The present invention belongs to the technical field of heat treatment of nickel-based superalloys, and particularly relates to a vacuum solution and aging treatment process for improving high-temperature plasticity of GH4738 rings.
High-temperature alloys, also referred to as superalloys, have high strength, excellent corrosion and oxidation resistance, good fatigue property and microstructure stability, and are mainly applied in the manufacturing of important parts serving at high-temperature ends on aeroengines and gas turbines. GH4738 is a γ′-phase precipitation hardened wrought superalloy, the service temperature of which is up to 800° C. to 900° C. owing to the large amount of alloying elements such as Co, Cr, and Mo. The remarkable advantage of this superalloy is its good formability at high temperature, so it is a good candidate for the production of high-temperature components with complex shapes such as rings for combustion chambers. Superalloy rings serving under extreme conditions will subjecte to high temperature, high stress and strong vibration simultaneously, so the material is required to have excellent high-temperature plasticity. In addition, the superalloy rings will be subjected to deformation because of high temperatures in the production process. Considering the characteristics of high alloying degree, high deformation resistance, and narrow machinable area of GH4738 superalloy, improper control of process parameters can lead to the cracking of the alloy being machined and the scrapping of a workpiece. Therefore, a higher requirement is put forward for the plasticity of GH4738 superalloy at high temperature.
It should be noted that the control of the mechanical properties of the GH4738 superalloy is mainly realized by adjusting sizes and contents of precipitates such as γ′ phase and carbides, wherein the grain interior is mainly strengthened by coherent γ′ precipitates with Ni3(Al, Ti) face-centered cubic structure and the grain boundary is mainly strengthened by precipitation of the M23C6 carbides. The high-temperature plasticity of a superalloy is jointly determined by the distribution characteristics of intragranular and intergranular precipitates. In the process of superalloy machining, the distribution of the precipitated phases is often changed by controlling parameters of solution and aging treatments, so that the high-temperature plasticity of the superalloy is controlled.
There is a set of standard heat treatment process for the GH4738 superalloy. That is, after solution treatment, the alloy is quickly cooled to room temperature by oil quenching or water quenching to inhibit the precipitation and growth of strengthening phases. Then, the alloy is subjected to standard two stage aging (stabilization at 845° C. and aging at 760° C.) treatment to further optimize the distribution of the strengthening phases. However, in the actual production process of superalloy components, a vacuum solution treatment process is often adopted to prevent surface oxidation. A patent (Patent No. CN109306399A) puts forward a novel heat treatment process based on the standard heat treatment process for the GH4738 superalloy. That is, after the two stage aging treatment, a third step of 730° C. aging treatment is added to give more γ′ precipitates and carbides with smaller size and higher dispersion degree, fully strengthening the superalloy and improving the mechanical properties of GH4738 bolt products. However, not only is this heat treatment method tedious in steps and time-consuming, but also the heat treatment process is carried out in the atmospheric environment, without considering vacuum heat treatment conditions.
The cooling rate is low after vacuum solution treatment since the superalloy cannot be taken out quickly, which leads to the precipitation and an increase in the size of the intragranular γ′ phase during cooling [Li J, Ding R, Guo Q Y, et al. Effect of solution cooling rate on microstructure evolution and mechanical properties of Ni-based superalloy ATI 718Plus, Mat. Sci. Eng. A, 2021, 812: 141113.]. If the standard two stage aging treatment is still adopted in subsequent aging treatment, the size of the γ′ precipitates in the alloy matrix will be too large, leading to a low plasticity index. Therefore, after the vacuum solution temperature of the superalloy is determined, it is necessary to optimize the microstructure of the superalloy by improving the solution and aging process and develop a heat treatment process suitable for GH4738 rings with high requirements on surface quality and high-temperature plasticity. However, so far, no related heat treatment process research has been found in China yet.
The object of the present invention is to develop a vacuum solution and aging treatment process for improving high-temperature plasticity of GH4738 rings, so as to ensure that GH4738 rings have excellent high-temperature plasticity within a temperature range from 540° C. to 760° C. This process is applicable to GH4738 rings which have a high requirement on high-temperature plasticity after heat treatment.
In order to achieve the aforementioned object of the present invention, the present invention adopts the following technical solution:
The vacuum solution and aging treatment process for improving high-temperature plasticity of GH4738 rings includes the following steps:
Further, in Step 2 and Step 3, the alloy is heated to the target temperatures along with the furnaces at a rate of 5° C/min to 10° C/min.
Furthermore, in Step 2, the cooling rate of the alloy is controlled in a range from 40° C/min to 80° C/min when nitrogen is injected for cooling.
Compared with the prior art, the present invention has the beneficial technical effects:
According to the present invention, nitrogen is directly injected for cooling after vacuum solution treatment, and the cooling rate of the superalloy is controlled in a range from 40° C/min to 80° C/min during cooling. This cooling process increases the cooling rate after solution treatment, ensuring a high nucleation rate of the γ′ precipitates and the intergranular M23C6 carbides and inhibiting the precipitation and growth of the precipitate phases to a certain degree. Afterwards, the alloy is treated with the low aging temperature of 740° C. to 750° C. for 30 hours to 35 hours, promoting the uniform and sufficient precipitation of the intragranular γ′ precipitates and the intergranular M23C6 carbides after aging treatment.
The high-temperature plasticity of the superalloy ring treated by adopting this process is significantly increased, while the strength is not decreased. The elongation and area reduction of the superalloy ring stretched at 540° C. after heat treatment are 30% and 34% respectively, which are 25% and 36% higher than those before process optimization respectively. The elongation and area reduction of the superalloy ring stretched at 760° C. are 49% and 70% respectively, which are 32% and 27% higher than those before process optimization respectively.
The present invention will be further illustrated in detail with reference to the following specific examples, which are illustrative rather than limitative for the present invention. The alloys in the examples and the comparative examples are specifically GH4738 rings with sectional dimensions of 40*20 mm made from the same batch of materials, the components of which are shown in the following table.
Example 1
After being hot-wrought, the GH4738 ring was first machined to achieve the precise control of final size and remove the oxide layer formed in the process of hot working. The pretreated GH4738 ring was put into a vacuum furnace, and the furnace was vacuumized to lower than 4×10−2 Pa.
The alloy was heated to a solution temperature of 1030° C. along with the furnace at a rate of 8° C/min, with the temperature being kept for 60 minutes, and nitrogen was then injected to cool the alloy to room temperature at a rate of 50° C/min.
The alloy was heated to an aging temperature of 750° C. along with the furnace at a rate of 10° C/min, and after the temperature was kept for 35 hours, the alloy was taken out and air-cooled to room temperature.
Comparative Example 1
After being hot-wrought, the GH4738 ring was first machined to achieve the precise control of final size and remove the oxide layer formed in the process of hot working. The pretreated GH4738 ring was put into a vacuum furnace, and the furnace was vacuumized to lower than 2×10−2 Pa.
The alloy was heated to a solution temperature of 1030° C. along with the furnace at a rate of 8° C/min, with the temperature being kept for 30 minutes, and afterwards, the alloy was first cooled to 900° C. in the furnace and then to less than 80° C. at a rate of 30° C/min.
The alloy was heated to a stabilization treatment temperature of 845° C. along with the furnace at a rate of 10° C/min, and after the temperature was kept for 4 hours, the alloy was then taken out and air-cooled to room temperature; the alloy was heated to an aging treatment temperature of 760° C. along with the furnace at a rate of 10° C/min, and after the temperature was kept for 16 hours, the alloy was taken out and air-cooled to room temperature.
Example 2
After being hot-wrought, the GH4738 ring was first machined to achieve the precise control of final size and remove the oxide layer formed in the process of hot working. The pretreated GH4738 ring was put into a vacuum furnace, and the furnace was vacuumized to lower than 10−3 Pa.
The alloy was heated to a solution temperature of 1020° C. along with the furnace at a rate of 10° C/min, with the temperature being kept for 40 minutes, and nitrogen was then injected to cool the alloy to room temperature at a rate of 60° C/min.
The alloy was heated to an aging temperature of 745° C. along with the furnace at a rate of 8° C/min, and after the temperature was kept for 30 hours, the alloy was taken out and air-cooled to room temperature.
The uniformity of the microstructure is one of the main factors affecting the plasticity of a superalloy. Adjusting the uniformity of the distribution of γ′ precipitates by optimizing the parameters of the heat treatment process is an important means to increase the plasticity of the GH4738 superalloy as a γ′ precipitation hardened alloy. According to the present invention, after vacuum solution treatment, a high cooling rate is adopted to increase the nucleation rate of the γ′ precipitates, and meanwhile, the uniformly distributed γ′ precipitates is obtained by long-time treatment at a low aging temperature of 740° C. to 750° C., so that the high-temperature plasticity of the alloy is increased. Because the carbide is hard and brittle and has an incoherent relationship with the matrix, the large-sized intergranular carbides will precede to become a crack source during hot working of superalloys, and as a result, alloy plasticity is decreased. According to the present invention, by increasing the cooling rate of the superalloy ring after solution treatment, the aggregation and growth of the large-sized M23C6 carbides are prevented.
Besides the aforementioned embodiments, the present invention can also have other embodiments. All technical solutions adopting equivalent substitutions or equivalent transformation forms shall fall within the claimed protection scope of the present invention.
Number | Date | Country |
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1890395 | Jan 2007 | CN |
103103465 | May 2013 | CN |
105798539 | Jul 2016 | CN |
109306399 | Feb 2019 | CN |
110337500 | Oct 2019 | CN |
111069496 | Apr 2020 | CN |
112593170 | Apr 2021 | CN |
2000064005 | Feb 2000 | JP |
2015193870 | Nov 2015 | JP |
Entry |
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Li Ning, et al., The Effect of Different Cooling Speeds after Solution Treatment on the Microstructure and Properties of GH4141 Alloy, Proceedings of the 13th China Superalloy Annual Conference, pp. 46-49. |
Jun Li, et al., Effect of solution cooling rate on microstructure evolution and mechanical properties of Ni-based superalloy ATI 718Plus, Materials Science & Engineering A, 2021, pp. 1-13, vol. 812, 141113. |