WO2022041252A1

WO2022041252A1 - Method for eliminating cracks during 3d printing with nickel-based superalloy

Info

Publication number: WO2022041252A1
Application number: PCT/CN2020/112689
Authority: WO
Inventors: 刘祖铭; 魏冰; 农必重; 吕学谦; 任亚科; 曹镔; 艾永康
Original assignee: 中南大学
Priority date: 2020-08-30
Filing date: 2020-08-31
Publication date: 2022-03-03
Also published as: CN112011713B; CN112011713A

Abstract

Disclosed is a method for eliminating cracks during 3D printing with a nickel-based superalloy. The nickel-based superalloy comprises the following components in mass percentages: 14-23% of Co, 11-15% of Cr, 2-5% of Al, 3-6% of Ti, 2.7-5% of Mo, 0.5-3% of W, 0.5-4% of Ta, 0.25-3% of Nb, 0.02-0.06% of Zr, 0.01-0.05% of B, 0.0015-0.1% of C, and 0.05-0.18 wt% of RE, with the balance being Ni; or a nickel-based superalloy selected from one of IN738LC, CM247LC, CMSX-4, René 142, Hastelloy X, IN718 and IN625 is used as a matrix, and 0.05-0.18 wt% of RE is added to the matrix, with the RE being selected from at least one of Sc, Y, La, Ce and Er. In view of the problem of cracking easily occurring during 3D printing with a γ'-phase-precipitation-strengthened nickel-based superalloy, it is proposed in the method that by means of rare earth microalloying with an appropriate amount of rare earth, cracking susceptibility during 3D printing with the γ'-phase-precipitation-strengthened nickel-based superalloy is reduced, the 3D printing process window is widened, the generation of cracks during 3D printing is inhibited, the strength and plasticity of a formed part are greatly improved, and the formation of cracks during subsequent machining processes, such as cracking during inter-process storage and cracking during subsequent heat treatment, is effectively prevented. A γ'-phase-precipitation-strengthened nickel-based superalloy, René104, prepared by means of the method is found to have no cracks, the compactness exceeds 99.4%, the yield strength and the tensile strength respectively reach 935 MPa and 1256 MPa, and the elongation exceeds 14.0%.

Description

A method to eliminate cracks in 3D-printed nickel-based superalloys

technical field

The invention provides a method for eliminating cracks in 3D printing nickel-based superalloys, belonging to the technical field of superalloy additive manufacturing.

Background technique

The γ' phase precipitation strengthening nickel-based superalloy is one of the major breakthroughs in the field of material science. Its strengthening phase is an ordered and coherent intermetallic compound such as γ'-Ni ₃ (Al, Ti), usually by casting and deformation processing Or powder forming technology, widely used in advanced aero-engines. However, these techniques cannot directly form parts with complex shapes. 3D printing, or additive manufacturing technology, can directly generate three-dimensional parts with near-net shape size layer by layer from three-dimensional computer-aided design data. It has unique advantages in the preparation of high-performance components with complex shapes. It has been used in titanium alloys, aluminum Alloys, stainless steel and nickel-based alloys and other materials are used. The large temperature gradient, fast cooling rate and repeated remelting in the 3D printing forming process result in high residual stress in the formed parts, and are prone to deformation and cracking, which brings challenges to 3D printing high-quality parts, especially high Al and Ti content. The γ' phase precipitation strengthens nickel-based superalloys, poor welding performance, and cracking have become the most prominent problems in 3D printing of such alloys.

In response to the above problems, exploratory research has been carried out at home and abroad. Catchpole-Smith et al [Catchpole-Smith S, et al. Fractal scan strategies for selective laser melting of 'unweldable' nickel superalloys[J]. Additive Manufacturing, 2017, 15:113-122.] investigated the effect of 3 different scan paths on cracking of "non-weldable" nickel-based superalloys formed by selective laser melting (SLM), samples formed with irregularly shaped scan paths, thermal The stress is smaller and evenly distributed, the cracks are significantly reduced, and the density is increased by 2 ± 0.7%, but the cracks cannot be completely eliminated; further hot isostatic pressing can be used to completely eliminate the cracks. Xu et al [Jianjun Xu, et al. The initiation and propagation mechanism of the overlapping zone cracking during laser solid forming of IN738LC superalloy[J].Journal of Alloys and Compounds, 2018, 749: 859-870] heated the substrate to 700℃ and above, and prepared a completely crack-free IN738LC nickel-based superalloy. This method of raising the substrate temperature to a temperature of 700°C or higher is likely to cause coarse grains due to the excessively high substrate temperature. [Quanquan Han, et al. Additive manufacturing of high-strength crack-free Ni-based Hastelloy X superalloy[J]. Additive Manufacturing, 2019, 30: 100919] Elimination of cracks in Hastelloy X nickel-based superalloy by adding nano-TiC. Chinese patent (CN108941560B) discloses a method for eliminating cracks in René 104 nickel-based superalloy by laser additive manufacturing, and proposes to eliminate forming parts by designing laser forming parameters and zone scanning strategy, combined with stress relief annealing and spark plasma sintering (SPS) treatment scheme of internal cracks and inhibits the growth of grains during sintering. Chinese patent (CN108994304B) discloses a method for eliminating cracks in additive manufacturing of metal materials and improving mechanical properties. Stress relief annealing with specific parameters and SPS treatment with specific parameters are used in sequence, which not only eliminates product cracks, but also achieves mechanical properties. a substantial increase. The above patents are all post-processing to eliminate cracks in 3D printed parts. The Chinese patent (CN104988355A) discloses a method for reducing the hot cracking tendency of nickel-based superalloy powder materials for printing, which solves the problem of hot cracking defects by adding a large amount of Hf and/or B elements. However, the above methods cannot suppress the problems such as cracks generated during printing and/or subsequent heat treatment of 3D printed nickel-based superalloy parts.

The present invention proposes for the first time that rare earth microalloying by appropriate amount of rare earth can reduce the cracking sensitivity of γ' phase precipitation-strengthened nickel-based superalloy 3D printing, widen the 3D printing process window of γ' phase precipitation-strengthened nickel-based superalloy, and inhibit 3D printing and subsequent The generation of heat treatment cracks is suitable for additive manufacturing of various shapes of parts.

technical problem

The invention proposes a method for eliminating cracks in 3D printing nickel-based superalloys. In view of the problem that cracks are easily generated in 3D printing of γ'-phase precipitation-strengthening nickel-based superalloys, it is first proposed to carry out rare-earth microalloying by appropriate amount of rare earth to reduce γ'-phase precipitation strengthening. Nickel-based superalloy 3D printing cracking sensitivity, widening the γ' phase precipitation strengthening nickel-based superalloy 3D printing process window, inhibiting 3D printing and subsequent heat treatment cracks, and greatly improving the strength and plasticity of formed parts.

technical solutions

The present invention is a method for eliminating cracks in 3D printing nickel-based superalloy. The dense nickel-based superalloy is prepared by 3D printing using nickel-based superalloy powder as raw material; the nickel-based superalloy is calculated in mass percentage, including the following said components.

Co: 14-23%.

Cr: 11-15%.

Al: 2-5%.

Ti: 3-6%.

Mo: 2.7-5%.

W: 0.5-3%.

Ta: 0.5-4%.

Nb: 0.25-3%.

Zr: 0.02-0.06%.

B: 0.01-0.05%.

C: 0.0015-0.1%.

RE: 0.05-0.18wt%.

Or use other non-weldable nickel-based superalloys as the matrix, and add 0.05-0.18wt% RE into the matrix.

The other non-weldable nickel-based superalloys are selected from one of IN738LC, CM247LC, CMSX-4, René 142, and Hastelloy X; or one of IN718 and IN625 nickel-based superalloys is used as the matrix, and 0.05 -0.18wt% RE.

The parameters of the 3D printing are: the laser power is 150-300W, the laser scanning rate is 500-1100mm/s, the spot diameter is 70-110μm, the laser scanning distance is 60-120μm, the powder layer thickness is 30-50μm, and the forming layer is 30-50μm thick. The laser scanning direction is rotated by 45°-90°, preferably 67°.

The RE is selected from at least one of Sc, Y, La, Ce, and Er.

The present invention is a method for eliminating cracks in a 3D printing nickel-based superalloy, where the nickel-based superalloy, in terms of mass percentage, includes the following components μm.

Co: 20.6%.

Cr: 13%.

Al: 3.4%.

Ti: 3.9%.

Mo: 3.8%.

W: 2.1%.

Ta: 2.4%.

Nb: 0.9%.

Zr: 0.05%.

B: 0.03%.

C: 0.04%.

RE: 0.06-0.18wt%.

The remainder is Ni.

The present invention is a method for eliminating cracks in 3D printing nickel-based superalloy, where RE is Sc; or RE is a mixture of Sc and at least one of Y, La, Ce, and Er.

The present invention is a method for eliminating cracks in a 3D printing nickel-based superalloy, wherein the nickel-based superalloy powder is prepared through the following steps.

Step 1: Vacuum smelting.

The raw materials are dispensed according to the design composition, and the raw materials are put into the crucible of the atomizing pulverizing furnace, and the vacuum melting is carried out by induction heating under the vacuum degree of less than 0.1Pa.

Step 2: Degassing.

After the raw materials are melted, vacuum degassing is performed for 10 to 20 minutes.

Step 3: Refinement.

Fill the atomizing pulverizing furnace with high-purity inert gas to 0.1-0.11 MPa, and keep the molten master alloy molten in the temperature range of 1600℃～1650℃ for 10min～15min.

Step 4: Atomization.

The molten mother alloy melt is flowed down through the guide tube at a flow rate of 3.5kg/min~5kg/min, and the metal liquid flow is broken into fine droplets with a high-pressure, high-purity inert gas of 3MPa~5MPa, and the droplets are cooled and cooled. It solidifies to form spherical powder, which goes into the powder collection tank.

Step 5: Sieve.

After the powder is fully cooled, air classification and ultrasonic vibration screening are used under the protection of inert gas to obtain spherical nickel-based superalloy powder with a medium particle size of 53-106 μm and a fine powder particle size of 15-53 μm, and vacuum-packed .

The inert gas should be helium, argon, or a mixed gas of argon and helium, with a purity of 99.99 wt %, wherein the oxygen content is less than 0.0001 wt %.

The oxygen content of the obtained nickel-based superalloy powder is less than or equal to 0.0126wt%, and the sulfur content is less than or equal to 0.0056wt%. In industrial application, nickel-based superalloy powder can also be prepared by plasma rotating electrode atomization method.

The present invention is a method for eliminating cracks in 3D printing nickel-based superalloy, wherein the oxygen content of the nickel-based superalloy powder is less than or equal to 0.01wt%, and the sulfur content is less than or equal to 0.004wt%.

The present invention is a method for eliminating cracks in 3D printing nickel-based superalloy. The nickel-based superalloy powder is tested for fluidity through 50g/2.5mm aperture, and the result is 15-25 s. Optimized for 15.5-16 s.

The present invention is a method for eliminating cracks in 3D printing nickel-based superalloy, and the 3D printing is one of selective laser melting (SLM), electron beam melting (EBM), or coaxial powder feeding laser forming (LENS).

The present invention is a method for eliminating cracks in 3D printing nickel-based superalloy. The parameters of the 3D printing are: laser power of 150-300 W, laser scanning rate of 500-1100 mm/s, spot diameter of 70-110 μm, and laser scanning spacing of 60 ~120 μm, the thickness of the powder layer is 30 to 50 μm, and the laser scanning direction between the forming layers is rotated by 45° to 90°, preferably 67°.

The invention provides a method for eliminating cracks in 3D printing nickel-based superalloy. After the 3D printing is completed, stress relief annealing at 450-650° C. for 0.5-3 hours is performed in a vacuum or an inert gas atmosphere to obtain a product.

The invention provides a method for eliminating cracks in 3D printing nickel-based superalloys. The density of the parts is 99.3%-99.5%, the room temperature yield strength is 918-935MPa, the tensile strength is 1120-1256MPa, and the elongation is 12.5-14.5 %.

The invention provides a method for eliminating cracks in 3D printing nickel-based superalloy, and the prepared alloy powder is supersaturated solid solution alloy powder with uniform composition. The alloy powder is prepared by atomization and rapid solidification, and the added elements can exceed the equilibrium solid solution limit to form a supersaturated solid solution; there is no segregation of alloy elements. 3D-printed and rapidly solidified parts using this alloy powder have a fine dendritic structure, and the element segregation is limited to the sub-micron level. Trace rare earth elements inhibit the formation of low melting point phases, eliminate low melting point compounds formed by B, Zr, etc., narrow the solidification temperature range, and reduce the cracking sensitivity of γ' phase precipitation-strengthened nickel-based superalloys, thereby inhibiting the formation of 3D printing cracks .

beneficial effect

(1) The present invention is aimed at the problem of γ' phase precipitation strengthening nickel-based superalloy with high Al and Ti content, poor welding performance, and easy cracking during 3D printing. The rare earth microalloying and 3D printing parameters are optimized by a suitable amount of rare earth. It reduces the cracking sensitivity of γ' phase precipitation-strengthened nickel-based superalloys, eliminates 3D printing cracks, and greatly improves the strength and plasticity of formed parts.

(2) In the present invention, supersaturated solid solution superalloy powder is prepared by adding trace amounts of Sc, Y, La, Ce, Er or mixed addition, followed by inert gas atomization or plasma rotating electrode atomization and rapid solidification, and the obtained powder has high sphericity and particle size. The distribution range is narrow, and the impurity elements such as oxygen and sulfur are significantly reduced, which is suitable for 3D printing technology.

(3) The present invention reduces the cracking sensitivity of the γ' phase precipitation strengthened nickel-based superalloy in the process of rapid melting and solidification of 3D printing, and widens the 3D printing process window of the γ' phase precipitation strengthened nickel-based superalloy.

(4) Through the synergistic effect of rare earth microalloying and parameter optimization, the present invention not only ensures the quality of 3D printing parts, but also controls the generation and accumulation of residual stress in the 3D printing process, and effectively inhibits the generation of cracks in the 3D printing process. .

(5) In the present invention, by inert gas atomization or plasma rotary electrode atomization powder milling and 3D printing rapid prototyping, the element segregation is limited to sub-micron level, and the uniformity of composition and structure is improved.

(6) The preparation method of the present invention reduces the component segregation of powder and 3D printing parts, greatly reduces the accumulation of thermal stress in 3D printing, suppresses the generation of solidification cracks and deformation, and improves the quality and mechanical properties of the parts.

(7) The present invention uses an appropriate amount of rare earth to microalloy rare earth, eliminates γ' phase precipitation strengthening nickel-based superalloy 3D printing cracks, greatly improves the strength and plasticity of formed parts, and effectively prevents subsequent processing such as storage cracking between processes and subsequent heat treatment cracking. crack formation during the process.

(8) The present invention effectively eliminates the 3D printing cracks of the γ' phase precipitation-strengthened nickel-based superalloy with high Al and Ti content. The γ' phase precipitation-strengthened nickel-based superalloy René104 prepared by this method has no cracks in the formed parts. The density exceeds 99.4%, the room temperature yield strength and tensile strength reach 935MPa and 1256MPa, respectively, and the elongation exceeds 14.0%.

To sum up, the present invention aims at the problems of γ' phase precipitation strengthening nickel-based superalloy with high Al and Ti content, poor welding performance and easy cracking during 3D printing. Er or mixed addition for micro-alloying, followed by inert gas atomization or plasma rotating electrode atomization for rapid solidification to prepare supersaturated solid solution superalloy powder, reducing the γ' phase precipitation strengthening nickel-based superalloy 3D printing crack sensitivity, widening γ 'phase precipitation strengthened nickel-based superalloy 3D printing process window, combined with parameter optimization to eliminate 3D printing γ' phase precipitation strengthened nickel-based superalloy cracks, greatly improve the strength and plasticity of formed parts, and effectively prevent storage cracking between processes and subsequent heat treatment cracking Crack formation during subsequent processing.

Description of drawings

FIG. 1 is a schematic diagram of scanning strategies adopted in Embodiments 1, 2, and 3 and Comparative Examples 1, 2, and 3. FIG.

FIG. 2 is a microstructure image of the rare earth Sc microalloyed René 104 alloy prepared by SLM in Example 1. FIG.

Figure 3 is a scanning electron microscope (SEM) photograph of the microstructure of the rare earth Y microalloyed René 104 alloy prepared by SLM in Example 2.

FIG. 4 is an SEM photograph of the microstructure of the Sc, Y mixed rare earth microalloyed René 104 alloy prepared by SLM in Example 3. FIG.

Figure 5 is a SEM photograph of the microstructure of the René 104 alloy prepared by SLM in Example 4.

FIG. 6 is an SEM photograph of the microstructure of the René 104 alloy prepared by SLM in Example 5. FIG.

Figure 7 is a SEM photograph of the microstructure of the rare earth Sc microalloyed René 104 alloy prepared by SLM in Comparative Example 1.

FIG. 8 is a SEM photograph of the microstructure of the René 104 alloy prepared by SLM in Comparative Example 2. FIG.

FIG. 9 is a SEM photograph of the microstructure of the René 104 alloy prepared by SLM in Comparative Example 3. FIG.

Embodiments of the present invention

The present invention will be further elaborated below with reference to the accompanying drawings and specific embodiments.

Example 1.

The method of the present invention is applied to the following René 104 nickel-based superalloy, and the mass fraction of rare earth Sc element is 0.08%, and the weight percentage of the alloy is 0.08%.

20.6Co~13Cr~3.4Al~3.9Ti~3.8Mo~2.1W~2.4Ta~0.9Nb~0.05Zr~0.03B~0.04C~0.08Sc~ The balance is Ni, and argon gas is used after preparing the master alloy of this alloy Atomization and rapid solidification are used to make powder, and the alloy powder of 15-53 μm is sieved through airflow classification and ultrasonic vibration sieve powder.

The present invention is used for SLM forming René104 nickel-based superalloy. First, the sieved René104 nickel-based superalloy powder is dried in a vacuum drying oven at 120° C. for 4 hours. After the substrate is heated to 170° C., the dried powder is dried. Load into the powder supply cylinder and spread powder, and pass argon or nitrogen into the working chamber until the oxygen content is less than 100ppm. Then enter the printing process, and repeat the steps of powder spreading and laser scanning powder until the printing is completed, and the René104 nickel-based superalloy block is obtained. Then, the printed block and the substrate were subjected to stress relief annealing at 450 °C for 3 h in a vacuum atmosphere.

The optimized SLM process parameters are: laser spot diameter 70μm, laser power 250W, laser scanning rate 900mm/s, laser scanning spacing 90μm, powder layer thickness 40μm, using strip scanning strategy, laser scanning between layers The direction is rotated 67°, and the forming strategy is shown in Figure 1.

The results in Figure 2 show that no cracks were observed in the printed parts.

The density of the prepared sample is 99.44%, the yield strength and tensile strength are 918MPa and 1236MPa, respectively, and the elongation is 14.0%.

Example two.

The method of the present invention is applied to the following René 104 nickel-based superalloy, and the mass fraction of rare earth Y element is 0.12%, and the alloy weight percentage is 0.12%.

20.6Co~13Cr~3.4Al~3.9Ti~3.8Mo~2.1W~2.4Ta~0.9Nb~0.05Zr~0.03B~0.04C~0.12Y~ The balance is Ni, and helium gas is used after preparing the master alloy of this alloy Atomization and rapid solidification are used to make powder, and the alloy powder of 15-53 μm is sieved through airflow classification and ultrasonic vibration sieve powder.

The present invention is used for SLM forming René104 nickel-based superalloy. First, the sieved René104 nickel-based superalloy powder is dried in a vacuum drying oven at 120° C. for 4 hours. After the substrate is heated to 170° C., the dried powder is dried. Load into the powder supply cylinder and spread powder, and pass argon or nitrogen into the working chamber until the oxygen content is less than 100ppm. Then enter the printing process, and repeat the steps of powder spreading and laser scanning powder until the printing is completed, and the René104 nickel-based superalloy block is obtained. Then, the printed block together with the substrate was subjected to stress relief annealing at 500 °C for 2 h in argon.

The results in Figure 3 show that no cracks were observed in the printed parts.

The density of the prepared sample is 99.39%, the yield strength and tensile strength are 930MPa and 1224MPa, respectively, and the elongation is 12.8%.

Example three.

The method of the present invention is applied to the following René 104 nickel-based superalloy, and the mass fractions of 0.06% rare earth Sc element and 0.08% rare earth Y element are added, and the alloy weight percentage is .

20.6Co～13Cr～3.4Al～3.9Ti～3.8Mo～2.1W～2.4Ta～0.9Nb～0.05Zr～0.03B～0.04C～0.06Sc～0.08Y～the balance is Ni, after preparing the master alloy of the alloy Argon atomization is used to rapidly solidify the powder, and the alloy powder of 15-53 μm is sieved through airflow classification and ultrasonic vibrating sieve powder.

The results in Figure 4 show that no cracks were observed in the printed parts.

The density of the prepared sample is 99.46%, the yield strength and tensile strength are 935MPa and 1256MPa, respectively, and the elongation is 14.3%.

Example four.

Using the alloy powder prepared in Example 1 as the raw material, the René 104 alloy bulk was prepared using the 3D printing process parameters used in Example 1 of the Chinese Patent (CN108941560A). The specific parameters of the SLM process are:

The laser power is 250W, the spot diameter is 0.12mm, the scanning speed is 500mm/s, the scanning distance is 0.12mm, and the thickness of the powder layer is 0.03mm.

The scanning strategy used by SLM is the strip scanning strategy. Figure 1 shows the schematic diagram of the strip scanning strategy. The scanning method from bottom to top is adopted. The laser scanning direction between adjacent layers is rotated by 67°, and the strip size is 7mm. , the overlap between the strips is 0.11mm, the purpose is to reduce the superposition of residual stress during the printing process.

Figure 5 is an SEM photograph of the microstructure of the René 104 alloy. The formed part has a dense structure and no cracks are observed. After testing, the density of the prepared René104 alloy is 99.32%, which is better than that of the molded part with a density of 99.18% prepared by SLM in Example 1 of the Chinese Patent (CN108941560A). The yield strength at room temperature is 926MPa and the tensile strength is 1242MPa. , the elongation is 14.2%.

For the above-mentioned molded parts, the same stress relief annealing and SPS treatment as in the first embodiment of the Chinese patent (CN108941560A) were adopted.

The parameters of stress relief annealing are as follows: temperature is 420°C, holding time is 90min, and then cooling with the furnace.

The parameters of spark plasma sintering are: a graphite abrasive tool with a diameter of 40 mm, a heating rate of 60 °C/min, a cooling rate of 60 °C/min, a sintering pressure of 45 MPa, a sintering temperature of 1020 °C, and a holding time of 15 minutes.

After testing, the final density of the prepared René104 alloy is 99.62%, the yield strength at room temperature is 1038MPa, the tensile strength is 1394MPa, and the elongation is 14.5%, which is better than that of the Chinese patent (CN108941560A). Mechanical properties of formed parts prepared by stress relief annealing to relieve residual stress and SPS to remove cracks. The room temperature mechanical properties of the formed parts prepared in Example 1 of the Chinese patent (CN108941560A) are 987 MPa and 1376 MPa, respectively.

Example five.

Using the alloy powder prepared in Example 1 as the raw material, the René104 alloy bulk was prepared by using the 3D printing process parameters used in Comparative Example 1 of the Chinese Patent (CN108941560B). The specific parameters of the SLM process are:

The laser power is 225W, the spot diameter is 0.12mm, the scanning speed is 600mm/s, the scanning distance is 0.11mm, and the thickness of the powder layer is 0.03mm. (without partition strategy).

Figure 6 is a SEM photograph of the microstructure of the René 104 alloy. The structure of the prepared sample is dense and no cracks are observed. After testing, the density of the prepared René104 alloy is 99.2%, the yield strength at room temperature is 913MPa, the tensile strength is 1247MPa, and the elongation is 13.3%.

Chinese patent (CN108941560B) compares the printed parts of Example 1. The density of the pre- and post-treatment (stress relief annealing + SPS) after post-treatment (stress relief annealing + SPS) is 98.12% and 99.02%, respectively. The mechanical properties at room temperature are respectively 98.12% and 99.02%. 751MPa and 916MPa.

Compared with the density and mechanical properties of Comparative Example 1 of the Chinese patent (CN108941560B), the present invention adopts the 3D printing process parameters of Comparative Example 1 with the most severe cracking and the worst part performance in the Chinese patent (CN108941560B), and can also produce high-quality 3D printing. High-quality, crack-free, and mechanically excellent parts. It shows that the alloy and powder prepared by the present invention can widen the 3D printing process window.

Comparative Example 1.

The present invention is used for forming René104 nickel-based superalloy by SLM. Firstly, the screened René104 nickel-based superalloy powder is dried in a vacuum drying oven at 120° C. for 4 hours. After the substrate is heated to 170° C., the dried powder is packed into Put it into the powder supply tank and spread the powder, and pass argon or nitrogen into the working chamber until the oxygen content is less than 100ppm. Then enter the printing process, and repeat the steps of powder spreading and laser scanning powder until the printing is completed, and the René104 nickel-based superalloy block is obtained. Then, the printed block and the substrate were subjected to stress relief annealing at 450 °C for 3 h in a vacuum atmosphere.

The unoptimized SLM process parameters are: the laser spot diameter is 70 μm, the laser power is 400 W, the laser scanning rate is 1200 mm/s, the laser scanning spacing is 90 μm, and the thickness of the powder layer is 30 μm. The scanning direction is rotated by 67°, and the forming strategy is shown in Figure 1.

The results in Fig. 7 show that a small amount of cracks can be observed in the printed parts, the crack length is about 150 μm, and the crack density is 1.4±0.5 mm/mm ² .

The density of the prepared sample is 90.12%, the yield strength and tensile strength are 893MPa and 1085MPa, respectively, and the elongation is 10.4%.

Comparative example two.

The method of the present invention is applied to the following René 104 nickel-based superalloy without adding rare earth elements, and the weight percentage of the alloy is .

20.6Co~13Cr~3.4Al~3.9Ti~3.8Mo~2.1W~2.4Ta~0.9Nb~0.05Zr~0.03B~0.04C~ The balance is Ni. After preparing the master alloy of this alloy, argon gas atomization is used to quickly Solidify and make powder, and sieve the alloy powder of 15-53 μm through airflow classification and ultrasonic vibration sieve powder.

The optimized SLM process parameters are: laser spot diameter 70μm, laser power 250W, laser scanning rate 900mm/s, laser scanning spacing 90μm, powder layer thickness 40μm, using strip scanning strategy, laser scanning between layers The direction is rotated by 67°, and the forming strategy is shown in Figure 1.

The results in Fig. 8 show that many cracks can be observed in the printed parts, the crack length is 300 μm, and the crack density is 2.5±0.6 mm/mm ² .

The density of the prepared sample was 98.9%, the yield strength and tensile strength were 786MPa and 918MPa, respectively, and the elongation was 3.9%.

Comparative example three.

20.6Co~13Cr~3.4Al~3.9Ti~3.8Mo~2.1W~2.4Ta~0.9Nb~0.05Zr~0.03B~0.04C~ The balance is Ni. After preparing the master alloy of this alloy, argon gas atomization is used to rapidly Solidify and make powder, and sieve out alloy powder of 15-53 μm through airflow classification and ultrasonic vibrating sieve powder.

The present invention is used for SLM forming René104 nickel-based superalloy. First, the sieved René104 nickel-based superalloy powder is dried in a vacuum drying oven at 120° C. for 4 hours. After the substrate is heated to 170° C., the dried powder is dried. Load into the powder supply cylinder and spread powder, and pass argon or nitrogen into the working chamber until the oxygen content is less than 100ppm. Then enter the printing process, and repeat the steps of powder spreading and laser scanning powder until the printing is completed, and the René104 nickel-based superalloy block is obtained. Then, the printed block and the substrate were subjected to stress relief annealing at 450 °C for 3 h in an argon atmosphere.

The results in Figure 9 show that obvious cracks can be observed in the printed parts, the crack length is close to 500 μm, and the crack density is 3.7±0.8 mm/mm ² .

The density of the prepared sample is 98.9%, the yield strength and tensile strength are 708MPa and 875MPa, respectively, and the elongation is 2.6%.

Claims

A method for eliminating cracks in 3D printing nickel-based superalloy, characterized in that: the dense nickel-based superalloy is prepared by using nickel-based superalloy powder as raw material by 3D printing; the nickel-based superalloy is calculated in mass percentage. Includes the following components:

Co: 14-23%;

Cr: 11-15%;

Al: 2-5%;

Ti: 3-6%;

Mo: 2.7-5%;

W: 0.5-3%;

Ta: 0.5-4%;

Nb: 0.25-3%;

Zr: 0.02-0.06%;

B: 0.01-0.05%;

C: 0.0015-0.1%;

RE: 0.05-0.18wt%;

The remainder is Ni;

Or use other non-weldable nickel-based superalloys as the matrix, and add 0.05-0.18wt% RE to the matrix;

The other non-weldable nickel-based superalloys are selected from one of IN738LC, CM247LC, CMSX-4, René 142, and Hastelloy X; or one of IN718 and IN625 nickel-based superalloys is used as the matrix, and 0.05 -0.18wt% RE;

The parameters of the 3D printing are: the laser power is 150-300W, the laser scanning rate is 500-1100mm/s, the spot diameter is 70-110μm, the laser scanning distance is 60-120μm, the powder layer thickness is 30-50μm, and the forming layer is 30-50μm thick. Rotate the laser scanning direction between 45°-90°;

The RE is selected from at least one of Sc, Y, La, Ce, and Er.
The method for eliminating 3D printing nickel-based superalloy cracks according to claim 1, wherein the nickel-based superalloy, in mass percentage, comprises the following components:

Co: 20.6%;

Cr: 13%;

Al: 3.4%;

Ti: 3.9%;

Mo: 3.8%;

W: 2.1%;

Ta: 2.4%;

Nb: 0.9%;

Zr: 0.05%;

B: 0.03%;

C: 0.04%;

RE: 0.06-0.18wt%;

The remainder is Ni.
The method for eliminating 3D printing nickel-based superalloy cracks according to claim 1, wherein: RE is Sc; or RE is a mixture of Sc and at least one of Y, La, Ce, and Er.
The method for eliminating 3D printing nickel-based superalloy cracks according to claim 1, wherein the nickel-based superalloy powder is prepared by the following steps:

Step 1: Vacuum Melting

Distribute the raw materials according to the design composition, and put the raw materials into the crucible of the atomizing pulverizing furnace, and use induction heating under the vacuum degree of less than 0.1Pa to carry out vacuum melting;

Step 2: Degassing

After the raw material is melted, vacuum degassing for 10min-20min;

Step 3: Refine

Fill the atomizing and pulverizing furnace with high-purity inert gas to 0.1-0.11MPa, and keep the molten master alloy molten in the temperature range of 1600℃～1650℃ for 10min～15min;

Step 4: Atomization

The molten mother alloy melt is flowed down through the guide tube at a flow rate of 3.5kg/min~5kg/min, and the metal liquid flow is broken into fine droplets with a high-pressure, high-purity inert gas of 3MPa~5MPa, and the droplets are cooled and cooled. Solidify, form spherical powder, and enter into the powder collection tank;

Step 5: Sieve

After the powder is fully cooled, air classification and ultrasonic vibration screening are used under the protection of inert gas to obtain spherical nickel-based superalloy powder with a medium particle size of 53-106 μm and a fine powder particle size of 15-53 μm, and vacuum-packed ;

The inert gas should be helium, argon, or a mixed gas of argon and helium, with a purity of 99.99wt%, wherein the oxygen content is less than 0.0001wt%;

The oxygen content of the obtained nickel-based superalloy powder is less than or equal to 0.0126wt%, and the sulfur content is less than or equal to 0.0056wt%.
The method for eliminating 3D printing nickel-based superalloy cracks according to claim 4, wherein the oxygen content of the nickel-based superalloy powder is less than or equal to 0.01wt%, and the sulfur content is less than or equal to 0.004wt%.
The method for eliminating 3D printing nickel-based superalloy cracks according to claim 4, wherein the fluidity of the nickel-based superalloy powder is tested for 50g/2.5mm aperture, and the result is 15-25 s. Optimized for 15.5-16 s.
A method for eliminating cracks in 3D printing nickel-based superalloys according to claim 4, wherein the 3D printing is selected area laser melting (SLM), or electron beam melting (EBM), or coaxial powder feeding laser Forming (LENS).
The method for eliminating cracks in 3D printing nickel-based superalloys according to claim 1, wherein the parameters of the 3D printing are: a laser power of 150-300W, a laser scanning rate of 500-1100mm/s, a spot diameter The thickness is 70-110 μm, the laser scanning distance is 60-120 μm, the thickness of the powder layer is 30-50 μm, and the laser scanning direction between the forming layers is rotated 45°-90°, preferably 67°.
A method for eliminating cracks in 3D printing nickel-based superalloys according to claim 1, characterized in that: after 3D printing is completed, stress relief annealing is performed at 450-650°C for 0.5-3h in a vacuum or inert gas atmosphere to obtain Parts.
The method for eliminating cracks in 3D printing nickel-based superalloys according to claim 9, wherein: the density of the workpiece is 99.3%~99.5%, the room temperature yield strength is 918~935MPa, and the tensile strength is 1120~ 1256MPa, the elongation is 12.5~14.5%.