CN111826538A - Preparation method of titanium alloy with bimodal structure and titanium alloy with bimodal structure - Google Patents

Abstract

The invention discloses a preparation method of a titanium alloy with a bimodal structure and the titanium alloy with the bimodal structure, which comprises the following steps: the method comprises the following steps: the Ti-55531 alloy spherical powder is subjected to selective laser sintering to generate a printing Ti-55531 alloy; step two: putting the printed Ti-55531 alloy into a vacuum heat treatment furnace for vacuum circulating solution heat treatment to obtain an equiaxial alpha-phase TI55531 alloy; step three: the TI55531 alloy with the equiaxial alpha phase is put into a vacuum heat treatment furnace for aging heat treatment to generate a secondary alpha phase, and the TI55531 alloy with a double-state structure is obtained. The titanium alloy with the bimodal structure prepared by the method has excellent mechanical properties and can meet the aerospace application standard.

Description

Preparation method of titanium alloy with bimodal structure and titanium alloy with bimodal structure

Technical Field

The invention relates to a preparation method of a titanium alloy with a bimodal structure and the titanium alloy with the bimodal structure.

Background

Titanium alloy is used as a novel light metal material which develops rapidly in recent decades and has excellent comprehensive performance matching of strength, modulus, toughness, high damage tolerance, weldability and the like, so that the titanium alloy becomes a main structural material of advanced airplanes and aeroengines.

With the improvement of the requirements of people on the aircraft and the change of the design concept of the aircraft, the development of the aviation industry puts higher and higher requirements on the comprehensive performance of the titanium alloy, and the titanium alloy not only requires high strength and high toughness, but also requires higher plasticity.

The existing titanium alloy cannot meet the rapid development of the aviation industry.

Disclosure of Invention

Based on the above problems, in one aspect, the invention provides a preparation method of a titanium alloy with a dual-state structure, and the titanium alloy with the dual-state structure prepared by the preparation method of the titanium alloy with the dual-state structure has excellent mechanical properties and can meet the aerospace application standards.

The technical scheme is as follows: a preparation method of a titanium alloy with a two-state structure comprises the following steps:

the method comprises the following steps: the Ti-55531 alloy spherical powder is subjected to selective laser sintering to generate a printing Ti-55531 alloy;

step two: putting the printed Ti-55531 alloy into a vacuum heat treatment furnace for vacuum circulating solution heat treatment to obtain an equiaxial alpha-phase TI55531 alloy;

step three: the TI55531 alloy with the equiaxial alpha phase is put into a vacuum heat treatment furnace for aging heat treatment to generate a secondary alpha phase, and the TI55531 alloy with a double-state structure is obtained.

Further, the selective laser sintering process comprises the following steps: the power is 200W, the scanning speed is 1000-1200mm/s, the layer thickness is 30-50 μm, the line spacing is 90-130 μm, and the strip scanning strategy is used for printing.

Further, the printed Ti-55531 alloy was a Ti-55531 alloy with a relative density of 99.96%.

Further, the equiaxed alpha phase is spherical or ellipsoidal and has a diameter of 1-3 μm.

Further, the vacuum circulating solid solution heat treatment comprises heating, heat preservation, heating, circulating temperature control and cooling.

Further, the circulation temperature is controlled to be slower from the high temperature to the low temperature than from the low temperature to the high temperature, and the circulation is performed sequentially.

Further, the high temperature is 835 ℃, the low temperature is 740 ℃, the speed from the high temperature to the low temperature is slower than the speed from the low temperature to the high temperature, the time from the high temperature to the low temperature is 50min, and the time from the low temperature to the high temperature is 30 min.

On the other hand, the invention also provides a titanium alloy with a bimodal structure, which is prepared by the method, the fracture strength of the titanium alloy with the bimodal structure is more than 1350MPa, the yield strength is more than 1300MPa, the elongation is more than 9%, the fracture toughness is more than 65MPa.m1/2, and the titanium alloy has excellent mechanical properties and can meet the aerospace application standard.

The Ti-5Al-5Mo-5V-3Cr-1Zr alloy is printed by adjusting parameters such as laser power, layer thickness, lap joint rate, scanning speed and the like through a selective laser Sintering (SLM) process. Because the printed alloy has a metastable beta structure, and the strength and the plasticity can not reach the aerospace standard, a cyclic heat treatment technology is further developed, so that the alloy can obtain an equiaxed alpha phase. Since the equiaxed α phase is generally difficult to achieve by heat treatment, it can be achieved only by annealing after hot working, and since the titanium alloy component produced by additive manufacturing does not have the conditions for hot working, a heat treatment method has been developed which can achieve equiaxed α without damaging the component.

Drawings

FIG. 1 is a schematic view of temperature control of vacuum cyclic solution heat treatment according to the present invention;

FIG. 2 is a schematic temperature control diagram of aging heat treatment according to the present invention.

Detailed Description

The invention will be further explained with reference to the drawings.

In the present invention, the relative density is measured density/theoretical density.

A preparation method of a titanium alloy with a two-state structure comprises the following steps:

the method comprises the following steps: the Ti-55531 alloy spherical powder is subjected to selective laser sintering to generate a printing Ti-55531 alloy;

step two: putting the printed Ti-55531 alloy into a vacuum heat treatment furnace for vacuum circulating solution heat treatment to obtain an equiaxial alpha-phase TI55531 alloy;

step three: the Ti55531 alloy with the equiaxial alpha phase is put into a vacuum heat treatment furnace for aging heat treatment to generate a secondary alpha phase, and the TI55531 alloy with the duplex structure is obtained.

In the invention, the vacuum circulating solution heat treatment comprises heating, heat preservation, heating, circulating temperature control and cooling.

In the present invention, further, the circulation temperature control is performed such that the speed from the high temperature to the low temperature is slower than the speed from the low temperature to the high temperature, and the circulation is performed sequentially.

Example 1:

a preparation method of a TI55531 alloy with a two-state structure comprises the following steps:

the method comprises the following steps: the Ti-55531 alloy spherical powder is put into an SLM (selective melt sintering) device, and is printed by using a stripe scanning strategy under the conditions that the power is 200W, the scanning speed is 1000-1200mm/s, the layer thickness is 30-50 mu m, and the line spacing is 90-130 mu m, so that the printed Ti-55531 alloy with the relative density of 99.96% is obtained.

Step two: and (3) placing the printed Ti-55531 alloy into a vacuum heat treatment furnace for vacuum heat treatment to obtain the TI55531 alloy with the equiaxed alpha phase, wherein the equiaxed alpha phase is spherical or ellipsoidal and has the diameter of 1-3 mu m.

The temperature control of the vacuum circulation solid solution heat treatment is shown in figure 1, the temperature is increased to 790 ℃ within 79min, the temperature is maintained at 790 ℃ for 80min, the temperature is increased to 835 ℃ within 5min, and the circulation treatment is carried out: the temperature was decreased from 835 ℃ to 740 ℃ over 50min, then increased to 835 ℃ over 30min, followed by 5 cycles, and finally cooled with argon.

The aging treatment is shown in figure 2: and putting the treated TI55531 alloy into a vacuum furnace, preserving the heat for 6 hours at the temperature of 600 ℃, generating a secondary alpha phase, and matching with the equiaxial alpha phase generated in the step II to obtain the TI55531 alloy with a duplex structure.

The mechanical property of the TI55531 alloy with a two-state structure of the embodiment is detected, and the detection conditions and standards are as follows: tensile and fracture toughness at room temperature were tested according to ASTM E8/E8M-16a and ASTM E1820-2018. Fracture toughness was measured using a CT type compact tensile specimen 62.5mm high, 60mm wide and 25mm thick, 2mm cracks were preformed on a fatigue machine, and then the test was started.

The detection result is as follows: the fracture strength is more than 1350MPa, the yield strength is more than 1300MPa, the elongation is more than 9 percent, the fracture toughness is more than 65MPa.m1/2, and the composite material has excellent mechanical properties.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A preparation method of a titanium alloy with a two-state structure comprises the following steps:

the method comprises the following steps: the Ti-55531 alloy spherical powder is subjected to selective laser sintering to generate a printing Ti-55531 alloy;

step two: putting the printed Ti-55531 alloy into a vacuum heat treatment furnace for vacuum circulating solution heat treatment to obtain an equiaxial alpha-phase TI55531 alloy;

step three: the TI55531 alloy with the equiaxial alpha phase is put into a vacuum heat treatment furnace for aging heat treatment to generate a secondary alpha phase, and the TI55531 alloy with a double-state structure is obtained.

2. The method of claim 1, wherein the selective laser sintering process comprises: the power is 200W, the scanning speed is 1000-1200mm/s, the layer thickness is 30-50 μm, the line spacing is 90-130 μm, and the strip scanning strategy is used for printing.

3. The method of claim 1, wherein the printed Ti-55531 alloy is a Ti-55531 alloy having a relative density of 99.96%.

4. The method of claim 1, wherein the equiaxed alpha phase is spherical or ellipsoidal and has a diameter of 1 μm to 3 μm.

5. The method for producing a titanium alloy having a two-state structure according to claim 1, wherein said vacuum cyclic solution heat treatment is heating, holding, heating, cyclic temperature control, cooling.

6. The method of claim 5, wherein the cycling temperature is controlled such that the speed from the high temperature to the low temperature is slower than the speed from the low temperature to the high temperature, and the cycling is performed sequentially.

7. The method according to claim 5, wherein the high temperature is 835 ℃, the low temperature is 740 ℃, the speed from the high temperature to the low temperature is slower than the speed from the low temperature to the high temperature by 50min, and the time from the low temperature to the high temperature is 30 min.

8. The method for producing a titanium alloy of a bimodal structure as claimed in claim 5, characterized in that the number of said cycles is 5.

9. The method for preparing a titanium alloy having a bimodal structure according to claim 1, wherein said aging heat treatment in said step (iii) is performed at 600 ℃ for 6 hours.

10. A titanium alloy of bimodal structure, characterized in that it is produced by a method according to any one of claims 1 to 9.

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