printing micron-level ink droplets, for instance, smaller than 50 µm, onto wearable electronic devices. However, quickly and accurately determining the printing quality, which is significant for the electronic device performance, is challenging due to the large quantity and micron size of ink droplets. Therefore, leveraging existing image processing algorithms, we have developed an effective method and software for quickly detecting the morphology of printed inks served in inkjet printing. This method is based on the edge detection technology. We believe this method can greatly meet the increasing demands for quick evaluation of print quality in inkjet printing. [ABSTRACT FROM AUTHOR]

Published

2024