Combustion Synthesis on Mechanoactivated FeTi+C Powder Mixtures; Energy Fluxes and Radiation Effects (EFRE-2020 online)

Combustion Synthesis on Mechanoactivated FeTi+C Powder Mixtures; Energy Fluxes and Radiation Effects (EFRE-2020 online)

Podrobná bibliografie
Parent link:	Energy Fluxes and Radiation Effects (EFRE-2020 online).— 2020.— [P. 1125-1128]
Korporativní autor:	Национальный исследовательский Томский политехнический университет Институт физики высоких технологий Кафедра материаловедения и технологии металлов Научно-образовательный центр "Современные производственные технологии"
Další autoři:	Baranovskiy A. Anton, Korthova V. Victoria, Pribytkov G. Gennady, Krinitsyn M. G. Maksim Germanovich
Shrnutí:	Title screen “Titanium carbide-iron binder” composite powders are synthesized in mechanically activated powder mixtures of ferrotitanium and carbon black. Two different synthesis modes are used: thermal explosion in specially made reactor and wave combustion synthesis in standard airtight reactor. Milling of FeTi powders is studied under mechanical activation by sieving. Optical metallography, X-ray diffraction analysis, and temperature measurements of MA mixtures and synthesis products were performed. No ignition was detected in non-mechanoactivated reactive mixtures. It is shown, that in the wave combustion mode even with 64g MA mixtures, the complete synthesis reaction does not occur. The minimum content of the unreacted phase is 6 wt.%. The target composition of the products with a complete consumption of reagents was obtained in the 10 min 64g MA mode. Thus, by the method of intensive MA followed by synthesis in the TE mode from a mixture of FeTi and carbon black powders, the “TiC+[alpha]-Fe” composite powders were obtained in which the starting reagents were not detected. Режим доступа: по договору с организацией-держателем ресурса
Jazyk:	angličtina
Vydáno:	2020
Témata:	электронный ресурс труды учёных ТПУ ferrotitanium titanium carbide combustion mechanical activation composite powder ферротитан карбид титана горение механическая активация композитные порошки
On-line přístup:	https://doi.org/10.1109/EFRE47760.2020.9242014
Médium:	Elektronický zdroj Kapitola
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=663092

Podobné jednotky

Structure of composite powders "TiC - high chromium cast iron binder" produced by SHS method; Mechanical Engineering, Automation and Control Systems (MEACS)
Autor: Kalambaeva S. S.
Vydáno: (2014)

Extending the SHS combustion concentration limits in Ti + C + Fe powder mixtures by preliminary mechanical activation; Materials Today: Proceedings; Vol. 25, Pt. 3 : III All-Russian Conference (with International Participation) Hot Topics of Solid State Chemistry : From New Ideas to New Materials
Vydáno: (2020)

Structural-Phase Composition of Tic/Ti Composites and Powders Obtained by Combustion of Green Mixtures Ti-C with a Titanium Excess; High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes; Vol. 24, iss. 3
Vydáno: (2020)

Влияние длительности горения разряда на фазовый состав порошкового карбида бора, полученного в атмосферной плазме дугового разряда постоянного тока; Инновационные технологии в машиностроении
Autor: Мартынов Р. С.
Vydáno: (2019)

Production of nitride containing mixture in oxidation of aluminum powder in air; Glass and Ceramics; Vol. 55, iss. 3-4
Vydáno: (1998)

Structure of Ti-TiC cathodes; Mechanical Engineering, Automation and Control Systems (MEACS)
Autor: Krinitcyn M. G.
Vydáno: (2014)

Structure and properties of composite coatings prepared by electron beam melting with “titanium carbide - titanium binder”; Surface and Coatings Technology; Vol. 358
Vydáno: (2019)

Boron carbide B4C ceramics with enhanced physico-mechanical properties sintered from multimodal powder of plasma dynamic synthesis; International Journal of Refractory Metals and Hard Materials; Vol. 78
Vydáno: (2019)

Effect of iron and boron ultrafine powders on combustion of aluminized solid propellants; Combustion and Flame; Vol. 178
Vydáno: (2017)

Mathematical Modeling of Combustion of a Mixture of Ultradisperse Aluminum Powder with Water; Journal of Engineering Physics and Thermophysics; Vol. 89, iss. 2
Autor: Krainov A. Yu.
Vydáno: (2016)

Dependence of the Product's Phase Composition on the Ratio of Precursors in Plasmadynamic Synthesis of Silicon Carbide; Key Engineering Materials; Vol. 769 : High Technology: Research and Applications (HTRA 2017)
Autor: Sivkov A. A. Aleksandr Anatolyevich
Vydáno: (2018)

Hard Metal Waste Recycling by the Atmospheric Direct Current Arc Plasma; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Autor: Kokorina A. I. Aleksandra Ivanovna
Vydáno: (2020)

Structural study of W2B obtained via mechanical alloying of W, B4C, TiC and graphite before and after He ions irradiation; Nuclear Materials and Energy; Vol. 31
Vydáno: (2022)

Applied aspects of nitrogen fixation by superfine powders (SFP) combustion in air phenomenon using; Modern Techniques and Technology (MTT' 2000)
Vydáno: (2000)

Pyrometry of the processes of self-propagating high-temperature synthesis; Bulletin of the Tomsk Polytechnic University; Vol. 311, № 2
Autor: Gumirov M. A.
Vydáno: (2007)

Multistage kinetics of the synthesis of Ti–TxCy composite; Nanoscience and Technology: An International Journal; Vol. 10, iss. 3
Autor: Demidov V. N. Valery Nikolaevich
Vydáno: (2019)

Fabrication of Ti3SiC2-based pastes for screen printing on paper-derived Al2O3 substrates; Ceramics International; Vol. 44, iss. 7
Vydáno: (2018)

Electric Arc Synthesis of Biomorphic Titanium Carbide from Wood Sawdust; Solid Fuel Chemistry; Vol. 56, iss. 3
Vydáno: (2022)

Obtaining Superhard Coatings of Cubic Tungsten Carbide under High-speed Plasma Spraying; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Vydáno: (2020)

Formation of filamentary crystals in intermediate combustion product of aluminium nanopowder and its mixtures with molybdenum and tungsten nanopowders in air; Bulletin of the Tomsk Polytechnic University; Vol. 310, № 2
Autor: Tolbanova L. O. Lyudmila Olegovna
Vydáno: (2007)

Каталитические свойства порошков карбида вольфрама в процессе крекинга тяжелого углеводородного сырья; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 328, № 8
Vydáno: (2017)

Novel Hybrid Printing of Porous TiC/Ti6Al4V Composites; Advanced Engineering Materials; Vol. 21, iss. 8
Vydáno: (2019)

Vacuum-free electric arc synthesis of titanium carbide using plant waste-derived carbon; New Journal of Chemistry; Vol. 47
Vydáno: (2023)

Coupling Model of the Combustion Synthesis of Composite with Reinforcing Inclusions; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Autor: Knyazeva A. G. Anna Georgievna
Vydáno: (2020)

Nitriding of Mechanically Pre-Activated Ferrochromaluminium in the Combustion Mode; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Autor: Reger A. Anton
Vydáno: (2020)

Monitoring of Nanopowder Combustion Ignited by Laser Radiation; Progress in Electromagnetics Research Symposium (PIERS-Toyama)
Vydáno: (2018)

Synchronized Two-Camera Laser Monitor for Studying Combusting Powder Systems; Symmetry; Vol. 14, iss. 4
Autor: Lin Li
Vydáno: (2022)

The influence of ion irradiation on the properties of ceramic silicon carbide; Energy Fluxes and Radiation Effects (EFRE-2016)
Vydáno: (2016)

Characteristics of Temperature Field Distribution during Vacuum-Free Electric Arc Synthesis; Bulletin of the Russian Academy of Sciences: Physics; Vol. 89, Suppl. 2
Vydáno: (2026)

Studies on the thermal stability of nanosized powder of WC1-x-based product prepared by plasma dynamic method, compaction feasibility of the powder and preparation of composite with aluminium; Ceramics International; Vol. 47, iss. 5
Vydáno: (2021)

Energy input effects on the microstructure and mechanical behavior of Ti–Nb alloy additivelymanufactured by electron beam melting; Materials Science and Engineering: A; Vol. 938
Vydáno: (2025)

Electric Arc Synthesis of Titanium Carbide Using Carbon Obtained by the Thermal Conversion of Food Industry Wastes; Solid Fuel Chemistry; Vol. 58, iss. 3
Vydáno: (2024)

Hydrogen sorption by Ni-coated titanium alloy VT1-0; International Journal of Hydrogen Energy; Vol. 42, iss. 22
Vydáno: (2017)

Microstructure, phase composition and hardness of Ti–Au cladding deposited on Ti–6Al–4V substrate by electron beam powder bed fusion method; Vacuum; Vol. 203
Vydáno: (2022)

Investigation of the Morphology of Product Particles Obtained by Plasma Dynamic Method into an Air Atmosphere; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Vydáno: (2020)

Application of fluoride salt systems for obtaining titanium by the method of electrolysis; Bulletin of the Tomsk Polytechnic University; Vol. 311, № 3
Autor: Karelin V. A. Vladimir Aleksandrovich
Vydáno: (2007)

Ч. 2: Металлургия сплавов вольфрама, молибдена, ванадия, титана, щелочноземельных и редкоземельных металлов, ниобия, циркония, алюминия, бора; Металлургия ферросплавов
Vydáno: (2007)

Влияние тепловложения при плазменной порошковой наплавке стали 10Р6М5 на структуру и твердость покрытия. Наплавка одиночного валика (Ч. I); Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 326, № 7
Autor: Хайдарова А. А. Анна Александровна
Vydáno: (2015)

Справочник по электротермическим процессам
Autor: Емлин Б. И. Борис Иванович
Vydáno: (Москва, Металлургия, 1978)

Structure and Mechanical Properties of Coatings Formed by Detonation Spraying of Titanium Powder; AIP Conference Proceedings; Vol. 1909 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures 2017 (AMHS’17)
Vydáno: (2017)