RU2378410C1 - Manufacturing method of plates from duplex titanium alloys - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: manufacturing method of plates from duplex titanium alloys includes hot working of ingot into slab, hot rolling and following thermal treatment of plates. Hot working is implemented by forging of ingot into three stages. At the first stage forging is implemented at a degree of deformation 40÷60% after heating up to temperature for 220÷280°C higher than temperature of polymorphic transformation Tpt, at the second - at a degree of deformation 30÷50% after heating for 80÷220°C higher than Tpt, at the third - at a degree of deformation 30÷40% after heating up to temperature for 20÷60°C lower than Tpt. The first hot rolling is implemented at a degree of deformation 30÷90% after heating of slab up to temperature for 80÷120°C higher than Tpt and cooling up to room temperature. The second hot rolling is implemented in two stages. At the first stage breakdown is heated up to temperature 20÷50°C lower than Tpt and is rolled at a degree of deformation 23÷35% with following cooling up to room temperature, at the second - it is implemented final deformation up at a degree of deformation 23÷35% after heating of breakdown up to temperature for 30÷50°C lower than Tpt. Cooling of the received plate is implemented after final deformation up to room temperature in the mode of nutation at roller conveyer.

EFFECT: there is increased level of mechanical properties of plates and there are improved quality ratings of macro- and microstructure.

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Description

The invention relates to the processing of metals by pressure, in particular to thermomechanical processing of two-phase titanium alloys.

It is known that the structure and its homogeneity have a decisive influence on the level and stability of the mechanical properties of thick sheets and plates. Therefore, when developing the technological process of plate manufacturing, it is critical to select the conditions for the formation of the structure during the hot deformation of titanium alloys.

A known method of manufacturing plates from α- and (α + β) -titanium alloys, which consists in combining hot and warm rolling from one heating of the slab by cooling and subsequent deformation according to the mode of warm rolling (Bulletin of VILS "Technology of light alloys.” No. 12, 1975 , p. 50-51).

However, cold rolling has significant drawbacks, as there is no possibility of monitoring the temperature of the metal during cooling and there is a temperature gradient across the plate thickness due to low thermal conductivity.

A well-known standard scheme of the technology for the production of hot-rolled plates, including heating the slab, hot rolling, cutting to length, annealing and finishing operations (Titanium alloys. Semi-finished products from titanium alloys. Corresponding editors: NF Anoshkin, MZ Ermanok, M ., ONTI WILS, 1996, p.207-210).

The disadvantage of a typical scheme for manufacturing hot-rolled plates is the instability and anisotropy of the mechanical properties, as well as the heterogeneity of the metal structure.

The prototype selected a method of manufacturing hot-rolled plates from titanium alloys, including two heating with cooling the metal to room temperature, subsequent heating of the strip at a temperature of the (α + β) region and rolling the metal to the required dimensions with compression of at least 40% (VILS Bulletin "Light technology alloys. "No. 12, 1975, S. 52, 53).

Such technology has made it possible to improve the microstructure of plates and increase the level of such indicators of mechanical properties as elongation and contraction. The main disadvantage of the prototype is that the manufacture of hot-rolled plates from titanium alloys by this method does not allow to obtain a homogeneous metal structure and, accordingly, does not provide the necessary level of mechanical properties.

The problem to which the invention is directed is the development of a method for manufacturing plates from two-phase titanium alloys, which allows for an increased level of mechanical properties and uniformity of macro- and microstructure.

The technical result achieved by the implementation of the invention is to increase the level of mechanical properties and improve the quality indicators of macro- and microstructure.

The specified technical result is achieved by the fact that in the method of manufacturing plates from two-phase titanium alloys, including hot deformation of the ingot into a slab, hot rolling and subsequent heat treatment of the plates, the slab is produced by forging ingots in three stages, the first of which is forged with a degree of deformation 40 ÷ 60% after heating to a temperature of 220 ÷ 280 ° C above the temperature of the polymorphic transformation (TPP), in the second - with a degree of deformation of 30 ÷ 50% after heating at 80 ÷ 220 ° C above the TPP, in the third - with a degree of deformation of 30 ÷ 40% after heating to a temperature of 20 ÷ 60 ° C below the TPP, the first hot rolling is carried out with a degree of deformation of 30 ÷ 90% after heating the slab to a temperature of 80 ÷ 120 ° C above the TPP and cooling to room temperature, and the second hot rolling is performed in two stages, in the first of which the roll is heated to a temperature of 20 ÷ 50 ° C below the TPP and rolled with a degree of deformation of 23 ÷ 35%, followed by cooling to room temperature, and in the second, the final deformation is carried out with a degree of deformation of 23 ÷ 35% after heating of the roll to a temperature of 30 ÷ 50 ° C is lower than the TPP, moreover, the resulting plate is cooled to room temperature after the final deformation is carried out on a live roll in the rocking mode.

The essence of the invention is as follows.

Free forging of the ingot at a temperature of the β-region with a degree of 40 ÷ 60% after heating to a temperature of 220 ÷ 280 ° C above the polymorphic transformation temperature (TPP) destroys the cast structure and grinds the primary β-grain.

Next, free forging of the workpiece with a degree of 30-50% is carried out after heating to a temperature of 80 ÷ 220 ° C above the TPP. The heating temperature of the workpiece and the degree of deformation are determined based on the conditions for obtaining a regulated structure in the final plates.

In the first and second forging operations, differently oriented shells are brewed and metal is densified at the junctions of the dendrites, mechanical averaging of the alloy composition, and elimination of zonal and dendritic segregation in the ingot are performed.

Forging a workpiece into a slab in the (α + β) region after heating 20–40 ° C below the polymorphic transformation temperature, the so-called “Half-hot hardening” destroys the large-angle grain boundaries. The strain value of 30–40% is determined by the need for the metal to obtain sufficient energy to facilitate the recrystallization treatment during subsequent heating of the slab to β-region temperatures.

After forging operations, the slab is machined to remove surface forging defects and a gas-saturated layer.

Next, a machined slab is rolled with a degree of deformation of 30 ÷ 90% after heating to a temperature of 80 ÷ 120 ° C above the polymorphic transformation temperature and cooled to room temperature. When the slab is heated for rolling to a temperature of 80 ÷ 120 ° C above the polymorphic transformation temperature, the β-phase recrystallizes with grain refinement and the formation of a macrostructure. Heating the slab to temperatures below the indicated temperature range causes the appearance of a banded structure and a decrease in the plastic characteristics of the alloy. Heating to temperatures above the specified range causes collective recrystallization of the alloy and leads to the formation of large grains, and also initiates the appearance of cracks as a result of the formation of a large gas-saturated layer on the surface of the roll. The degree of deformation of 30 ÷ 90% is due to the provision of the required volume of deformation of the plates in the (α + β) region during subsequent rolling. After rolling in order to fix the recrystallized β-phase, the roll is cooled to room temperature.

In the process of rolling deformation in the (α + β) region, microstructure is formed. The following rolling is carried out with a degree of deformation of 23–35% after heating the roll to a temperature of 20 ÷ 50 ° C below the polymorphic transformation temperature, followed by cooling of the roll to room temperature. Heating of the roll above (TPP-20) ° C leads to coarsening of the structure with possible overheating of the metal and, as a result, to a mismatch between the mechanical properties and the structure of the finished product. Heating the roll below (TPP-50) ° C causes a cooling of the metal and leads to the appearance of surface cracks in the roll due to a decrease in the ductility of the metal. Rolling in the (α + β) region with a degree of deformation of less than 23% reduces the efficiency of the process due to the small volume of deformation, increasing the number of heatings and deforming operations. Rolling in the (α + β) region with a degree of deformation of more than 35% increases the duration of the process, thereby causing considerable effort due to cooling of the rolled metal. After rolling in the (α + β) region in order to obtain a homogeneous microstructure, the resulting roll is cooled to room temperature.

The final deformation of the plates is carried out by rolling with a degree of deformation of 23–35% after heating the roll to a temperature of 30–50 ° C below the polymorphic transformation temperature. The temperature of heating the roll (TPP - 30 ÷ 50) ° C is determined based on the conditions for obtaining the required values of mechanical properties, microstructure and surface quality. After rolling, in order to avoid tamping of the metal at the points of contact with the rollers, the resulting plate is cooled in the swaying mode. In the rocking mode, the rollers are rotated through an angle of 90 ÷ 480 ° in one direction, and then after stopping in the opposite direction by the same amount. Swing cooling helps to ensure the stability of mechanical properties throughout the volume of the slab.

The industrial applicability of the proposed method is confirmed by the following example of a specific implementation of the invention.

Example. The proposed method was tested in the manufacture of plates with dimensions of 50 × 1000 × 2000 mm from a two-phase titanium alloy W 23. The temperature of the polymorphic transformation of the alloy (TPP) is 890 ° C. The slab was made from an ingot with a diameter of 740 mm and a mass of 3200 kg. The ingot was heated to a temperature of 1150 ° C (260 ° C higher than the TPP) and forged with a degree of deformation of 55%. Then the billet was heated to a temperature of 1100 ° C (210 ° C higher than the TPP) and forged with a degree of deformation of 50%. After that, the preform was heated to a temperature of 860 ° C (30 ° C below the TPP) and deformed with a degree of deformation of 36%. The resulting slab was machined to a size of 280 × 1080 × 1730 mm. The machined slab was heated to a temperature of 990 ° C (100 ° C higher than the TPP), rolling was performed on a quarto-2000 mill with a total degree of deformation of 50%, followed by cooling to a workshop temperature. Next, the roll was heated to a temperature of 860 ° C (30 ° C below the TPP), rolled with a degree of deformation of 30% and cooled to the temperature of the workshop. Then, the roll was heated to a temperature of 850 ° C (40 ° C lower than the TPP) and the final rolling was carried out with a degree of deformation of 28%, after which the resulting plates were cooled on a rolling table in the rocking mode.

The resulting slabs were subjected to adjustation treatment, as well as subsequent tests of mechanical properties and structural control. The test results of the mechanical properties are given in table 1.

The microstructure of the plates in the direction along the rolling is shown in figure 1, where:

a is the microstructure of plates made by the proposed method;

b - the microstructure of the plates made by a known method.

The macrostructure of the plates in the direction across the rolling is shown in figure 2, where:

a is the macrostructure of plates made by the proposed method;

b - the macrostructure of plates made by a known method.

Table 1 A method of manufacturing plates The condition of the test samples Mechanical properties transverse direction longitudinal direction temporary resistance σ _in , kg / mm ² elongation δ,% relative narrowing ψ,% impact strength KCU, MJ / m ² Proposed Aged 124.3 10.8 30.9 0.4 Hardened and aged 128.4 10,4 38,4 0.4 Famous Aged 115.6 7.1 15.3 0.32 Hardened and aged 116.3 6.8 14.9 0.33

The resulting plates are characterized by a homogeneous fine-grained macrostructure, an increased level and stability of mechanical properties, as well as high accuracy of geometric dimensions and the absence of surface defects.

Claims (1)

A method of manufacturing plates from two-phase titanium alloys, including hot deformation of an ingot into a slab, hot rolling and subsequent heat treatment of plates, characterized in that hot deformation is carried out by forging an ingot in three stages, the first of which is forged with a degree of deformation of 40 ÷ 60% after heating to a temperature of 220 ÷ 280 ° C above the temperature of the polymorphic transformation of the TPP, on the second - with a degree of deformation of 30 ÷ 50% after heating by 80 ÷ 220 ° C above the TPP, on the third - with a degree of deformation of 30 ÷ 40% after heating to a temperature 20 ÷ 60 ° C below the TPP, while the first hot rolling is carried out with a degree of deformation of 30 ÷ 90% after heating the slab to a temperature of 80 ÷ 120 ° C above the TPP and cooling the resulting roll to room temperature, and the second hot rolling is performed in two stages, in the first of which the roll is heated to a temperature of 20 ÷ 50 ° C below the TPP and rolled with a degree of deformation of 23 ÷ 35%, followed by cooling to room temperature, in the second, the final deformation is carried out with a degree of deformation of 23 ÷ 35% after heating the roll to temperature at 30 ÷ 50 ° С below TPP, and cooling the resulting plate is carried out to room temperature after the final deformation in the swing mode on the rolling table.

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