Relevant bibliographies by topics / Fusible alloy

Academic literature on the topic 'Fusible alloy'

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Published: 30 May 2022
Last updated: 31 May 2022

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Journal articles on the topic "Fusible alloy"

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Press and Shear. "Fusible alloy tooling." Materials & Design 10, no. 5 (September 1989): 265–67. http://dx.doi.org/10.1016/s0261-3069(89)80067-6.

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Lee, Seong Hyuk, Jung Hee Lee, Jin Woon Lee, and Jong Min Kim. "Coalescence Characteristics of Fusible Particles in Solderable Isotropic Conductive Adhesives (ICAs)." Materials Science Forum 580-582 (June 2008): 213–16. http://dx.doi.org/10.4028/www.scientific.net/msf.580-582.213.

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A new hybrid soldering and conductive adhesive joining technology using a fusible lowmelting- point alloy (LMPA) have been developed. A numerical method for numerical analysis of fusible particles behavior is proposed to investigate coalescence characteristics of fusible particles in solderable isotropic conductive adhesives (ICAs). For finding out suitable conditions to obtain reliable conduction paths, the present study examines the influence of process-related parameters such as volume fraction and viscosity on coalescence characteristics of fusible particles.
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Kim, Se-Ho, Ji Yeong Lee, Jae-Pyoung Ahn, and Pyuck-Pa Choi. "Fabrication of Atom Probe Tomography Specimens from Nanoparticles Using a Fusible Bi–In–Sn Alloy as an Embedding Medium." Microscopy and Microanalysis 25, no. 2 (February 4, 2019): 438–46. http://dx.doi.org/10.1017/s1431927618015556.

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AbstractWe propose a new method for preparing atom probe tomography specimens from nanoparticles using a fusible bismuth–indium–tin alloy as an embedding medium. Iron nanoparticles synthesized by the sodium borohydride reduction method were chosen as a model system. The as-synthesized iron nanoparticles were embedded within the fusible alloy using focused ion beam milling and ion-milled to needle-shaped atom probe specimens under cryogenic conditions. An atom probe analysis revealed boron atoms in a detected iron nanoparticle, indicating that boron from the sodium borohydride reductant was incorporated into the nanoparticle during its synthesis.
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Jensen, William B. "The Origin of the Name “Onion’s Fusible Alloy”." Journal of Chemical Education 87, no. 10 (October 2010): 1050–51. http://dx.doi.org/10.1021/ed100764f.

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Kulikov, Mihail U., Vitaliy E. Inozemtsev, and Myo Naing Oo. "Technological Method for the Finishing Process of Fusible Alloy." Key Engineering Materials 581 (October 2013): 224–28. http://dx.doi.org/10.4028/www.scientific.net/kem.581.224.

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The way is developed by the combined process of finishing machining. In this method, surface treatment is due to the combined effects of cutting tool and anodic dissolution of metal under the influence of an electric current in the electrolytic solution. Applying of this method allow the processing of aluminum and copper alloys to obtain higher quality parameters of the obtained surface, including special material.
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Baudelet, B., M. C. Dang, and F. Bordeaux. "Mechanical behaviour of an aluminium alloy with fusible grain boundaries." Scripta Metallurgica et Materialia 26, no. 4 (February 1992): 573–78. http://dx.doi.org/10.1016/0956-716x(92)90286-n.

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El-Bediwi, Abu Bakr. "Effect of quaternary addition on structure, electrical, mechanical and thermal properties of bismuth-tin-zinc rapidly solidified fusible alloy." JOURNAL OF ADVANCES IN PHYSICS 7, no. 3 (February 23, 2015): 1952–58. http://dx.doi.org/10.24297/jap.v7i3.1592.

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Effect of quaternary addition, silver or indium, on structure, electrical, mechanical and thermal properties of bismuth-tin-zinc rapidly solidified fusible alloy have been investigated. Adding silver or indium caused change in alloy matrix microstructure such as matrix parameters and crystal structure of formed phase. A significant increase in bismuth-tin-zinc alloy strengthens with a little decreased in melting point after adding silver content. But a significant decrease in bismuth-tin-zinc alloy melting point with a very little increase in alloy strengthens after adding indium content
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Chartier, Thierry, Eric Delhomme, Jean François Baumard, Georg Veltl, and François Ducloux. "Injection moulding of hollow silicon nitride parts using fusible alloy cores." Ceramics International 27, no. 7 (January 2001): 821–27. http://dx.doi.org/10.1016/s0272-8842(01)00036-0.

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Geist, H., and M. Kottke. "Solderability Degradation Models for Fusible Tin Alloy Coatings on Copper Substrates." IEEE Transactions on Components, Hybrids, and Manufacturing Technology 11, no. 3 (September 1988): 270–73. http://dx.doi.org/10.1109/tchmt.1988.1134916.

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Geist, H., and M. Kottke. "Solderability degradation models for fusible tin alloy coatings on copper substrates." IEEE Transactions on Components, Hybrids, and Manufacturing Technology 11, no. 3 (September 1988): 270–73. http://dx.doi.org/10.1109/33.16652.

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Dissertations / Theses on the topic "Fusible alloy"

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Ганзюк, А. Л., and A. L. Hanzyuk. "Підвищення зносостійкості трибосистем номінальнонерухомих з’єднань в умовах малоамплітудного фретингу із застосуванням легкоплавких сплавів." Дисертація, 2019. http://elar.khnu.km.ua/jspui/handle/123456789/9365.

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Books on the topic "Fusible alloy"

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Tradizione, traduzione, tras-fusione: Dracula dal testo allo schermo. Roma: Aracne, 2007.

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Comelli, Pietro. Trieste a destra: Viaggio nelle idee diventate azione lontano da Roma : dalle origini del Msi alla svolta di An, dalla fusione del Pdl allo strappo dei futuristi. Trieste: Edizioni Il murice, 2013.

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Book chapters on the topic "Fusible alloy"

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"Fusible Alloys." In Metals Handbook Desk Edition, 670. ASM International, 1998. http://dx.doi.org/10.31399/asm.hb.mhde2.a0003161.

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Гоняный, М. И., and Т. Г. Сарачева. "“Whether the rich man – gold, or the poor man – tin, with each and his own lies delight therein”: medieval fusible alloys from the territory of Ustye archeological complex on the Kulikovo field." In The Archaeology of the Moscow region Proceedings of scientific seminar Issue 16, 162–201. Институт археологии РАН, 2021. http://dx.doi.org/10.25681/iaras.2020.978-5-94375-309-1.162-201.

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Conference papers on the topic "Fusible alloy"

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Hirano, Sei, Daisuke Hirasawa, Yoshihisa Kiyotoki, Keisuke Sakemura, Keiji Sasaki, and Yuta Fukuda. "Development of a Water Injection System Fusible Plug for Severe Accidents at Nuclear Power Plants." In 2020 International Conference on Nuclear Engineering collocated with the ASME 2020 Power Conference. American Society of Mechanical Engineers, 2020. http://dx.doi.org/10.1115/icone2020-16737.

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Abstract Background: When terminal stage of Severe Accident (SA) with no coolant injection at a nuclear power plant, the equipment that has cooled and solidified through water injection to a molten core that has ex-vessel and fallen outside of the pressure vessel will then be required to operate autonomously by heat detection, without external signals or power (e.g. electricity, air). The fusible plug operation is triggered by fusible alloy which receives heat from molten core and will melt. Because the fusible plug is also the boundary of Suppression Pool (S/P), high reliability is required for sealing performance. It is for that reason that Hitachi GE Nuclear Energy Ltd. (Hitachi-GE) has developed a fusible plug to serve as a device necessary to operate this system. Features of the Fusible Plug: The autonomous operation of the fusible plug is triggered by the melting of a fusible alloy, which is part of the fusible plug. However, the fusible alloy has a remarkably low mechanical strength and therefore is not suitable as a strength member. As such, it is necessary to ensure reliable plug sealing without applying a load to the fusible alloy so as to prevent the fusible plug from malfunctioning during normal operation. Therefore, to reduce the load to be applied to the fusible alloy, Hitachi-GE has developed a fusible plug structure that operates autonomously by detecting the ambient temperature without using the fusible alloy as a strength member. We have performed a verification test using this fusible plug and confirmed that it satisfies the predetermined performance requirements. Future Actions: Hitachi-GE is holding discussions on using the fusible plug at nuclear power plants in Japan. In the future, we plan to expand to the overseas.
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Kretschmer, I., P. Heimgartner, R. Polak, and P. A. Kammer. "New Fusible Alloys with Enhanced Corrosion Resistance." In ITSC 1997, edited by C. C. Berndt. ASM International, 1997. http://dx.doi.org/10.31399/asm.cp.itsc1997p0199.

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Abstract Fusible Ni-B-Si alloys with a variety of alloy additions (Cr, Mo, Cu etc.) have been in service for many years as fused coatings with moderate corrosion resistance. Both gas- and water-atomised powders have been used with the spray and fuse and with the plasma transferred arc process to produce coatings. As the severity of corrosive industrial environments has increased, for example in waste burning boilers, existing alloys have not provided the desired service performance. This study was undertaken to develop a new family of alloys with improved corrosion resistance without sacrificing usability, wear resistance or cost effectiveness. A range of compositions was prepared and evaluated for deposition characteristic, microstructure, hardness, wear resistance and corrosion resistance in various media. The resulting alloy has an exceptional combination of wear and corrosion resistance in comparison to conventional alloys, when tested under comparable conditions.
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Bo, Ke, Jinyang Zheng, Chunlin Gu, Baodi Zhao, Qianghua Huang, and Binbin Liao. "Experimental Studies on Discharge Characteristics of the Typical Thermally-Activated Pressure Relief Device Used for High-Pressure Hydrogen Storage Cylinder in Different Fire Conditions." In ASME 2019 Pressure Vessels & Piping Conference. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/pvp2019-93381.

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Abstract Thermally-activated pressure relief devices (TPRD) with glass bulbs or fusible alloy are applied to high-pressure hydrogen storage cylinders (HHSC), in order to release hydrogen gas from the cylinder in fire accidents. In this paper, cylinders with different TPRDs were tested in two groups using different bonfire test methods. In group A, the fire was set exactly under the TPRD. While in group B, the fire was set 80 mm beside the TPRD. The result shows that TPRDs with glass bulb and fusible alloy acted in a similar way when the fire was under the cylinder and the TPRD. However, they acted in a quite different way when the fire was only under the cylinder and beside the TPRD. In group A, hydrogen was released continuously from TPRD both for glass bulb and fusible alloy. In group B, hydrogen was released continuously from the TPRD using glass bulb which was similar to the group A. However, for TPRDs using a fusible alloy, hydrogen was released in several stages taking much more time. The results are instructive for the design and selection of TPRDs on HHSC.
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Sharma, Anil Kumar, K. Velusamy, N. Kasinathan, P. Chellapandi, S. C. Chetal, and Baldev Raj. "Thermal Hydraulic Analysis Towards a Robust Design of Leak Collection Tray for Pool Type Sodium Cooled Fast Reactors." In 18th International Conference on Nuclear Engineering. ASMEDC, 2010. http://dx.doi.org/10.1115/icone18-29294.

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To protect the sodium cooled FBR plant against the hazardous effects of sodium leak into the ambient, one of the passive protection devices used is the Leak Collection Trays (LCT) below the secondary sodium carrying pipelines in the Steam Generator Building (SGB). The design of LCT is based on immediate channeling of burning liquid sodium on the funnel shaped ‘sloping cover tray’ to the bottom ‘sodium hold-up vessel’ in which self-extinction of the fire occurs due to oxygen starvation. In the secondary heat transfer circuits of FBRs, leakage of liquid sodium from the pipelines is postulated as one of the design basis accidents with probability of occurrence at 10−2 per reactor year. LCT collect the leaked sodium in a hold up vessel, suppress the sodium fire due to oxygen starvation and guide the sodium to an inerted ‘sodium transfer tank’ located at the bottom most elevation of the SGB. The procedure of draining the leaked sodium into the transfer tank has been envisaged as a defense in depth measure against the handling of un-burnt sodium and to guard against larger leak rates than that can be handled by the LCT effectively. Towards this, a network of carbon steel pipelines are laid out connecting all the LCT and the transfer tank through headers in strategic locations, each having a fusible plug. The fusible plug separates the air environment in LCT and argon environment in sodium transfer tank. Woods metal is the preliminary choice for the fusible plug. It is an alloy of 50% Bi, 25% Pb, 12.5% Sn and 12.5% Cd with a melting point of 72°C. The transfer tank is filled with argon at ∼ 0.03 bars-g pressure. Both the header and the tank are at room temperature during normal conditions. Leaked sodium by virtue of its high temperature has to heat up the fusible plug to melt the same and drain into the transfer tank. Transient thermal hydraulic investigations have been carried out to predict the fusing characteristics of woods metal plug. The numerical results have been validated against analytical solutions for idealized conditions. Detailed parametric studies have been carried out with plug thickness as a parameter. It is established that effective melting of the plug and trouble free draining of the leaked sodium is possible for a 3 mm thick fusible plug.
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Lazarus, Nathan, Sarah S. Bedair, and Christopher Meyer. "Remoldable inductors based on self-heating fusible alloys." In 2014 IEEE Sensors. IEEE, 2014. http://dx.doi.org/10.1109/icsens.2014.6985312.

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6

Moskowitz, L. "The Effects of Post Heating an HVOF Sprayed Fusible Coating." In ITSC 1997, edited by C. C. Berndt. ASM International, 1997. http://dx.doi.org/10.31399/asm.cp.itsc1997p0519.

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Abstract Fusible coatings of Nickel-Chromium alloys with various amounts of Boron and Silicon commonly used for severe load applications. The coating is normally sprayed, then fused by heating to the point of liquation. The fusing process causes powder coalescence and increases density. At the same time, the high fusing temperatures creates a “brazed” bond which gives these coatings extremely high adhesive bond strengths. The improved bond strength is the result of the metallurgical bond as compared to the majority of thermal spray coatings which rely only on mechanical bonding mechanisms. The fusing operation is very sensitive, especially when a hand torch fuse is required. To circumvent these problems, a study was conducted to see if high density HVOF sprayed coatings might achieve fused quality by furnace heating to temperatures well below the liquation point. Various times and temperatures were surveyed. Bond strength tests of coatings sprayed to heavy thicknesses, hardness and impact tests, and metallography were used for evaluation. It was determined that heating as low as 1500° F for three hours could improve the properties of an as-sprayed HVOF coating to where it developed characteristics very similar to that of a fused coating.
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