Influence of Ti and TiH2 Additives on the Structure and Properties of Copper Alloys for Diamond Cutting Tools
Autor: | D. A. Sidorenko, A. Okubayev, Pavel Loginov, E. A. Levashov, N.V. Shvyndina, Stepan Vorotilo, Yu. V. Lopatina |
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Rok vydání: | 2020 |
Předmět: |
010302 applied physics
Materials science Metallurgy Metals and Alloys Titanium hydride chemistry.chemical_element 02 engineering and technology Tribology 01 natural sciences Copper 020501 mining & metallurgy Surfaces Coatings and Films Diamond cutting chemistry.chemical_compound 0205 materials engineering chemistry Mechanics of Materials 0103 physical sciences Ultimate tensile strength Hardening (metallurgy) Titanium Solid solution |
Zdroj: | Russian Journal of Non-Ferrous Metals. 61:429-435 |
ISSN: | 1934-970X 1067-8212 |
DOI: | 10.3103/s1067821220040069 |
Popis: | The influence of titanium and titanium hydride additives on the structure, mechanical properties, and wear resistance of copper alloys intended for use as a binder of the diamond cutting tool is investigated. Powder mixtures Cu–Ti and Cu–TiH2 are fabricated by mechanical alloying in a planetary centrifugal mill. Such treatment makes it possible to form single-phased powders of the copper-based solid solution in the Cu–Ti system and two-phased powders based on copper with uniformly distributed TiH2 particles in the Cu–TiH2 system. It is established that the maximal mechanical properties are characteristic of the samples of compositions Cu–2.5% Ti and Cu–10% TiH2 (higher than for pure copper by a factor of 2.0–3.5). Hardening in such alloys is implemented according to the solid-solution mechanism and due to the formation of the Cu3Ti3O phase. Grains of this phase have higher dispersity in alloys where TiH2 is used as the titanium-containing additive, due to which high values of the bending ultimate strength (920 MPa) and hardness (114 HB) are attained. It is established according to the results of comparative tribological investigations that samples of the Cu–10% TiH2 composition possess the best wear resistance. The reduced wear of these samples after the test according to the “rod–disc” scheme is an order of magnitude lower than for pure copper and lower by a factor of 5 than for Cu–2.5% Ti samples. |
Databáze: | OpenAIRE |
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