Isothermal and high retained strain forging of Ni-base superalloys

US 6,059,904 A
Filed: 05/23/1997
Issued: 05/09/2000
Est. Priority Date: 04/27/1995
Status: Expired due to Fees

First Claim

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1. A method of forging an article having a controlled grain size from a Ni-base superalloy, comprising the sequence of the steps of:

selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and

γ

'"'"' phases, wherein the γ

'"'"' phase occupies at least 40% by volume of the Ni-base superalloy;

forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°

below a γ

'"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article, wherein during the forging at the first subsolvus temperature a minimum amount of retained strain energy per unit of volume is stored;

forging the forged article at a second subsolvus temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article; and

annealing the article at an annealing temperature T_A in the range (T_S -100)≦

T_A ≦

(T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.

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Abstract

A method combining isothermal and high retained strain forging is described for Ni-base superalloys, particularly those which comprise a mixture of γ and γ'"'"' phases, and most particularly those which contain at least about 40 percent by volume of γ'"'"'. The method permits the manufacture of forged articles having a fine grain size in the range of 20 μm or less. The method comprises the selection of a fine-grained forging preform formed from a Ni-base superalloy, isothermal forging to develop the shape of the forged article, subsolvus forging to impart a sufficient level of retained strain to the forged article to promote subsequent recrystallization and avoid critical grain growth, and annealing to recrystallize the microstructure. The method permits the forging of relatively complex shapes and avoids the problem of critical grain growth. The method may also be used to produce location specific grain sizes and phase distributions within the forged article.

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28 Claims

1. A method of forging an article having a controlled grain size from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the γ
  
  '"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°
  
  below a γ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article, wherein during the forging at the first subsolvus temperature a minimum amount of retained strain energy per unit of volume is stored;
  
  forging the forged article at a second subsolvus temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article; and
  
  annealing the article at an annealing temperature T_A in the range (T_S -100)≦
  
  T_A ≦
  
  (T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
- - 2. The method of claim 1, wherein the annealing is a supersolvus annealing and the supersolvus annealing temperature is greater than the γ
    - '"'"' solvus temperature.
  - 3. The method of claim 2, further comprising the step of cooling the article to a temperature lower than the γ
    - '"'"' solvus temperature at a controlled cooling rate immediately after said supersolvus annealing.
  - 4. The method of claim 3, wherein the controlled cooling rate is in the range of about 100-600 F.°
    - /minute.
  - 5. The method of claim 2, wherein time for the supersolvus annealing is in the range of about 15 minutes to 5 hours.
  - 6. The method of claim 5, wherein a grain size in the forged article after said annealing is in the range of about 20 μ
    - m or less.
  - 7. The method of claim 1, wherein a temperature of said annealing is less than or equal to the γ
    - '"'"' solvus temperature.
  - 8. The method of claim 7, further comprising the step of cooling the article at a controlled cooling rate immediately after the step of annealing.
  - 9. The method of claim 8, wherein the controlled cooling rate is in the range of about 100-600 F.°
    - /minute.
  - 10. The method of claim 7, wherein a time for the annealing is in the range of about 8 to 168 hours.
  - 11. The method of claim 10, wherein a grain size in the forged article after said annealing is in the range of about 7-12 μ
    - m.
  - 12. The method of claim 1, wherein the second temperature is in the range of 0-600 F.°
    - below the γ
      
      '"'"' solvus temperature of the Ni-base superalloy and the second strain rate is 0.01 s^-1 or greater.

13. A method of forging an article having a controlled grain size from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the g'"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°
  
  below a g'"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article;
  
  forging the forged article at a second temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein a minimum amount of retained strain energy per unit of volume is stored during the forging steps;
  
  subsolvus annealing the article after the step of forging at a subsolvus temperature in the range of about 0-100 F.°
  
  below the solvus temperature for a time sufficient to ensure that substantially all of the forged article is at the subsolvus temperature; and
  
  supersolvus annealing the article at a supersolvus temperature in the range of about 0-100 F.°
  
  above the solvus temperature for a time sufficient to ensure that substantially all of the forged article is raised to the supersolvus temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article upon supersolvus annealing.
- View Dependent Claims (14, 15, 16, 17, 18, 19, 20, 21)
- - 14. The method of claim 13, further comprising the step of cooling the article to a temperature lower than the γ
    - '"'"' solvus temperature at a controlled cooling rate immediately after said supersolvus annealing.
  - 15. The method of claim 14, wherein the controlled cooling rate is in the range of about 100-600 F.°
    - /minute.
  - 16. The method of claim 13, wherein the forging preform comprises an extruded billet formed by hot-extruding a pre-alloyed powder comprising the Ni-base superalloy.
  - 17. The method of claim 13, wherein a time for the supersolvus annealing is in the range of about 15 minutes to 5 hours.
  - 18. The method of claim 13 wherein the forged article has a substantially uniform grain size after recrystallization.
  - 19. The method of claim 13, wherein a grain size in the forged article is in the range of about 20 μ
    - m or less.
  - 20. The method of claim 13, wherein a grain size of the forging preform is in the range of about 1-50 μ
    - m.
  - 21. The method of claim 13, wherein the second temperature is in the range of 0-600 F.°
    - below the γ
      
      '"'"' solvus temperature of the Ni-base supealloy and the second strain rate is 0.01 s^-1 or greater.

22. A method of forging articles having location specific grain size ranges from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the γ
  
  '"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first temperature in the range of about 0-100 F.°
  
  below a g'"'"' solvus temperature T_S of the Ni-base superalloy and at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article;
  
  forging the forged article at a second temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein a minimum amount of retained strain energy per unit of volume is stored during the forging steps;
  
  wherein the minimum amount of retained strain energy per unit of volume stored in the forged article during forging is equivalent to the strain energy per unit of volume that would be stored in the Ni-base superalloy compressed to about a 6% reduction in height or more at room temperature; and
  
  annealing the article at a temperature T_A in the range (T_S -100)≦
  
  T_A ≦
  
  (T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.

23. A method of forging an article having a controlled grain size ranges from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the γ
  
  '"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°
  
  below a γ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article, wherein during forging a minimum amount of retained strain energy per unit of volume is stored, where the forging at a first subsolvus temperature is superplastic forging;
  
  forging the forged article at a second subsolvus temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article; and
  
  annealing the article at an annealing temperature T_A in the range (T_S -100)≦
  
  T_A ≦
  
  (T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.

24. A method of forging an article having a controlled grain size ranges from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the g'"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°
  
  below a γ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article, where the forging at a first subsolvus temperature is superplastic forging;
  
  forging the forged article at a second temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein a minimum amount of retained strain energy per unit of volume is stored during the forging steps;
  
  subsolvus annealing the article after the step of forging at a subsolvus temperature in the range of about 0-100 F.°
  
  below the solvus temperature for a time sufficient to ensure that substantially all of the forged article is at the subsolvus temperature; and
  
  supersolvus annealing the article at a supersolvus temperature in the range of about 0-100 F.°
  
  above the solvus temperature for a time sufficient to ensure that substantially all of the forged article is raised to the annealing supersolvus temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article upon supersolvus annealing.

25. A method of forging articles having location specific grain size ranges from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the γ
  
  '"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first temperature in the range of about 0-100 F.°
  
  below a γ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy and at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article, where the forging at a first subsolvus temperature is superplastic forging;
  
  forging the forged article at a second temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein a minimum amount of retained strain energy per unit of volume is stored during the forging steps;
  
  wherein the minimum amount of retained strain energy per unit of volume stored in the forged article during forging is equivalent to the strain energy per unit of volume that would be stored in the Ni-base superalloy compressed to about a 6% reduction in height or more at room temperature; and
  
  annealing the article at a temperature T_A in the range (T_S -100)≦
  
  T_A ≦
  
  (T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.

26. A method of forging an article having a controlled grain size ranges from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the g'"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°
  
  below a γ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article, wherein during the forging at the first subsolvus temperature a minimum amount of retained strain energy per unit of volume is stored;
  
  forging the forged article at a second subsolvus temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein there is no heat treatment between the forging at a first subsolvus temperature and the forging at a second subsolvus temperature; and
  
  annealing the article at an annealing temperature T_A in the range (T_S -100)≦
  
  T_A ≦
  
  (T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.

27. A method of forging an article having a controlled grain size from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the γ
  
  '"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first subsolvus temperature in the range of about 0-100 F.°
  
  below aγ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article;
  
  forging the forged article at a second temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein a minimum amount of retained strain energy per unit of volume is stored during the forging steps, wherein there is no heat treatment between the forging at a first subsolvus temperature and the forging at a second subsolvus temperature;
  
  subsolvus annealing the article after the step of forging at an annealing subsolvus temperature in the range of about 0-100 F.°
  
  below the solvus temperature for a time sufficient to ensure that substantially all of the forged article is at the subsolvus temperature; and
  
  supersolvus annealing the article at a supersolvus temperature in the range of about 0-100 F.°
  
  above the solvus temperature for a time sufficient to ensure that substantially all of the forged article is raised to the supersolvus temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article upon supersolvus annealing.

28. A method of forging articles having location specific grain size ranges from a Ni-base superalloy, comprising the sequence of the steps of:
- selecting a forging preform formed from a Ni-base superalloy and having a microstructure comprising a mixture of γ and
  
  γ
  
  '"'"' phases, wherein the γ
  
  '"'"' phase occupies at least 40% by volume of the Ni-base superalloy;
  
  forging the forging preform at a first temperature in the range of about 0-100 F.°
  
  below a γ
  
  '"'"' solvus temperature T_S of the Ni-base superalloy and at a first strain rate of 0.01 s^-1 or less for a first time sufficient to superplastically form the forging preform into a forged article;
  
  forging the forged article at a second temperature and a second strain rate for a second time sufficient to re-form the forged article and store a minimum amount of retained strain energy per unit of volume throughout the forged article, wherein a minimum amount of retained strain energy per unit of volume is stored during the forging steps, wherein there is no heat treatment between the forging at a first subsolvus temperature and the forging at a second subsolvus temperature;
  
  wherein the minimum amount of retained strain energy per unit of volume stored in the forged article during forging is equivalent to the strain energy per unit of volume that would be stored in the Ni-base superalloy compressed to about a 6% reduction in height or more at room temperature; and
  
  annealing the article at a temperature T_A in the range (T_S -100)≦
  
  T_A ≦
  
  (T_S +100), where T_A and T_S are in Fahrenheit degrees, for a time sufficient to ensure that substantially all of the forged article is raised to the annealing temperature, wherein the minimum amount of retained strain energy per unit of volume stored during forging is sufficient to promote recrystallization throughout the forged article during said annealing.

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Current Assignee
General Electric Company
Original Assignee
General Electric Company
Inventors
Blankenship, Charles Philip Jr., Murut, Aldo Enrique, Henry, Michael Francis, Benz, Mark Gilbert
Primary Examiner(s)
PHIPPS, MARGERY S

Application Number

US08/862,448
Time in Patent Office

1,082 Days
Field of Search

148/675, 148/676, 148/677, 148/564, 419/28, 419/29, 419/32, 72/709, 72/342.5, 72/356
US Class Current

148/676
CPC Class Codes

B22F 2998/00   Supplementary information c...

B22F 3/115   by spraying molten metal, i...

B22F 3/20   by extruding

B22F 3/24   After-treatment of workpiec...

C22C 1/0433   Nickel- or cobalt-based alloys

C22F 1/10   of nickel or cobalt or allo...

Y10S 72/709   Superplastic material

Isothermal and high retained strain forging of Ni-base superalloys

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Isothermal and high retained strain forging of Ni-base superalloys

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Abstract

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