RU2635650C1 - Method of thermomechanical processing of high-alloyed pseudo- (titanium alloys alloyed by rare and rare-earth metals - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: method comprises manufacture of a sheet semifinished product and thermomechanical processing thereof by multiple heatings and deformations. Thermomechanical processing of sheet semifinished products is carried out in seven stages. The first stage includes an all-around forging on a slab in at least two sets with a total deformation degree of not less than 40±10% at each one, lowering of forging temperature and intermediate heatings in the temperature range from T_ih+180 to T_ih+490°C. The second stage comprises heating the slab to a temperature (T_ih+250÷T_ih+420)°C, deformation by hot rolling with a total deformation degree of not less than 80±10% and intermediate heatings. The third stage comprises heating to a temperature (T_ih+30÷T_ih+70)°C, deformation of the intermediate hot-rolled semifinished rolled products by hot rolling with a total deformation degree of at least 40±10% and intermediate heatings. The fourth stage comprises further deformation of the semifinished rolled products into one or more stages by heating to a temperature (T_ih+90÷T_ih+130)°C and hot rolling with a total deformation degree from 40 to 70±10% and intermediate heatings. The fifth stage comprises heat treatment of sheet semifinished products at a temperature (T_ih+10÷T_ih+50)°C for 0.3-1.5 hours in a chamber resistance furnace and subsequent water or air hardening to obtain β-structure. The sixth stage comprises cold rolling of sheets with a total deformation degree from 20 to 60±10%. The seventh stage comprises straightening at a temperature (T_ih-20÷T_ih-90)°C with subsequent surface treatment.

EFFECT: increasing degree of structure elaboration by increasing the limiting deformation degrees during hot and cold processing with pressure, increasing technological plasticity while maintaining strength and plasticity after hardening heat treatment, decreasing the minimum relative bend radius in the quenched state.

3 cl, 2 tbl

Description

The invention relates to the field of non-ferrous metallurgy, in particular to the thermomechanical processing of highly alloyed pseudo-β titanium alloys and products from them, and can be used in aircraft.

The prior art method of thermomechanical processing disclosed in patent RU 2487962 (publ. 09/23/2011, C22F 1/18, B21B 3/00), including:

- heating of the initial billet to a temperature (TPP + 120 ÷ TPP + 200) ° C, deformation with a total degree of 40 ÷ 80%;

- heating to temperature (TPP + 60 ÷ TPP + 80) ° C, rolling with a total degree of deformation of 50 ÷ 80%;

- heating to a temperature of (TPP-20 ÷ TPP-40) ° C, rolling with a total degree of deformation of 40 ÷ 70%;

- assembly of sheet blanks into a bag, heating to a temperature of (T _pp -20 ÷ Tpp-120) ° C, rolling with a total degree of deformation of 50 ÷ 85%. The disadvantage of this method is the increased complexity and complexity of manufacturing thin sheets due to the need for "batch rolling", a low level of technological plasticity (stampability), due to the insufficient degree of elaboration of the structure.

A known method of thermomechanical processing disclosed in patent RU 2549804 (publ. 09/26/2013, B21B 3/00, C22C 14/00), including the deformation of the ingot into a slab, rolling the slab on a tackle. Multi-stage rolling of billets is carried out by: heating in the β-region, at least 50 ° C above T _pp and subsequent rolling, then in the (α + β) region after heating to a temperature not higher than TPP-20 ° C, then in β -regions at least 50 ° C higher than T _pp , then in the (α + β) -region after heating to a temperature not higher than T _pp -20 ° C with a degree of deformation of up to 50%.

The disadvantage of this method is the low level of technological plasticity (stampability) of the obtained semi-finished products, due to the insufficient degree of deformation processing of the product at low temperatures and cold.

The closest analogue of the claimed invention is a method for manufacturing deformed products from pseudo-β titanium alloys, including: heating the initial ingot to a temperature (T _pp +150 ÷ T _pp +380) ° C, deformation with a total degree of 40 ÷ 70%; heating to temperature (T _pp +60 ÷ T _pp +220) ° C, deformation with a total degree of 30 ÷ 60%; heating to temperature (T _pp -20 ÷ T _pp -60) ° C, deformation with a total degree of 30 ÷ 60%; recrystallization treatment by heating the workpiece to a temperature (T _pp +70 ÷ T _pp +140) ° C and subsequent deformation with a total degree of 20 ÷ 60%; heating to a temperature (T _pp -20 ÷ T _pp -60) ° C, deformation with a total degree of 30 ÷ 70%; recrystallization treatment by heating the workpiece to a temperature of (T _pp +30 ÷ T _pp +110) ° C and subsequent deformation with a total degree of 15 ÷ 50%; heating to a temperature (T _pp -20 ÷ T _pp -60) ° C, deformation with a total degree of 50 ÷ 90% (RU 2441097, 01.27.2012, C22F 1/18).

The disadvantages of this method are the low level of technological plasticity (stampability), due to the insufficient degree of elaboration of the structure, and the high labor and energy consumption of manufacturing complex products.

The technical task of the claimed invention is to simplify the manufacturing process of manufacturing complex products (parts) from sheets of highly alloyed pseudo-β titanium alloys, including alloyed with rare (RM) and / or rare earth (REM) metals.

The technical result of the proposed invention is to increase the degree of development of the structure by increasing the ultimate degrees of deformation during hot and cold processing, increasing the characteristics of technological plasticity (stampability) of sheet semi-finished products while maintaining strength and ductility after hardening heat treatment at a high level and, as a result, a decrease in hardened state of the minimum relative radius of bending when bending at an angle of 90 ° at a temperature of 20 ° C.

To achieve the claimed technical result, a method for manufacturing sheet semi-finished products from pseudo-β titanium alloys is proposed, including the manufacture of a sheet semi-finished product and its thermomechanical treatment by repeated heating and deformation, which consists in the fact that the thermomechanical processing of sheet semi-finished products is carried out in seven stages. The first stage includes comprehensive forging on a slab in at least two approaches with a total degree of deformation on each of at least 40 ± 10%, a decrease in the temperature of forging and intermediate heating in the temperature range from T _pp +180 to T _pp + 490 ° C. The second stage includes heating the slab to a temperature of (T _pp + 250 ÷ T _pp +420) ° C, deformation by hot rolling with a total degree of deformation of at least 80 ± 10% and intermediate heatings. The third stage includes heating to a temperature of (T _pp + 30 ÷ T _pp +70) ° C, deformation of the intermediate hot-rolled tin by hot rolling with a total degree of deformation of at least 40 ± 10% and intermediate heatings. The fourth stage includes the further deformation of the tackle in one or more stages by heating to a temperature (T _pp + 90 ÷ T _pp +130) ° C and hot rolling with a total degree of deformation from 40 to 70 ± 10% and intermediate heating. The fifth stage includes the heat treatment of sheet semi-finished products at a temperature of (T _pp + 10 ÷ T _pp +50) ° C for 0.3-1.5 hours in a resistance chamber furnace and subsequent quenching in water or in air to obtain a β-structure, further sandblasting or waterjet treatment and surface etching. The sixth stage involves the deformation of sheet semi-finished products processed into β-structures by cold rolling with a total degree of deformation from 20 to 60 ± 10%. The seventh stage includes sweeping at a temperature of (T _pp -20 ÷ T _pp -90) ° C, followed by surface treatment.

Subsequent surface treatment in order to remove gas-saturated layers can be carried out by sandblasting and / or waterjet cleaning and etching and finishing grinding to the required thickness and tolerances for thickness variation.

Intermediate heating is carried out if necessary to prevent the formation of cracks, delaminations and other surface defects on the semi-finished product. The feasibility and frequency of the intermediate heating depends on the specific production conditions.

At the fifth stage, subsequent quenching in water or in air to fix a single-phase (predominantly) β-structure is necessary, since it is such a structure that has high ductility, which allows the shaping of sheet blanks (for example, by cold rolling) with the largest single and total degrees of deformation. The presence of α-phase particles in the alloy structure (formed during heat treatment under conditions not corresponding to those specified in the claimed invention) significantly increases the deformation forces of semi-finished products and reduces the permissible degrees of their deformation.

At the sixth stage, the deformation of sheet semi-finished products processed into β-structures (mainly) is included, since deformation by cold rolling provides favorable parameters of the structure and substructure, which allows to increase the complex of mechanical properties of the final product after hardening heat treatment. Also, cold rolling helps to reduce the size of the grains of the alloy in the hardened state.

At the seventh stage, laying at a temperature of (T _pp -20 ÷ T _pp -90) ° C and subsequent processing (by sandblasting and / or waterjet cleaning, grinding and etching) is carried out, if necessary, depending on the specific requirements for surface quality and flatness of sheets . In particular, to ensure improved flatness of large sheets (for example, t × 800 × 2000 mm) after cold rolling, it is necessary to lay, surface treat by sandblasting and subsequent etching. To ensure reduced variation in the actual thickness of the sheets and their thickness difference, additional grinding is necessary.

To reduce the number of technological operations and reduce the risk of hydrogenation of sheet semi-finished products during etching, the preparation of the structural-phase composition can be carried out by treatment in a vacuum or argon-vacuum furnace, in which the charge is cooled by means of natural cooling with a furnace or forced cooling in an inert gas medium, provided that the cooling rate V _OHL cages to 550 ° C is at least 8 ° C / min from 550 to 300 ° C - at least 4 ° C / min, and the gas-removal layers by ne kostruynoy treatment or surface etching is carried out before heat treatment.

Argon can be used as an inert gas, and sandblasting and pickling operations are not required before heat treatment of cold-rolled sheet semi-finished products.

The manufacture of sheet semi-finished products by the proposed technology is preferably carried out from high-strength pseudo-β titanium alloy containing PM and / or REM, grade BT47 or its modifications (containing, wt.%: Aluminum from 1.5 to 3.7; molybdenum from 1.0 up to 3.1; vanadium from 8.0 to 12.0; chrome from 2.5 to 5.0; iron from 0.1 to 1.8; zirconium from 0.4 to 2.0; tin from 0.4 up to 2.2 and one or more of the following elements: ruthenium, yttrium, gadolinium in an amount of from 0.01 to 0.16, for example, according to patent RU 2569285, 11.20.2015, C22C 14/00.

The manufacture of complex products (parts) from sheets of pseudo-β titanium alloys can be carried out by cold forming: sheet stamping, pneumatic molding, extrusion, hydrostatic pressing, gas-static pressing, embossing, profiling on a roll bending machine, deep drawing, firmware, rotary extrusion , bending with stretching, bending under the press and cold heading.

In the process of deformation after the first three heatings at a temperature above the polymorphic transformation (β-region), alternating precipitation and drawing, a more isotropic structure is created compared to the initial structure of the ingot, the initial crystals are crushed and spheroidized during dynamic recrystallization, the chemical composition is averaged, reduction of intradentritic gradients in the content of alloying elements and the elimination of foundry origin. With subsequent heating and deformation, a moderately fine-grained microstructure is prepared, devoid of defects of deformation origin (banding, sunsets, shackles, internal and external cracks). The use of operations to homogenize the structure by recrystallization in the β region together with quenching in a wide range of cooling rates makes it possible to obtain a homogeneous homogeneous structural phase state. Such a structural phase state obtained in semi-finished semi-finished products provides high characteristics of their technological plasticity (stampability) in the hardened state and strength values in the thermally hardened state. The preparation of the structural phase state and cold rolling, carried out at the fifth and sixth stages of the technological process, the total degree of deformation at which can reach 70%, have the greatest influence on obtaining a high complex of technological and mechanical characteristics. The use of intensive deformation during cold rolling can significantly increase the density of dislocations, vacancies, and other defects of the crystal lattice, which allows subsequent structural processing to more effectively grind structural phase components and increase the level of technological plasticity in the hardened state and mechanical properties after aging.

Semi-finished sheet products manufactured according to the above technological process are well processed by pressure at room temperature by sheet stamping, bending, drawing, extrusion, etc. According to the level of technological plasticity in the hardened state (including in vacuum furnaces), pseudo-β titanium sheets alloy containing RM and / or REM, practically not inferior to the characteristics of high-tech alloys VT1-0 and OT4-1. This allows us to produce various complex products (parts) that are comparable in complexity to products made of VT1-0 and OT4-1 alloys made under similar conditions by cold forming methods (without heating parts and rigging and intermediate annealing).

Examples of implementation

Sheets were made from an alloy containing, by weight. %: 1.5 ÷ 3.7 aluminum, 1.0 ÷ 3.1 molybdenum, 8.0 ÷ 12.0 vanadium, 2.5 ÷ 5.0 chromium, 0.1 ÷ 1.8 iron, 0.4 ÷ 2.0 zirconium, 0.4 ÷ 2.2 tin, one or more of the following elements: 0.01 ÷ 0.16 ruthenium, 0.01 ÷ 0.16 yttrium, 0.01 ÷ 0.16 gadolinium, and alloy -prototype of the proposed method of thermomechanical processing and prototype method. Then, the sheets were subjected to heat treatment (quenching for the β phase or hardening heat treatment) and studies of their mechanical properties and manufacturability were carried out.

Example 1

1st stage. Comprehensive forging in 2 sets with a total degree of deformation at each 80%, at installation temperatures TPP + 490 and TPP + 380 ° С. Workpiece cooling in air;

2 stage. Heating the slab to a temperature of (T _pp +250) ° C, deformation by hot rolling with a total degree of deformation of 70% (4 intermediate heating at a temperature of (T _pp +320) ° C);

3 stage. Heating of hot-rolled steel to a temperature of (T _pp +30) ° C, deformation by hot rolling with a total degree of deformation of 60% (3 intermediate heating at a temperature of (T _pp +30) ° C);

4 stage. Heating of hot-rolled steel to a temperature of (T _pp +130) ° C, deformation by hot rolling in 2 stages with a total degree of deformation of 50% (1 intermediate heating was carried out at a temperature of (T _pp +130) ° C);

5 stage. Preparation of the structural phase state and surface of intermediate sheet semi-finished products by heat treatment at a temperature of (T _pp +50) ° C for 0.3 hours in a resistance chamber furnace, subsequent quenching in water and removal of gas-saturated layers by sandblasting and etching of the surface;

6th stage. Deformation of semi-finished sheet products by cold rolling with a total degree of deformation of 10%;

7th stage. Ironing at a temperature of (T _PP -20) ° С and removal of gas-saturated layers by hydroabrasive surface treatment, grinding and etching.

Example 2

1st stage. Comprehensive forging in 4 sets with a total degree of deformation on each from 30 to 70%, at installation temperatures T _pp +470, T _pp +350, T _pp +250 and T _pp + 180 ° C. Workpiece cooling in air;

2 stage. Heating the slab to a temperature of (T _pp +350) ° C, deformation by hot rolling with a total degree of deformation of 85% (4 intermediate heatings were carried out at a temperature of (T _pp +350) ° C);

3 stage. Heating of hot-rolled steel to a temperature of (T _pp +70) ° C, deformation by hot rolling with a total degree of deformation of 30% (1 intermediate heating was carried out at a temperature of (T _pp +70) ° C);

4 stage. Heating of hot-rolled steel to a temperature of (T _PP +90) ° C, deformation by hot rolling in 1 stage with a total degree of deformation of 30% (without intermediate heatings);

5 stage. Preparation of the structural phase state and the surface of intermediate sheet semi-finished products by removing gas-saturated layers by sandblasting and etching the surface. Subsequent heat treatment at a temperature of (T _pp +10) ° C for 1.5 hours in a vacuum resistance furnace, cooling the billets with the furnace;

6th stage. Deformation of semi-finished sheet products by cold rolling with a total degree of deformation of 70%;

7th stage. Progladka temperature _(BTT -90) ° C and a gas-removal layers by blasting surface treatment, grinding and etching.

Example 3

1st stage. Comprehensive forging in 3 sets with a total degree of deformation on each from 40 to 70%, at installation temperatures T _pp +470, T _pp +340 and T _pp + 220 ° C. Workpiece cooling in air;

2 stage. Heating the slab to a temperature of (T _pp +420) ° C, deformation by hot rolling with a total degree of deformation of 80% (3 intermediate heating at a temperature of (T _pp +420) ° C);

3 stage. Heating of hot-rolled steel to a temperature of (T _pp +45) ° C, deformation by hot rolling with a total degree of deformation of 50% (2 intermediate heating at a temperature of (T _pp +45) ° C);

4 stage. Heating of hot-rolled steel to a temperature of (T _PP +115) ° С, deformation by hot rolling for 1 stage with a total degree of deformation of 61% (1 intermediate heating was carried out at a temperature of (T _PP +115) ° С);

5 stage. Preparation of the structural phase state and the surface of intermediate sheet semi-finished products by removing gas-saturated layers by sandblasting and etching the surface. Subsequent heat treatment at a temperature of (T _PP +20) ° C for 1.0 hour in a vacuum resistance furnace, cooling the workpieces in an argon atmosphere;

6th stage. Deformation of semi-finished sheet products by cold rolling with a total degree of deformation of 30%;

7th stage. Preparation of the structural phase state and final deformation by cold rolling with a total degree of deformation of 25%.

Table 1 shows the chemical composition of the manufactured sheets.

Next, the following characteristics of the obtained semi-finished products were determined:

- the tensile strength and elongation of the samples at a temperature of 20 ° C were determined by conducting tensile tests in accordance with GOST 1497;

- the minimum relative radius of bending when bending at an angle of 90 ° at a temperature of 20 ° C was determined in accordance with GOST 14019-2003.

Table 2 shows the results of determining the mechanical properties and manufacturability (minimum relative bending radius).

The proposed method for thermomechanical processing of high-alloyed pseudo-β titanium alloys, in particular, the Ti-Al-Mo-V-Cr-Fe-Sn-Zr alloying system doped with RM and / or REM, allows to increase the degree of structure development by increasing the ultimate degrees of deformation during hot and cold processing, it is regulated to reduce the size and ensure uniformity of the structural phase components in the semi-finished product, due to which to increase the characteristics of technological plasticity (stampability) while maintaining a high level of durable other properties.

As can be seen from table 2, in semi-finished products manufactured by the proposed method, the minimum relative radius of bending when bent at an angle of 90 ° at a temperature of 20 ° C in a hardened (annealed) state increased by 13-19%, the tensile strength at 20 ° C in thermally hardened (aged) state and the characteristics of elongation remained the same high.

Claims (3)

1. A method of manufacturing a sheet of semi-finished products from pseudo-β titanium alloys, including the manufacture of a sheet of semi-finished product and its thermomechanical processing by repeated heating and deformation, characterized in that the thermomechanical processing of sheet semi-finished products is carried out in seven stages, while the first stage includes comprehensive forging on a slab for no less than two approaches with a total degree of deformation on each of at least 40 ± 10%, a decrease in the temperature of forging and intermediate heatings in the temperature range from T _pp +180 to T _pp + 490 ° C, the second stage includes heating the slab to a temperature of (T _pp + 250 ÷ T _pp +420) ° C, deformation by hot rolling with a total degree of deformation of at least 80 ± 10% and intermediate heating, the third stage includes heating to a temperature (T _pp + 30 ÷ T _pp +70) ° C, deformation of the intermediate hot-rolled tin by hot rolling with a total degree of deformation of at least 40 ± 10% and intermediate heatings, the fourth stage includes further deformation of the tack in one or more stages by heating to a temperature _(BTT + 90 ÷ _BTT +130) ° C and hot proc ki with a total degree of deformation from 40 to 70 ± 10% and the intermediate heating, the fifth step comprises heat treating the semi-finished sheet at a temperature _(BTT + 10 ÷ T _claims +50) ° C for 0.3-1.5 hours in a chamber resistance furnaces and subsequent quenching in water or air to obtain a β-structure, the sixth stage includes cold rolling of sheets with a total degree of deformation from 20 to 60 ± 10%, and the seventh stage includes laying at a temperature (T _pp -20 ÷ T _pp - 90) ° С followed by surface treatment. 2. The method according to p. 1, characterized in that before the heat treatment in the fifth stage carry out sandblasting or waterjet and etching the surface of the sheets. 3. The method according to p. 1, characterized in that the manufacture of products from pseudo-β titanium alloy containing, by weight. %: aluminum 1.5 ÷ 3.7, molybdenum 1.0 ÷ 3.1, vanadium 8.0 ÷ 12.0, chromium 2.5 ÷ 5.0, iron 0.1 ÷ 4.8, zirconium 0, 4 ÷ 2.0, tin 0.4 ÷ 2.2, one or more of the elements, including ruthenium, yttrium and gadolinium, 0.01 ÷ 0.16.