Source: http://viam-works.ru/en/articles?year=2016&num=9
Timestamp: 2019-04-22 06:14:37+00:00

Document:
Klochkov G.G., Klochkova Y.Y., Romanenko V.A.
The research results of deformation temperature influence on structure, mechanical and corrosion properties of extruded products of Al–Mg–Si alloy V-1341 additionally doped with small additions of Ca made in industrial-scale production of JSC «KUMW» metallurgical plant are presented. Extrusion is maintained at low (300–350°C) and high (450–500°C) temperatures. Corrosion resistance (intergranular corrosion and layer corrosion) of extruded products is investigated. Comparison of mechanical properties after thermal processing in laboratory and metallurgical workshop conditions is also given.
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Kashapov O.S., Pavlova T.V., Kalashnikov V.S., Kondrateva A.R.
The study of influence of alloying elements content (aluminum, tin, silicon and iron) in the near alpha titanium alloy VТ46 in room and elevated temperatures (500 and 550°С) is performed. It is found that reducing the content of elements such as aluminum, tin, silicon comparing with a nominal composition leads to decrease in creep strength characteristics of the material. Content of iron has a significant effect only on the level of strength in relatively low test temperatures.
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Zaysev D.V., Sbitneva S.V., Ber L.B., Zavodov A.V.
The chemical composition of γ, γ` and carbide particles in disc blanks from granulated nickel superalloy EP741NP is defined. Investigation of the phase’s chemical composition is performed using X-ray spectral microanalysis having locality 1,5 nm in transmission electron microscope. The γ`-phases particles have an increased content of Ni, Al, Ti, Nb and a lower concentration of Cr, Co, Mo and W than the matrix γ-layer. Particles of carbides contain high boron concentration besides of high carbon content thus theу are the carboborides. It is shown that the carboborides can be divided into two types depending on stoichiometric composition. The larger 0,3–1 micron sized particles are Me(B, C) phase where Me is Ti, Nb, Hf. and the smaller 80–200 nm sized particles corresponds to Ме23(В, С)6 or Ме3(В, С)2, where Ме is Cr, Mo, W. The identification of Me(B, C) particles is carried out using diffraction methods. The work is executed within implementation of integrated scientific direction 2.
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The article presents a study on the development of methods for the quantification of the surface morphology and structural defects in superalloy synthesized by the method of selective laser melting (SLM). The results of studies on the proposed methods for the quantitative metallographic analysis of samples of superalloys ZHS6K-VI and EP648-VI, obtained at different technological parameters of SLM.
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