技术问题technical problem
本发明提出一种消除3D打印镍基高温合金裂纹的方法,针对γ′相沉淀强化镍基高温合金3D打印易产生裂纹问题,首次提出通过适量稀土进行稀土微合金化,降低γ′相沉淀强化镍基高温合金3D打印开裂敏感性,扩宽γ′相沉淀强化镍基高温合金3D打印工艺窗口,抑制3D打印以及后续热处理裂纹的产生,大幅提高成形件的强度和塑性。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.
技术解决方案technical solutions
本发明一种消除3D打印镍基高温合金裂纹的方法,所述致密镍基高温合金是以镍基高温合金粉末为原料,通过3D打印制备;所述镍基高温合金以质量百分比计,包括下述组分。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%。Co: 14-23%.
Cr:11-15%。Cr: 11-15%.
Al:2-5%。Al: 2-5%.
Ti:3-6%。Ti: 3-6%.
Mo:2.7-5%。Mo: 2.7-5%.
W:0.5-3%。W: 0.5-3%.
Ta:0.5-4%。Ta: 0.5-4%.
Nb:0.25-3%。Nb: 0.25-3%.
Zr:0.02-0.06%。Zr: 0.02-0.06%.
B:0.01-0.05%。B: 0.01-0.05%.
C:0.0015-0.1%。C: 0.0015-0.1%.
RE:0.05-0.18wt%。RE: 0.05-0.18wt%.
或以其他不可焊镍基高温合金为基体,向基体中加入0.05-0.18wt%的RE。Or use other non-weldable nickel-based superalloys as the matrix, and add 0.05-0.18wt% RE into the matrix.
所述其他不可焊镍基高温合金选自IN738LC、CM247LC、CMSX-4、René 142、Hastelloy X中的一种;或以IN718、IN625镍基高温合金中的一种为基体,向基体中加入0.05-0.18wt%的RE。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.
所述3D打印的参数为:激光功率为150~300W,激光扫描速率500~1100mm/s,光斑直径为70~110μm,激光扫描间距60~120μm,铺粉层厚为30~50μm,成形层之间的激光扫描方向旋转45°-90°,优选为67°。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°.
所述RE选自Sc、Y、La、Ce、Er中的至少一种。The RE is selected from at least one of Sc, Y, La, Ce, and Er.
本发明一种消除3D打印镍基高温合金裂纹的方法,所述镍基高温合金以质量百分比计,包括下述组分μm。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%。Co: 20.6%.
Cr:13%。Cr: 13%.
Al:3.4%。Al: 3.4%.
Ti:3.9%。Ti: 3.9%.
Mo:3.8%。Mo: 3.8%.
W:2.1%。W: 2.1%.
Ta:2.4%。Ta: 2.4%.
Nb:0.9%。Nb: 0.9%.
Zr:0.05%。Zr: 0.05%.
B:0.03%。B: 0.03%.
C:0.04%。C: 0.04%.
RE:0.06-0.18wt%。RE: 0.06-0.18wt%.
余量为Ni。The remainder is Ni.
本发明一种消除3D打印镍基高温合金裂纹的方法,RE为Sc;或RE为Sc与Y、La、Ce、Er中至少一种的混合。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.
本发明一种消除3D打印镍基高温合金裂纹的方法,所述镍基高温合金粉末通过以下步骤制备。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.
步骤一:真空熔炼。Step 1: Vacuum smelting.
按照设计组分配取原料,并将原料装入雾化制粉炉的坩埚内,在低于0.1Pa的真空度下采用感应加热,进行真空熔炼。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.
步骤二:脱气。Step 2: Degassing.
原料熔化后,真空脱气10min~20min。After the raw materials are melted, vacuum degassing is performed for 10 to 20 minutes.
步骤三:精炼。Step 3: Refinement.
向雾化制粉炉内充入高纯惰性气体至0.1-0.11MPa,将熔融的母合金熔液在1600℃~1650℃温度范围内保温10min~15min。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.
步骤四:雾化。Step 4: Atomization.
将熔融的母合金熔液以3.5kg/min~5kg/min的流速经导流管流下,用3MPa~5MPa的高压、高纯惰性气体将金属液流破碎成细小液滴,液滴经过冷却和凝固,形成球形粉末,进入粉末收集罐中。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.
步骤五:筛分。Step 5: Sieve.
粉末经充分冷却后,在惰性气体保护下使用气流分级和超声震动筛分,得到中粉粒径为53~106μm,细粉粒径为15~53μm的球形镍基高温合金粉末,并进行真空封装。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 .
所述的惰性气体应为氦气、氩气,或氩、氦混合气体,纯度为99.99wt%,其中氧含量小于0.0001wt%。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 %.
所得镍基高温合金粉末的氧含量小于等于0.0126wt%,硫含量小于等于0.0056wt%。在工业上应用时,还可以采用等离子旋转电极雾化法制备镍基高温合金粉末。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.
本发明一种消除3D打印镍基高温合金裂纹的方法,所述镍基高温合金粉末的氧含量小于等于0.01wt%,硫含量小于等于0.004wt%。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%.
本发明一种消除3D打印镍基高温合金裂纹的方法,所述镍基高温合金粉末经50g/2.5mm孔径测试流动性,其结果为15-25 s。经优化后可为15.5-16
s。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.
本发明一种消除3D打印镍基高温合金裂纹的方法,所述3D打印为选区激光熔融(SLM),或电子束熔化(EBM),或同轴送粉激光成形(LENS)中的一种。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).
本发明一种消除3D打印镍基高温合金裂纹的方法,所述3D打印的参数为:激光功率为150~300W,激光扫描速率500~1100mm/s,光斑直径为70~110μm,激光扫描间距60~120μm,铺粉层厚为30~50μm,成形层之间的激光扫描方向旋转45°~90°,优选为67°。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°.
本发明一种消除3D打印镍基高温合金裂纹的方法,3D打印完成后,在真空或惰性气体气氛中进行450~650℃保温0.5~3h去应力退火,得到制件。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.
本发明一种消除3D打印镍基高温合金裂纹的方法,制件的致密度为99.3%~99.5%,室温屈服强度为918~935MPa,抗拉强度为1120~1256MPa,伸长率为12.5~14.5%。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 %.
本发明一种消除3D打印镍基高温合金裂纹的方法,所制备的合金粉末为成分均匀的过饱和固溶体合金粉末。该合金粉末采用雾化快速凝固制备,所添加的元素可以超出平衡固溶极限,形成过饱和固溶体;无合金元素偏析。采用该合金粉末进行3D打印快速凝固成形的制件,具有细小树枝晶组织,元素偏析被限制在亚微米级。微量稀土元素抑制了低熔点相的形成,消除了B、Zr等形成的低熔点化合物,缩小凝固温度范围,降低了γ′相沉淀强化镍基高温合金开裂敏感性,从而抑制了3D打印裂纹形成。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 .
有益效果beneficial effect
(1)本发明针对高Al、Ti含量的γ′相沉淀强化镍基高温合金,焊接性能差,在3D打印过程中容易开裂的问题,通过适量稀土进行稀土微合金化结合3D打印参数优化,降低了γ′相沉淀强化镍基高温合金开裂敏感性,消除3D打印裂纹,大幅提高成形件的强度和塑性。(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)本发明通过添加微量Sc、Y、La、Ce、Er或混合添加,随后采用惰性气体雾化或等离子旋转电极雾化快速凝固制备过饱和固溶体高温合金粉末,所得粉末球形度高,粒度分布范围窄,同时氧、硫等杂质元素显著降低,适用于3D打印技术。(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)本发明降低了γ′相沉淀强化镍基高温合金在3D打印快速熔化、凝固过程中的开裂敏感性,扩宽γ′相沉淀强化镍基高温合金3D打印工艺窗口。(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)本发明通过稀土微合金化和参数优化的协同作用,既保证了3D打印制件质量,也控制了3D打印过程中残余应力的产生和积累,有效抑制了3D打印过程中裂纹的产生。(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)本发明通过惰性气体雾化或者等离子旋转电极雾化制粉和3D打印快速成形,使元素偏析被限制亚微米级,提高了成分和组织均匀性。(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)本发明的制备方法减少了粉末和3D打印制件的成分偏析,大大减小了3D打印热应力积累,抑制了凝固裂纹与变形的产生,提高了制件的质量与力学性能。(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)本发明通过适量稀土进行稀土微合金化,消除γ′相沉淀强化镍基高温合金3D打印裂纹,大幅提高成形件的强度和塑性,有效预防工序间存放开裂、后续热处理开裂等后续加工过程中裂纹的形成。(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)本发明有效消除了高Al、Ti含量的γ′相沉淀强化镍基高温合金3D打印裂纹,使用本方法制备的γ′相沉淀强化镍基高温合金René104,成形件内未见裂纹,致密度超过99.4%,其室温屈服强度和抗拉强度分别达到了935MPa和1256MPa,伸长率超过14.0%。(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%.
综上所述,本发明针对高Al、Ti含量的γ′相沉淀强化镍基高温合金,焊接性能差,3D打印过程中容易开裂的问题,通过添加适量的稀土Sc、Y、La、Ce、Er或混合添加进行微合金化,随后采用惰性气体雾化或者等离子旋转电极雾化快速凝固制备过饱和固溶体高温合金粉末,降低γ′相沉淀强化镍基高温合金3D打印开裂敏感性,扩宽γ′相沉淀强化镍基高温合金3D打印工艺窗口,结合参数优化消除3D打印γ′相沉淀强化镍基高温合金裂纹,大幅提高成形件的强度和塑性,并有效预防工序间存放开裂、后续热处理开裂等后续加工过程中裂纹的形成。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.
本发明的实施方式Embodiments of the present invention
下面结合附图和具体实施例,对本发明做进一步的阐述。The present invention will be further elaborated below with reference to the accompanying drawings and specific embodiments.
实施例一。Example 1.
将本发明方法用于下述René104镍基高温合金,添加质量分数为0.08%稀土Sc元素,该合金重量百分比为。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~余量为Ni,配制该合金的母合金后采用氩气雾化快速凝固制粉,通过气流分级和超声振动筛粉筛出15~53μm的合金粉末。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.
将本发明用于SLM成形René104镍基高温合金,首先将筛分后的René104镍基高温合金粉末在120℃的真空干燥箱中烘干4h,基板加热到170℃后,将经烘干的粉末装入供粉缸并进行铺粉,往工作腔内通入氩气或氮气至氧含量低于100ppm。之后进入打印程序,不断重复铺粉、激光扫描粉末的步骤,直到打印完成,得到René104镍基高温合金块体。随后对打印好的块体连同基板在真空气氛中进行450℃保温3h的去应力退火。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.
经优化后的SLM工艺参数为:激光光斑直径70μm,激光功率250W,激光扫描速率900mm/s,激光扫描间距90μm,铺粉层厚为40μm,采用条带扫描策略,逐层之间的激光扫描方向旋转67°,成形策略如图1所示。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.
图2结果表明,打印成形件没有观察到裂纹。The results in Figure 2 show that no cracks were observed in the printed parts.
所制备样品的致密度为99.44%,屈服强度和抗拉强度分别为918MPa、1236MPa,伸长率为14.0%。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%.
实施例二。Example two.
将本发明方法用于下述René104镍基高温合金,添加质量分数为0.12%稀土Y元素,该合金重量百分比为。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~余量为Ni,配制该合金的母合金后采用氦气雾化快速凝固制粉,通过气流分级和超声振动筛粉筛出15~53μm的合金粉末。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.
将本发明用于SLM成形René104镍基高温合金,首先将筛分后的René104镍基高温合金粉末在120℃的真空干燥箱中烘干4h,基板加热到170℃后,将经烘干的粉末装入供粉缸并进行铺粉,往工作腔内通入氩气或氮气至氧含量低于100ppm。之后进入打印程序,不断重复铺粉、激光扫描粉末的步骤,直到打印完成,得到René104镍基高温合金块体。随后对打印好的块体连同基板在氩气中进行500℃保温2h的去应力退火。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.
经优化后的SLM工艺参数为:激光光斑直径70μm,激光功率250W,激光扫描速率900mm/s,激光扫描间距90μm,铺粉层厚为40μm,采用条带扫描策略,逐层之间的激光扫描方向旋转67°,成形策略如图1所示。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.
图3结果表明,打印成形件没有观察到裂纹。The results in Figure 3 show that no cracks were observed in the printed parts.
所制备样品的致密度为99.39%,屈服强度和抗拉强度分别为930MPa、1224MPa,伸长率为12.8%。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%.
实施例三。Example three.
将本发明方法用于下述René104镍基高温合金,添加质量分数为0.06%稀土Sc元素和0.08%稀土Y元素,该合金重量百分比为。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~余量为Ni,配制该合金的母合金后采用氩气雾化快速凝固制粉,通过气流分级和超声振动筛粉筛出15~53μm的合金粉末。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.
将本发明用于SLM成形René104镍基高温合金,首先将筛分后的René104镍基高温合金粉末在120℃的真空干燥箱中烘干4h,基板加热到170℃后,将经烘干的粉末装入供粉缸并进行铺粉,往工作腔内通入氩气或氮气至氧含量低于100ppm。之后进入打印程序,不断重复铺粉、激光扫描粉末的步骤,直到打印完成,得到René104镍基高温合金块体。随后对打印好的块体连同基板在真空气氛中进行450℃保温3h的去应力退火。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.
经优化后的SLM工艺参数为:激光光斑直径70μm,激光功率250W,激光扫描速率900mm/s,激光扫描间距90μm,铺粉层厚为40μm,采用条带扫描策略,逐层之间的激光扫描方向旋转67°,成形策略如图1所示。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.
图4结果表明,打印成形件没有观察到裂纹。The results in Figure 4 show that no cracks were observed in the printed parts.
所制备样品的致密度为99.46%,屈服强度和抗拉强度分别为935MPa、1256MPa,伸长率为14.3%。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%.
实施例四。Example four.
以实施例一制备的合金粉末为原料,采用中国专利(CN108941560A)实施例一中采用的3D打印工艺参数制备René104合金块体。SLM工艺具体参数为。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:
激光功率为250W,光斑直径为0.12mm,扫描速度为500mm/s,扫描间距为0.12mm,铺粉层厚为0.03mm。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.
SLM所用扫描策略为条带扫描策略,如图1所示为条带扫描策略示意图,采用由下至上逐层扫描的方式,相邻层之间的激光扫描方向旋转67°,条带大小为7mm,条带间的搭接为0.11mm,目的是减少打印过程中残余应力的叠加。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.
图5为René104合金的微观结构SEM照片,成形件结构致密,没有观察到裂纹。经检测,所制备的René104合金的致密度为99.32%,优于中国专利(CN108941560A)实施例一采用SLM制备得到的致密度为99.18%的成形件;室温屈服强度为926MPa,抗拉强度为1242MPa,伸长率为14.2%。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%.
对上述成型件,采用中国专利(CN108941560A)实施例一相同的去应力退火和SPS处理。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.
去应力退火参数为:温度420℃,保温90min,然后随炉冷却。The parameters of stress relief annealing are as follows: temperature is 420°C, holding time is 90min, and then cooling with the furnace.
放电等离子烧结参数为:直径为40mm的石墨磨具,升温速率为60℃/min,降温速率为60℃/min,烧结压力45MPa,烧结温度1020℃,保温时间15min。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.
经检测,最终所制备的René104合金的致密度为99.62%,室温屈服强度为1038MPa,抗拉强度为1394MPa,伸长率为14.5%,优于中国专利(CN108941560A)实施例一采用SLM制备、并采用去应力退火消除残余应力和SPS消除裂纹制备的成形件的力学性能。所述中国专利(CN108941560A)实施例一制备的成形件的室温力学性能分别为987MPa和1376MPa。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.
实施例五。Example five.
以实施例一制备的合金粉末为原料,采用中国专利(CN108941560B)对比例一中采用的3D打印工艺参数制备René104合金块体。SLM工艺具体参数为。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:
激光功率为225W,光斑直径为0.12mm,扫描速度为600mm/s,扫描间距为0.11mm,铺粉层厚为0.03mm。(不采用分区策略)。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).
图6为René104合金的微观结构SEM照片,所制备样品的结构致密,没有观察到裂纹。经检测,所制备的René104合金的致密度为99.2%,室温屈服强度为913MPa,抗拉强度为1247MPa,伸长率为13.3%。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%.
中国专利(CN108941560B)对比例一的打印成形件,经后处理(去应力退火+SPS)前和后处理(去应力退火+SPS)后的致密度分别为98.12%和99.02%,室温力学性能分别为751MPa和916MPa。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.
对比中国专利(CN108941560B)对比例一的致密度、力学性能,本发明采用中国专利(CN108941560B)中,开裂最严重、制件性能最差的对比例一的3D打印工艺参数,也可以制备出高质量、无裂纹,且力学性能优异制件。表明本发明所制备的合金及粉末,可扩宽3D打印工艺窗口。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.
对比例一。Comparative Example 1.
将本发明方法用于下述René104镍基高温合金,添加质量分数为0.08%稀土Sc元素,该合金重量百分比为。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~余量为Ni,配制该合金的母合金后采用氩气雾化快速凝固制粉,通过气流分级和超声振动筛粉筛出15~53μm的合金粉末。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.
将本发明用于SLM成形René104镍基高温合金首先将筛分后的René104镍基高温合金粉末在120℃的真空干燥箱中烘干4h,基板加热到170℃后,将经烘干的粉末装入供粉缸并进行铺粉,往工作腔内通入氩气或氮气至氧含量低于100ppm。之后进入打印程序,不断重复铺粉、激光扫描粉末的步骤,直到打印完成,得到René104镍基高温合金块体。随后对打印好的块体连同基板在真空气氛中进行450℃保温3h的去应力退火。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.
未经优化后的SLM工艺参数为:激光光斑直径70μm,激光功率400W,激光扫描速率1200mm/s,激光扫描间距90μm,铺粉层厚为30μm,采用条带扫描策略,逐层之间的激光扫描方向旋转67°,成形策略如图1所示。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.
图7结果表明,打印成形件可以观察到少量裂纹,裂纹长度为150μm左右,裂纹密度为1.4±0.5 mm/mm
2。
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 .
所制备样品的致密度为90.12%,屈服强度和抗拉强度分别为893MPa、1085MPa,伸长率为10.4%。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%.
对比例二。Comparative example two.
将本发明方法用于下述René104镍基高温合金,不添加稀土元素,该合金重量百分比为。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~余量为Ni,配制该合金的母合金后采用氩气雾化快速凝固制粉,通过气流分级和超声振动筛粉筛出15~53μm的合金粉末。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.
将本发明用于SLM成形René104镍基高温合金,首先将筛分后的René104镍基高温合金粉末在120℃的真空干燥箱中烘干4h,基板加热到170℃后,将经烘干的粉末装入供粉缸并进行铺粉,往工作腔内通入氩气或氮气至氧含量低于100ppm。之后进入打印程序,不断重复铺粉、激光扫描粉末的步骤,直到打印完成,得到René104镍基高温合金块体。随后对打印好的块体连同基板在真空气氛中进行450℃保温3h的去应力退火。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.
经优化后的SLM工艺参数为:激光光斑直径70μm,激光功率250W,激光扫描速率900mm/s,激光扫描间距90μm,铺粉层厚为40μm,采用条带扫描策略,逐层之间的激光扫描方向旋转67°,成形策略如图1所示。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.
图8结果表明,打印成形件可以观察到较多裂纹,裂纹长度为300μm,裂纹密度为2.5±0.6 mm/mm
2。
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 .
所制备样品的致密度为98.9%,屈服强度和抗拉强度分别为786MPa、918MPa,伸长率为3.9%。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%.
对比例三。Comparative example three.
将本发明方法用于下述René104镍基高温合金,不添加稀土元素,该合金重量百分比为。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~余量为Ni,配制该合金的母合金后采用氩气雾化快速凝固制粉,通过气流分级和超声振动筛粉筛出15~53μm的合金粉末。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.
将本发明用于SLM成形René104镍基高温合金,首先将筛分后的René104镍基高温合金粉末在120℃的真空干燥箱中烘干4h,基板加热到170℃后,将经烘干的粉末装入供粉缸并进行铺粉,往工作腔内通入氩气或氮气至氧含量低于100ppm。之后进入打印程序,不断重复铺粉、激光扫描粉末的步骤,直到打印完成,得到René104镍基高温合金块体。随后对打印好的块体连同基板在氩气气氛中进行450℃保温3h的去应力退火。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.
未经优化后的SLM工艺参数为:激光光斑直径70μm,激光功率400W,激光扫描速率1200mm/s,激光扫描间距90μm,铺粉层厚为30μm,采用条带扫描策略,逐层之间的激光扫描方向旋转67°,成形策略如图1所示。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.
图9结果表明,打印成形件可以观察到明显裂纹,裂纹长度接近500μm,裂纹密度为3.7±0.8 mm/mm
2。
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 .
所制备样品的致密度为98.9%,屈服强度和抗拉强度分别为708MPa、875MPa,伸长率为2.6%。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%.