Relevant bibliographies by topics / Screen printing

Academic literature on the topic 'Screen printing'

Author: Grafiati
Published: 4 June 2021
Last updated: 14 March 2023

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Journal articles on the topic "Screen printing"

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Wheelwright, J. S. "Screen Printing." Journal of the Society of Dyers and Colourists 54, no. 7 (October 22, 2008): 319–22. http://dx.doi.org/10.1111/j.1478-4408.1938.tb02017.x.

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Hobby, A. "Fundamentals of Screens for Electronics Screen Printing." Circuit World 16, no. 4 (March 1990): 16–28. http://dx.doi.org/10.1108/eb046094.

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Overill, Ralph. "Between the screens: Screen-printing moving images." Journal of Arts Writing by Students 4, no. 1 (March 1, 2018): 37–47. http://dx.doi.org/10.1386/jaws.4.1.37_1.

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ITO, Nobuto. "Screen Printing Inks." Journal of the Japan Society of Colour Material 61, no. 5 (1988): 303–8. http://dx.doi.org/10.4011/shikizai1937.61.303.

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Beton, E. S. "IV-Screen Printing." Journal of the Society of Dyers and Colourists 63, no. 4 (October 22, 2008): 100–101. http://dx.doi.org/10.1111/j.1478-4408.1947.tb02452.x.

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Handono, Sulis Dri, Mafruddin Mafruddin, Ari Dwi Prasetyo, Bambang Iswadi, and Riki Purnomo. "Rancang bangun mesin sablon cup semi otomatis." ARMATUR : Artikel Teknik Mesin & Manufaktur 3, no. 2 (September 27, 2022): 79–87. http://dx.doi.org/10.24127/armatur.v3i2.2859.

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Screen printing is a technique of printing graphic designs using gauze or called screens. One application of the screen printing machine is on the cup. The more beverage vendors in cup packaging like today, the more screen printing machines are needed. To meet these needs, a cup screen printing machine was made. The purpose of the study was to determine the shape and dimensions as well as the performance of the semi-automatic cup screen printing machine. The research method carried out is by designing and manufacturing a semi-automatic cup screen printing machine and testing with two different types of molding, namely 14 Oz and 16 Oz. From the results of the design and manufacture of the semi-automatic cup screen printing machine design, the length is 600 mm, the width is 400 mm and the height is 900 mm. Using an electric motor of 0.25 HP, gear box 1:60, screen length of 400 mm and width of 150 mm and using a steel frame ST 37 type L. Based on the results of tests and calculations it is known that the production capacity of the screen printing machine is 300 cups/hour and the quality production with 14 Oz molding type is 92% good, 4.67% normal, 2.6% bad while 16 Oz molding is 88% good, 7.34% normal, 4.6% bad. The electrical power consumption of the screen printing machine is 328.6 Watt and the mechanical efficiency is 54.04 %.
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SANO, Yasushi. "Advanced Screen Printing Techniques." Journal of the Japan Society of Colour Material 85, no. 3 (2012): 117–21. http://dx.doi.org/10.4011/shikizai.85.117.

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Baudry, H. "Screen Printing Piezoelectric Devices." Microelectronics International 4, no. 3 (March 1987): 71–74. http://dx.doi.org/10.1108/eb044294.

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Vasilantone, Mark. "Faster, Better Screen Printing." Metal Finishing 110, no. 2 (March 2012): 39–40. http://dx.doi.org/10.1016/s0026-0576(13)70117-x.

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Mackenzie, F. W. "MACKENZIE-“SLIK SCREEN PRINTING”." Journal of the Society of Dyers and Colourists 54, no. 5 (October 22, 2008): 196–209. http://dx.doi.org/10.1111/j.1478-4408.1938.tb02006.x.

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Dissertations / Theses on the topic "Screen printing"

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White, Gordon Sutherland. "Mathematical models of screen printing." Thesis, University of Oxford, 2006. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.437003.

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Dolden, Elisabeth Diane. "Fundamental investigations into screen printing." Thesis, University of Leeds, 2005. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.422613.

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Medina, Rodríguez Beatriz. "Inkjet and screen printing for electronic applications." Doctoral thesis, Universitat de Barcelona, 2016. http://hdl.handle.net/10803/400486.

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Printed electronics (PE) is a set of printing methods used to create electrical devices on various substrates. Printing typically uses common printing equipment suitable for defining patterns on material, such as screen printing, flexography, gravure, offset lithography, and inkjet. Electrically functional, electronic or optical inks are deposited on the substrate, creating active or passive devices. PE offers a great advantage when compared to traditional processes or microelectronics due to its versatility, low manufacturing cost and the possibility of generating flexible circuit componentsi. Furthermore, these techniques are suitable for roll-to-roll processes and open the possibility for printing large areas and in a large-scale production. . The selection of the printing technique is crucial to achieve a good result and it will largely depend on both, the material needed and dimensional and functional requirements pursued. Each technology offers different possibilities in terms of resolution, complexity, versatility, speed, layers thickness, materials, reliability and scalability. This work aims to dig deeper into two of the main techniques in the world of printed electronics: screen printing and inkjet printing for different applications and for the manufacturing of different devices. In addition, the capabilities of a technology that is currently in growing development (inkjet) are analyzed in comparison with the mature screen printing technique to give a wider insight of the advantages and limitations that this technology offers. The totally knowledge in this technique is still in progress and it arises to be a trend in technological and scientific aspects due to the barely availability of functional materialsii and the difficulties in achieving a precise control on the drop formation and its interaction in the final system. A better understanding of these technological issues, as well as the approaching to current difficulties in electronic applications is accomplished in this thesis. Up-to-date issues as the reliability of flexible resistive gas sensors, solution-based synthesis of absorber layers in thin film solar cells and the tuning and area reducing for inductors in RF applications are tackled. The main objective in this thesis arises from the need of expanding the knowledge on inkjet printing by exploring affordable new possibilities, taking as starting point the previous knowledge of screen printing. To pursue this goal, the comparison between SP and IP is presented along the thesis. The framework of this thesis is not solely an overview of the development of functional materials for both techniques, but also the investigation of its final implementation reliability in several devices for different electronic applications. The structure of this thesis dissertation can be divided in two well defined blocks. In chapter 2 and 3, both printing techniques are explained in detail, while in Chapter 4, 5 and 6, the potential of both technologies are studied for different electronic applications by means of the fabrication and characterization of different devices. In chapter 2, the main topic is the analysis of the inkjet printing technique. This chapter follows the attainment of two different objectives: the establishment of a quality evaluation guideline for any inkjet ink and as example of it, the formulation of our own silver ink developed in our laboratory. In this sense, the most important properties for the functional materials which should be under control during its formulation are reviewed; as well as the fundamentals and main parameters during the printing process, which affect the outcome quality. Instead, in chapter 3, the fundamentals of screen printing technique are quickly overviewed due to the consolidation of the technique knowledge and the previous studies on it done in the field, and specifically at FAE Company. In the second block of this thesis, the description of the printing techniques leads to the implementation of both, inkjet and screen printing, in different electronic fields. The chapters involving this block are focused in the printing step during its fabrication, the printing and functional material quality characterization, and the influence of this printing step in the functional performance of the devices. Chapter 4 is a comparison between low-cost flexible resistive sensor platforms with heater fabricated by both, SP and IP techniques. The performance of these sensor platforms was checked by long-term characterization and aging tests to identify the causes of the device failure. Chemical degradation of silver is observed in SP-devices due to the flake-like morphology of the deposits but not in the smooth sintered silver tracks deposited by IP. However, the IP very thin film promotes failure by hot spot phenomena. Design improvements are, hence, implemented to overcome the drawbacks of silver corrosion and power consumption. The final devices turned to be sturdy, wearable and reliable gas sensor platforms. In Chapter 5, IP is implemented in the step of the absorber layer synthesis for the fabrication of kesterite thin film solar cells. Copper-Zinc-Tin-Sulfur (CZTS) precursor ink is formulated and optimized for the enhancement of the solar cell performance. The influence of the formulation and the printing process is analyzed. Finally, the thickness of the deposited precursor was modified until obtained a cell with 6.55% efficiency, the higher efficiency reported with this absorber type using IP as deposition method. In the last chapter, Chapter 6, spiral inductors are fabricating using the two printing technologies in LTCC (low-temperature-cofired-ceramics). IP, although turning out to be a suitable technology for enhancing the accuracy of narrower tracks than SP and thus, for increasing the number of turns within a concrete area, presents difficulties to achieve a certain value in electrical conductivity due to the deposition of very thin conductor layers. For this reason, in this part of the thesis, a combination of IP with electroless copper deposition is used to overcome this limitation and to develop equivalent performances using SP and IP devices.
La electrónica impresa permite la impresión de dispositivos electrónicos ofreciendo una gran ventaja en comparación con procesos tradicionales o microelectrónica debido a su versatilidad, bajo coste de producción y posibilidad de generar circuitos flexibles. La selección del método de impresión es crucial a la hora de alcanzar un buen resultado y depende de los materiales necesarios y de los requerimientos dimensionales y funcionales. En esta tesis, la serigrafía, una técnica de impresión fiable y consolidada en la industria desde hace años, es comparada con la inyección de tinta (inkjet), que aún muestra un gran desafío en cuanto a rendimiento y reproducibilidad. Cada tecnología ofrece posibilidades diferentes en complejidad, resolución, grosor de capas y materiales. En la primera parte de la tesis se describen la inyección de tinta y la serigrafía en términos de fundamentos, parámetros y formulación de materiales. En la segunda parte, el potencial de ambas tecnologías se ha estudiado en diferentes escenarios mediante la fabricación de diversos dispositivos electrónicos. En el estudio de la fiabilidad y robustez de plataformas sensoras flexibles se ha encontrado una relación directa entre la morfología de la plata depositada y su causa de fallo en funcionamiento prolongado. La sinterización de las nanoparticulas depositadas por inkjet forma una capa lisa y con poca porosidad que evita parcialmente la corrosión, a diferencia de la pasta de plata impresa por serigrafía. Sin embargo, su bajo provoca defectos puntuales que puede causar puntos calientes. También, inkjet se ha empleado para la síntesis de precursores de la capa absorbente para celdas solares de capa fina. Se ha formulado una tinta de precursores de cobre, zinc, estaño y azufre (CZTS) para la formación de kesterita obteniéndose celdas de 6.55% de eficiencia, siendo la más alta reportada hasta la fecha utilizando este tipo de absorbente y tecnología. Sin embargo, en aplicaciones donde la conductividad es crucial para altas prestaciones, como en radiofrecuencia, queda patente la desventaja del inkjet sobre la serigrafía, donde su escaso grosor de capa es un claro hándicap para la obtención de conductividades elevadas. Dicho factor limitante es abordado con la combinación de la inyección de tinta con la deposición química (electroless) de níquel y cobre, consiguiéndose inductores equivalentes a los serigrafiados.
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Fox, Ian James. "Ink flow within the screen-printing process." Thesis, Swansea University, 2002. https://cronfa.swan.ac.uk/Record/cronfa42565.

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Screen-printing is one of the oldest printing processes, yet its market share remains very limited due to its slower printing speeds compared to the other available processes. This is mainly because of the reciprocating motion of the squeegee upon the printing screen. In order for screen-printing to become more competitive, the concept of a high-speed continuous belt screen-printing press was developed. However, this will produce an increase in squeegee wear and friction of the squeegee upon the screen. For this reason, this work investigated the use of a roller squeegee that could rotate across the screen. It has been proven that screen-printing with a roller squeegee can be successfully achieved. Additionally, in terms of density and tone gain, these images were comparable to those produced with traditional blade squeegees. A numerical model has been developed to simulate the characteristics that will be encountered within the ink film when printing with a roller squeegee. Numerical simulations were run where the settings corresponded to the parameters utilised in experimental trials. Here, it was discovered that an increase in squeegee diameter will increase the ink film on the squeegee and will also increase the contact width of the screen upon the substrate. This will have the effect of increasing the pumping capacity of the squeegee, which will therefore increase the ink deposit. This was confirmed in the experimental trials. It was also shown that the locking of the squeegee increased the shear mechanism within the ink film, resulting in a reduction in the ink viscosity within the nip contact region. This had the effect of reducing the ink film thickness on the squeegee, which reduces the pumping capacity of the squeegee, thus producing a reduced ink deposit. Additionally, this work is the first method that has been able to estimate the height of the ink deposit for a range of halftone open areas where the results correspond almost identically to the actual printed heights of the prints obtained in experimental studies. This work has improved the fundamental understanding of the mechanics and the process physics within the ink transfer mechanism in the screen-printing process. Use of experimental and numerical models has resulted in new theories being developed that will further the knowledge of the process. This has led to the design and manufacture of a high-speed rotary screen-printing press that will enable high-speed, continuous screen-printing.
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Taroni, Michele. "Thin film models of the screen-printing process." Thesis, University of Oxford, 2010. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.540261.

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Hill, Matthew Raymond. "Preparation of catalyst coated membranes using screen printing." Master's thesis, University of Cape Town, 2013. http://hdl.handle.net/11427/11834.

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Of the various types of fuel cells, Polymer Electrolyte Fuel Cells (PEFCs) have already been demonstrated in transportation appliances from light-duty vehicles to buses and in portable appliances including laptops and cell phones. A key component of a PEFC is its platinum electrocatalyst. With an estimated 75% of the world’s platinum reserves and resources in South Africa, local development of this technology will allow South Africa to become a major player in the growing hydrogen economy. This project therefore forms part of the Department of Science and Technologies strategy, to develop fuel cell technology in South Africa. More specifically, this study aims to contribute to the development of membrane electrode assembly (MEA) platform technology at the HySA/Catalysis Centre. In order to achieve this goal, a catalyst coated membrane (CCM) fabrication procedure was implemented using a newly acquired screen printer. In this procedure, catalyst ink is forced through a mesh onto a substrate, where it can then be transferred to a membrane via decal transfer to form a CCM. Two gas diffusions layers can then be placed on either side of the CCM forming a 5-layered MEA. Characterisation techniques of the catalyst ink, CCM and 5-layered MEA were successfully implemented such that future researchers can expand on the ideas. Catalyst inks with varying amounts of isopropanol, 1,2-propanediol and water were screened for their suitability for screen printing. In particular the catalyst ink rheology required for a smooth and even printed surface was determined for a given screen and squeegee combination. With all the established steps in pace, screen printing proved to be a fast and reliable approach for CCM fabrication with potential for future scale up and commercialisation. The fabricated CCMs performed on a par with a commercial Ion Power CCM, but under performed in comparison to a commercial Johnson Matthey (JM) MEA. Possible reasons for this include improved materials in the JM MEA and cell conditions favouring the JM MEA. Future projects which specifically arise from this work entail an investigation into the water management of the fuel cell environment at HySA/Catalysis, as well as a modification of the various steps in order to optimise the process and in doing so manufacture commercially viable MEAs.
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Bougàs, Aristotelis Platon. "Influence of ink sequence on color's hue and saturation in four color halftone screen printing /." Online version of thesis, 1993. http://hdl.handle.net/1850/11080.

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Choudhry, Nadeem Azram. "New directions in screen printing and related fabrication processess." Thesis, Manchester Metropolitan University, 2013. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.588608.

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This thesis reports the development of screen printed electrodes and associated fabrication processes in order to develop and understand new electrochemical based sensors. There are three main sections to this thesis. In the first part, an overview of sensors, in particular electrochemical sensors, that are commercially available and their current problems and limitations with conventional electrodes and electrode materials is discussed. Second, an introduction into screen printing and their advantages are given. The full process by which these next generation electrodes are manufactured is thoroughly described followed by examples of screen printed-electrodes and their powerful application as well as their low detection limits which compare well to existing literature on the market. The first example of a copper (11) oxide screen-printed electrode is reported, which is characterised with microscopy and its efficiency for the electrochemical sensing of glucose, maltose, sucrose and fructose is explored. It is shown that the non-enzymatic electrochemical sensing of glucose with cyclic voltammetry and amperometry is possible with low micro-molar up to milli-molar glucose readily detectable, which compares competitively with nano-catalyst modified electrodes. An additional benefit of this approach is that metal oxides with known oxidation states can be incorporated into the screen- printed electrodes allowing one to identify exactly the origin of the observed electro- catalytic response which is difficult when utilising metal oxide modified electrodes formed via electro-deposition techniques which result in a mixture of metal oxides/oxidation states. These next generation screen printed electrochemical sensing platforms provide a simplification offering a novel fabrication route for the mass production of electro-catalytic sensors for Analytical and Forensic applications. Other examples such as, bespoke screen printed electrodes which can be used as a template to produce randomly dispersed electro- catalytic micro-domains for analytical sensing purposes, are also shown to further demonstrate the applications and utility of screen printed electrodes. The final section focuses on electrode design. It is demonstrated that the electron transfer properties of disposable screen-printed electrodes can be readily tailored via the introduction of a polymeric formulation into the ink used in their fabrication. This approach allows the role of the binder on the underpinning electrochemical properties to be explored and quantified for the first time, allowing the electrochemical reactivity of the screen- printed electrodes to be tailored from that of edge plane-like to basal plane-like reactivity of highly ordered pyrolytic graphite. Building on this fundamental study of the origin of electron transfer at these novel electrodes, the first example of "Cosmetic Electrochemistry" is demonstrated where a commercially available cosmetic product, a deodorant, can be used to confer microelectrode behaviour on a macroelectrode. Proof-of-concept is shown that a graphite screen-printed electrode can be sprayed with an off-the-shelf cosmetic product and within seconds is ready to use. The polymer contained within the cosmetic product partially blocks the graphite screen-printed electrode surface leaving the underlying graphite electrode exposed in the form of graphite micron-sized sites which are randomly distributed across the electrode surface. The creation of microdomain sites enhance mass transport of the target analyte and it is shown that the electroanalytical performance of the cosmetically modified electrode, via the cathodic stripping of lead, could achieve a similar performance to current state-of-the-art methodologies. Further examples are also reported with the introduction of plaster-trodes where a commercially available plaster is electrolytically modified with electrocatalytic material and is used to detect various alcohols.
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Tan, Fang. "New developments in screen printing for advances in electroanalysis." Thesis, Manchester Metropolitan University, 2013. http://e-space.mmu.ac.uk/324232/.

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Within the discipline of electrochemistry, the sub-section that concerns itself with quantification is electroanalysis, which is the basis of portable and sensitive sensors; this is exemplified in the billion dollar glucose market where their development allows diabetics to measure their blood glucose on-the-spot without recourse to the clinic. Screen-printing is a suitable method to fabricate such a sensor which is mass-produced yet reproducible and economical in nature. In order for the next-generation of biosensors (such as the glucose sensors), advances in screen-printed electrode design needs to be made; this is exactly what this Master’s Thesis aims to achieve. This thesis first considers the fabrication of platinum screen-printed macroelectrodes, which are analytically explored and benchmarked towards the sensing of selected target analytes. Next, palladium screen-printed macroelectrodes are fabricated and characterised via microscopy and cyclic voltammetry, in particular, the electroanalytical applications are explored towards the sensing of formaldehyde, hydrazine and its potential use in gas sensors for the sensing of hydrogen and methane with comparisons made to existing literature reports. Note that such an electrode made entirely via screen-printing has not been reported before in the literature. In order to improve mass transport properties, shallow recessed screen-printed electrodes are designed and fabricated and benchmarked towards the sensing of NADH and nitrite. The electroanalytical sensing of nitrite is further testing within canal water samples showing the robust nature of the sensors analytical performance. Additionally these unique sensors were found to be electrochemically useful in sensing towards hydrazine and hydrogen peroxide. Finally, carbon screen-printed microelectrode arrays are fabricated and are benchmarked towards the sensing of acetaminophen, dopamine and nitrite. Note that this is 3 the first example of an array which exhibits diffusional independence (the current literature reports only arrays that have diffusional interaction) and as such gives rise to analytically useful measurements. This screen printed microelectrode array is also shown to be possible to be produced with gold working electrodes which are benchmarked towards the determination of Chromium (VI).
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Dulina, I. O., S. O. Umerova, and A. V. Ragulya. "Barium Titanate Thin Films Obtained by Screen Printing Technology." Thesis, Sumy State University, 2013. http://essuir.sumdu.edu.ua/handle/123456789/35153.

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Barium titanate thin films have been obtained using screen printing of pastes based on BaTiO3 na-nopowders. Obtained pastes have been characterized by optical microscopy and optical profilometry. De-posit pattern geometry fidelity in regard to screen mask and films thickness and roughness parameter Ra during screen printing parameters changing depended on pastes rheological behavior. In addition, films roughness and thickness were strongly depended on solid and solvent content in pastes. Solvent content rising and BaTiO3 content lowering resulted in films thickness and roughness decreasing. Depending on paste solid and content barium titanate films thickness was changed from 1.56 to 3.18 m, the film rough-ness Ra from 50 to 196 nm and Rz from 160 to 393 nm. When you are citing the document, use the following link http://essuir.sumdu.edu.ua/handle/123456789/35153
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Books on the topic "Screen printing"

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Kosloff, Albert. Photographic screen printing. 7th ed. Cincinnati, Ohio, U.S.A: Signs of the Times Pub. Co., 1987.

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Magee, Babette. Screen printing primer. Pittsburgh, Pa: Graphic Arts Technical Foundation, 1985.

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Screen process printing. 2nd ed. London: Blueprint, 1995.

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Banks, Craig E., Christopher W. Foster, and Rashid O. Kadara. Screen-Printing Electrochemical Architectures. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-25193-6.

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Textile/garment screen printing. 4th ed. Cincinnati, Ohio: ST Publications, 1987.

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Screen printing: Design & technique. London: B. Batsford, 1990.

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Screen printing production management. Cincinnati, Ohio: ST Publications, 1989.

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O'Kelley, Hallie H. Screen printing for quilters. Montgomery, AL: Black Belt Press, 1995.

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Screen printing: A contemporary approach. Albany: Delmar, 1997.

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MacDougall, Andy. Screen printing today-- the basics. Courtenay, B.C., Canada: MacDougall Screen Printing, 2005.

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Book chapters on the topic "Screen printing"

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Keeler, Robert. "Screen Printing." In The Electronics Assembly Handbook, 293–300. Berlin, Heidelberg: Springer Berlin Heidelberg, 1985. http://dx.doi.org/10.1007/978-3-662-13161-9_50.

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Gooch, Jan W. "Screen Printing." In Encyclopedic Dictionary of Polymers, 649. New York, NY: Springer New York, 2011. http://dx.doi.org/10.1007/978-1-4419-6247-8_10361.

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Sauer, M., S. Meilchen, A. Kalleder, M. Mennig, and H. Schmidt. "Screen Printing." In Sol-Gel Technologies for Glass Producers and Users, 117–22. Boston, MA: Springer US, 2004. http://dx.doi.org/10.1007/978-0-387-88953-5_14.

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Clark, Raymond H. "Screen Printing." In Handbook of Printed Circuit Manufacturing, 216–44. Dordrecht: Springer Netherlands, 1985. http://dx.doi.org/10.1007/978-94-011-7012-3_11.

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Gooch, Jan W. "Silk Screen (Screen Process) Printing." In Encyclopedic Dictionary of Polymers, 666. New York, NY: Springer New York, 2011. http://dx.doi.org/10.1007/978-1-4419-6247-8_10665.

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Gooch, Jan W. "Rotary Screen Printing." In Encyclopedic Dictionary of Polymers, 638. New York, NY: Springer New York, 2011. http://dx.doi.org/10.1007/978-1-4419-6247-8_10149.

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Gooch, Jan W. "Screen Process Printing." In Encyclopedic Dictionary of Polymers, 649. New York, NY: Springer New York, 2011. http://dx.doi.org/10.1007/978-1-4419-6247-8_10362.

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Joannou, G. "Screen Inks." In The Printing Ink Manual, 481–514. Boston, MA: Springer US, 1988. http://dx.doi.org/10.1007/978-1-4684-6906-6_9.

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Joannou, J. "Screen Inks." In The Printing Ink Manual, 481–514. Dordrecht: Springer Netherlands, 1988. http://dx.doi.org/10.1007/978-94-011-7097-0_9.

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Sherazi, Tauqir A. "Screen Printing of Membranes." In Encyclopedia of Membranes, 1–2. Berlin, Heidelberg: Springer Berlin Heidelberg, 2014. http://dx.doi.org/10.1007/978-3-642-40872-4_757-1.

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Conference papers on the topic "Screen printing"

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Xiao, Gaozhi George, Zhiyi Zhang, Stephen Lang, and Ye Tao. "Screen printing RF antennas." In 2016 17th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM). IEEE, 2016. http://dx.doi.org/10.1109/antem.2016.7550245.

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Nakazawa, Akira, Michinori Kutami, Mitsuo Ozaki, Shigeharu Suzuki, and Hideyuki Kikuchi. "Electrostatic screen-through ink jet printing technique." In Printing Technologies for Images, Gray Scale, and Color, edited by Derek B. Dove, Takao Abe, and Joachim L. Heinzl. SPIE, 1991. http://dx.doi.org/10.1117/12.46343.

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Cao, Kun, Kai Cheng, and Ziliang Wang. "Optimization of Screen Printing Process." In 2006 7th International Conference on Electronic Packaging Technology. IEEE, 2006. http://dx.doi.org/10.1109/icept.2006.359881.

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Dressler, M., T. Studnitzky, and B. Kieback. "Additive manufacturing using 3D screen printing." In 2017 International Conference on Electromagnetics in Advanced Applications (ICEAA). IEEE, 2017. http://dx.doi.org/10.1109/iceaa.2017.8065283.

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Ney, Linda, Sebastian Tepner, Noah Wengenmeyr, Michael Linse, Andreas Lorenz, Sebastian Bechmann, Ralf Weber, Maximilian Pospischil, and Florian Clement. "Optimization of fine line screen printing using in-depth screen mesh analysis." In INTERNATIONAL SYMPOSIUM ON GREEN AND SUSTAINABLE TECHNOLOGY (ISGST2019). AIP Publishing, 2019. http://dx.doi.org/10.1063/1.5125871.

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Adachi, M., S. Funada, Y. Sakai, T. Kakuda, and T. Futakuchi. "Preparation of Bi4Ti3O12 Thick Films by Screen Printing." In 15th IEEE International Symposium on Applications of Ferroelectrics. ISAF 2006. IEEE, 2006. http://dx.doi.org/10.1109/isaf.2006.4387828.

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Wei, Lei, Zhang Xiaobing, Zhao Zhiwei, and Wang Baoping. "A screen-printing triode with low driving voltage." In 2009 22nd International Vacuum Nanoelectronics Conference (IVNC). IEEE, 2009. http://dx.doi.org/10.1109/ivnc.2009.5271673.

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Tajan, V., Paul Gonnard, and M. Troccaz. "Elaboration of PZT thick films by screen printing." In 3rd International Conference on Intelligent Materials, edited by Pierre F. Gobin and Jacques Tatibouet. SPIE, 1996. http://dx.doi.org/10.1117/12.237179.

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Horibe, Masahiro, and Ryo Sakamaki. "Impedance standard substrate fabricated by screen printing technology." In 2015 86th ARFTG Microwave Measurement Conference. IEEE, 2015. http://dx.doi.org/10.1109/arftg.2015.7381478.

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Szentgyörgyvölgyi, Rozália, Erszébet Novotny, and Milán Weimert. "DETERMINING AND SELECTING SCREEN PRINTING FORM PARAMETERS FOR PRINTING ON PAPER AND TEXTILE." In 9th International Symposium on Graphic Engineering and Design. Faculty of Technical Sciences, 2018. http://dx.doi.org/10.24867/grid-2018-p42.

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Reports on the topic "Screen printing"

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Martens, Niles. The paper stencil method of silk screen printing. Portland State University Library, January 2000. http://dx.doi.org/10.15760/etd.701.

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Ovalle, Samuel, E. Viamontes, and Tony Thomas. Optimization of DLP 3D Printed Ceramic Parts. Florida International University, October 2021. http://dx.doi.org/10.25148/mmeurs.009776.

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Abstract:
Digital Light Processing (DLP) 3D printing allows for the creation of parts with advanced engineering materials and geometries difficult to produce through conventional manufacturing techniques. Photosensitive resin monomers are activated with a UV-producing LCD screen to polymerize, layer by layer, forming the desired part. With the right mixture of photosensitive resin and advanced engineering powder material, useful engineering-grade parts can be produced. The Bison 1000 is a research-grade DLP printer that permits the user to change many parameters, in order to discover an optimal method for producing 3D parts of any material of interest. In this presentation, the process parameter optimization and their influence on the 3D printed parts through DLP technique will be discussed. The presentation is focused on developing 3D printable slurry, printing of complex ceramic lattice structures, as well as post heat treatment of these DLP-produced parts.
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Temporary worker dies when crushed in screen printing press. U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health, November 1994. http://dx.doi.org/10.26616/nioshsface94ma018.

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Health hazard evaluation report: HETA-82-212-1553, Screen Printing Shops. U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control, National Institute for Occupational Safety and Health, January 1985. http://dx.doi.org/10.26616/nioshheta822121553.

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NIOSH hazard controls HC15 - control of ergonomic hazards from squeegee handles in the screen- printing industry. U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health, June 1997. http://dx.doi.org/10.26616/nioshpub97137.

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Health hazard evaluation report: HETA-2007-0053-3092, employees' exposures to organic solvent vapors during screen printing, Inter Sign National Incorporated, Baltimore, Maryland. U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health, October 2009. http://dx.doi.org/10.26616/nioshheta200700533092.

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