V. N. Moiseev scite author profile

V. N. Moiseev

5Publications

32Citation Statements Received

3Citation Statements Given

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Volgograd State University, All Russian Scientific Research Institute of Aviation Materials, Moscow State Aviation Technological University

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Coefficient of β-stabilization of titanium alloys

Antipov

Moiseev

1997

Met Sci Heat Treat

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The coefficient of[3-stabilization KI3 was introduced in Russia for titanium alloys in the seventies. It makes it possible to determine the class of the alloy from its chemical composition and evaluate approximately the mechanical properties. The present paper concerns the effect of various elements and the cooling rate in quenching on KI3. The limits of application of the coefficient of 13-stabilization are determined.The coefficient of 13-stabilization [ 1 ] is determined by the formulawhere c i is the concentration of the 13-stabilizing element in the alloy and cc'ri is its critical concentration.The coefficient of [3-stabilization is arbitrary and is based on unproved assumptions but characterizes the class of the alloy rather accurately. Proceeding from this coefficient, all titanium alloys can be arranged in a sequence in accordance with the stability of the 13-phase. The coefficient KI3 is useful both for metal-science students studying titanium alloys and fbr specialists in the field. The coefficient is very convenient in working with publications concerning newly created alloys.The coefficient of [3-stabilization does not take into account the aluminum present in almost every titanium alloy, the neutral strengthners such as tin and zirconium often contained in the alloys, and the impurities. We will show how this is justified below. Formula (1) for determining the coefficient of ]3-stabilization involves the critical concentration c'c' r, i.e., the minimum possible concentration of [3-stabilizer at which a binary titanium alloy quenched from the single-phase 13-region in water no longer contains martensite (Fig. 1) [2].We begin our consideration with the cooling rate in quenching. In the majority of works devoted to the critical concentration the alloys are subjected to quenching in water at a high cooling rate. This method is convenient technologiAll-Russia Institute of Aircraft Materials, Moscow, Russia.cally, and the cooling rates are close to those used in industry. However, it should be noted that the actual cooling rates in various works differ due to the differences in the size of the specimens and the test conditions. However, the effect of the quenching conditions on the value of c'c' r begins to manifest itself only at very high cooling rates. In [3] the effect of the cooling rate on C'c' r of Ti -Mo alloys has been studied in different quenching media, namely, room-temperature water, water with ice, and liquid nitrogen. After quenching at different rates co' r did not change. The effect of the cooling rate, varied in a wide range, on decomposition of the [3-phase in Ti -Nb alloys with formation of martensite has been studied in [4]. As the cooling rate ofa Ti-17.5 at.% Nb alloy was increased from 0.1 to 1000 K/sec the temperature of the martensite transformation decreased from 350 to about 280~ At a quenching rate of 3000 K/sec the martensite transformation did not begin and the alloy hardened to "pure" 13-phase. 499

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High-strength titanium alloys for large parts of aircraft engines

Moiseev

2000

Met Sci Heat Treat

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Titanium in Russia

Moiseev

2005

Met Sci Heat Treat

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Untitled

Moiseev¹

2001

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Effect of additional carbon and boron alloying on the structure and mechanical properties of alloy VT22

Moiseev¹,

Sysoeva²,

Polyakova³

1998

Met Sci Heat Treat

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The creation of high-strength heat-resistant alloys based on titanium is of great scientific interest. Doublephase titanium (at + 13) alloys are widely used at present. The alloying sets for these alloys are mainly developed with the purpose of increasing their strength and heat resistance by solution strengthening of the phases with substitutional elements. However, the increasing strictness of the requirements on the level of their mechanical properties makes it necessary to create titanium alloys that can be strengthened by the segregation of an intermetallic phase or chemical compounds. An important problem in the development of such alloys is the choice of the optimum composition and the attainment of the requisite dispersity and uniformity of distribution of segregations of strengthening phases in the structure. In this connection, carbon and boron, poorly soluble in titanium and forming independent carbide and boride segregations, are of some interest as alloying additives to these alloys.

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V. N. Moiseev

Coefficient of β-stabilization of titanium alloys

High-strength titanium alloys for large parts of aircraft engines

Titanium in Russia

Untitled

Effect of additional carbon and boron alloying on the structure and mechanical properties of alloy VT22

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