Composition, Structure and Properties of Hard-Alloy Powders Obtained by Electrodispersion of T5k10 Alloy in Water

Агеев, Е. В.; Ageeva, A. E.

doi:10.52351/00260827_2022_02_39

Cited by 6 publications

(5 citation statements)

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“…Достоинства латуни способствуют стабильному планомерному росту потребления ее во всех отраслях промышленности. Этот металл востребован практически везде -от производства дверных ручек и часовых шестерёнок до изготовления самых сложных теплообменников в энергетике [1][2][3][4].…”

Section: Introductionunclassified

“…В настоящее время промышленность сталкивается с проблемой переработки отходов медных сплавов и повторным их использованием. В качестве одного из перспективных, но недостаточно изученных способов переработки металлоотходов в пригодные для повторного применения порошки является измельчение с помощью электроэрозии [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20]. Однако в промышленности данный способ переработки практически не применяется, поскольку в технической литературе отсутствуют полноценные сведения о составе, структуре и свойствах получаемых таким образом порошков.…”

Section: Introductionunclassified

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Structure and Properties of Electroerosion Powders Obtained from LS58-3 Brass Waste in Isopropyl Alcohol

Ageeva,

Serebrovsky,

Pereverzev

et al. 2023

jour

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Purpose of research. Study of the structure and properties of powders obtained by electroerosion of the LS58-3 alloy in a carbon-containing medium - isopropyl alcohol.Methods. The process of electrical erosion of LS58-3 alloy waste was carried out on a patented installation, LS58-3 alloy waste was used as metal waste. Isopropyl alcohol, which is a carbon-containing medium, was chosen as the working fluid.Studies of the morphology and granulometric composition of the obtained particles were carried out on an electron-ion scanning microscope "Quanta 600 FEG" and a laser particle size analyzer Analysette 22 NanoTec", respectively.X-ray spectral microanalysis of powders was carried out on an energy-dispersive X-ray analyzer from EDAX (Netherlands) built into a scanning electron microscope QUANTA 200 3D (Netherlands). The phase analysis of the powders was performed on a Rigaku Ultima IV X-ray diffractometer (Japan).Results. An analysis of the morphology of the obtained powders showed that the particles are mainly spherical and elliptical in shape, as well as agglomerates.Analysis of the particle size distribution of the powder obtained using the Analysette 22 NanoTec particle size analyzer showed that the average particle size is 24 µm. This particle size was obtained in the operating mode of the installation, in which the electroerosion process proceeds stably.Analysis of the elemental composition has established that free carbon is contained on the surface of the powder particles. The remaining chemical elements Cu, Zn, Pb, Sn are distributed relatively evenly. The presence of free carbon is due to the chemical composition of the dispersion medium, which is carbon-containing.X-ray diffraction analysis of the obtained powders showed the presence of Cu3Zn, Pb, ZnO, CuO2, SnO2 phases. There are no carbide-forming elements in the composition of the alloy.It has been experimentally established that the composition, structure and properties of the charge of LS58-3 brass dispersed by electroerosion are affected by the chemical composition of the working fluid, as well as the dispersion modes.Conclusion. On the basis of the conducted experimental studies, it can be concluded that the use of electroerosive dispersion technology for the processing of LS58-3 brass waste and the production of powders based on it is relevant. It is noted that the particles of the resulting charge have a given set of properties and can be used by various methods of powder metallurgy.

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Section: Introductionunclassified

Structure and Properties of Electroerosion Powders Obtained from LS58-3 Brass Waste in Isopropyl Alcohol

Ageeva,

Serebrovsky,

Pereverzev

et al. 2023

jour

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“…Industrial methods for producing powders from hard alloy waste have a number of disadvantages: large capacity, energy intensity, large production areas, environmental problems. One of the most progressive methods of obtaining powder from hard alloy waste, characterized by relatively low energy costs and environmental cleanliness of the process, is the method of electroerosion dispersion (EED) [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

“…The possibility of using powders obtained by EED from sintered hard alloy waste as a dispersed phase in the application of CGC is due to the following properties: spherical or elliptical shape of the particles; aggregate stability in the suspension state; high microhardness, dispersion, wettability, sorption capacity; the ability to introduce powders into the electrolyte without additional purification; the ability to obtain powders directly in the galvanic bath and combine the EED process with the electrodeposition [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

The Use of Hard Alloy Waste in Composite Galvanic Coatings for the Restoration of Car Parts

Семенихин

Kuznetsova

Kozlikin

2020

SSP

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The results of the research of the use of powders based on tungsten carbide with a particle size of 1 μm or less, obtained by the method of electro-erosion dispersion from the waste of sintered hard alloys, as a dispersed phase of composite galvanic coatings based on iron during the restoration and hardening of car parts are presented. It is shown that the introduction powders of hard alloys of grades VK8 and T15K6 in the chloride electrolyte of iron plating with a concentration of 100 g/l and more, practically does not affect the micro-hardness, but allows to increase the relative wear resistance of the obtained composite galvanic coatings, compared to simple iron galvanic coatings, and, at the same time, increase the life of parts and reduce repair costs.

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“…One of the effective, but insufficiently studied metallurgical methods of obtaining alloy powders by grinding metal waste is electrodispersion [14][15][16][17]. At present, this method is practically not used in industry, due to the lack of complex and comprehensive data on the composition, structure and properties of particles dispersed by electric erosion.…”

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confidence: 99%

Composition, structure and properties of hard alloy products from electroerosive powders obtained from T5K10 hard alloy waste in kerosene

Ageev¹,

Ageeva²

2022

nfm

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Composition, Structure and Properties of Hard-Alloy Powders Obtained by Electrodispersion of T5k10 Alloy in Water

Cited by 6 publications

References 0 publications

Structure and Properties of Electroerosion Powders Obtained from LS58-3 Brass Waste in Isopropyl Alcohol

Structure and Properties of Electroerosion Powders Obtained from LS58-3 Brass Waste in Isopropyl Alcohol

The Use of Hard Alloy Waste in Composite Galvanic Coatings for the Restoration of Car Parts

Composition, structure and properties of hard alloy products from electroerosive powders obtained from T5K10 hard alloy waste in kerosene

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