Austenitic stainless steel is disclosed herein. In the described embodiments, the austenitic stainless steel comprises 16.00 wt % of Chromium to 30.00 wt % of Chromium; 8.00 wt % of Nickel to 27.00 wt % of Nickel; no more than 7.00 wt % of Molybdenum; 0.40 wt % of Nitrogen to 0.70 wt % of Nitrogen,
Austenitic stainless steel is disclosed herein. In the described embodiments, the austenitic stainless steel comprises 16.00 wt % of Chromium to 30.00 wt % of Chromium; 8.00 wt % of Nickel to 27.00 wt % of Nickel; no more than 7.00 wt % of Molybdenum; 0.40 wt % of Nitrogen to 0.70 wt % of Nitrogen, 1.0 wt % of Manganese to 4.00 wt % of Manganese, and less than 0.10 wt % of Carbon, wherein the ratio of the Manganese to the Nitrogen is controlled to less than or equal to 10.0. Austenitic stainless steel based on specified minimum PREN (Pitting Resistance Equivalent Number) values is also disclosed. (1) PRE=wt % Cr+3.3×wt % (Mo)+16 wt % N=25 for N in range of 0.40-0.70. (2) PRE=wt % Cr+3.3×wt % (Mo+W)+16 wt % N=27 for N in range of 0.40-0.70 with W present.
대표청구항▼
1. Austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 0.40 wt % of Nitrogen to 0.70 wt % of Nit
1. Austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 0.40 wt % of Nitrogen to 0.70 wt % of Nitrogen (N), 1.0 wt % of Manganese to less than 4.00 wt % of Manganese (Mn), no more than 1.0 wt % of Niobium (Nb), less than 0.10 wt % of Carbon (C), ≦0.070 wt % Oxygen, no more than 2.00 wt % of Silicon (Si), ≧0.03 wt % of Cerium and ≦0.08 wt % of Cerium, and a balance of iron and inevitable impurity, wherein ratio of the Manganese (Mn) to the Nitrogen (N) is controlled to less than 10.0; andwherein ratio of Chromium Equivalent [Cr] to Nickel Equivalent [Ni] is determined and controlled to more than 0.40 and less than 1.05; and wherein the Chromium Equivalent is determined and controlled according to a first formula: [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)−4.99; andwherein the Nickel Equivalent is determined and controlled according to a second formula: [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+2.77;and wherein the ratio of the [Cr] equivalent divided by the [Ni] equivalent is optimized at a melting stage in order to primarily obtain an austenitic microstructure in the base stainless steel after solution heat treatment performed in the range 1100 deg C. to 1250 deg C. followed by water quenching. 2. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.030 wt % of Carbon. 3. Austenitic stainless steel base metal according to claim 1, further comprising 0.020 wt % to 0.030 wt % of Carbon. 4. Austenitic stainless steel base metal according to claim 1, further comprising no more than 2.0 wt % Mn. 5. Austenitic stainless steel base metal according to claim 1, further comprising 1.0 wt % Manganese to 2.0 wt % Manganese. 6. Austenitic stainless steel base metal according to claim 1, wherein the ratio of Manganese to the Nitrogen is controlled to less than or equal to 3.75. 7. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.030 wt % of Phosphorus. 8. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.010 wt % of Sulphur. 9. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.001 wt % of Sulphur. 10. Austenitic stainless steel base metal according to claim 1, wherein the Oxygen is ≦0.050 wt % Oxygen. 11. Austenitic stainless steel base metal according to claim 1, further comprising no more than 0.75 wt % of Silicon. 12. Austenitic stainless steel base metal according to claim 1, wherein the Silicon is ≧0.25 wt % and ≦0.75 wt % of Silicon. 13. Austenitic stainless steel base metal according to claim 1, further comprising ≧0.75 wt % Si and ≦2.00 wt % Silicon. 14. Austenitic stainless steel base metal according to claim 1, further comprising at least one element selected from Boron, Aluminium, Calcium, Magnesium, Copper, Tungsten, Vanadium, Titanium, and/or Niobium plus Tantalum. 15. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.010 wt % Boron. 16. Austenitic stainless steel base metal according to claim 1, further comprising ≧0.001 wt % Boron and ≦0.010 wt % Boron. 17. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.050 wt % Aluminium. 18. Austenitic stainless steel base metal according to claim 1, further comprising ≧0.005 wt % Aluminium and ≦0.050 wt % Aluminium. 19. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.010 wt % Calcium. 20. Austenitic stainless steel base metal according to claim 1, further comprising ≧0.001 wt % Calcium and ≦0.010 wt % Calcium. 21. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.010 wt % Magnesium. 22. Austenitic stainless steel base metal according to claim 21, further comprising ≧0.001 wt % Magnesium and ≦0.010 wt % Magnesium. 23. Austenitic stainless steel base metal according to claim 1, further comprising ≦1.50 wt % Copper. 24. Austenitic stainless steel base metal according to claim 1, further comprising ≧1.50 wt % Copper and ≦3.50 wt % Copper. 25. Austenitic stainless steel base metal according to claim 1, further comprising ≦2.00 wt % Tungsten. 26. Austenitic stainless steel base metal according to claim 1, further comprising ≧0.50 wt % Tungsten and ≦1.00 wt % Tungsten. 27. Austenitic stainless steel base metal according to claim 1, further comprising ≦0.50 wt % Vanadium. 28. Austenitic stainless steel base metal according to claim 1, further comprising ≧0.10 wt % Vanadium and ≦0.50 wt % Vanadium. 29. Austenitic stainless steel base metal according to claim 1, further comprising 0.040 wt % Carbon to less than 0.10 wt % of Carbon. 30. Austenitic stainless steel base metal according to claim 29, wherein the Carbon is ≧0.030 wt % Carbon and ≦0.08 wt % Carbon. 31. Austenitic stainless steel base metal according to claim 29, further comprising no more than 0.70 wt % Titanium. 32. Austenitic stainless steel base metal according to claim 31, wherein the Titanium is more than Ti (min); wherein Ti (min) is calculated from 4×C (min); and whereinC (min) is minimum amount of the Carbon. 33. Austenitic stainless steel base metal according to claim 30, wherein the Titanium is more than Ti (min); wherein Ti (min) is calculated from 5×C (min); and whereinC (min) is minimum amount of the Carbon. 34. Austenitic stainless steel base metal according to claim 29, wherein the Niobium is more than Nb (min); wherein Nb (min) is calculated from 8×C (min); whereinC (min) is minimum amount of the Carbon. 35. Austenitic stainless steel base metal according to claim 30, wherein the Niobium is more than Nb (min); wherein Nb (min) is calculated from 10×C (min); whereinC (min) is minimum amount of the Carbon. 36. Austenitic stainless steel base metal according to claim 34, further comprising no more than 1.0 wt % Niobium plus Tantalum and maximum of 0.10 wt % of Tantalum. 37. Austenitic stainless steel base metal according to claim 36, wherein the Niobium and Tantalum is more than Nb+Ta (min); wherein Nb+Ta (min) is calculated from 8×C (min); whereinC (min) is minimum amount of the Carbon, (with 0.10 wt % Ta max). 38. Austenitic stainless steel base metal according to claim 30, further comprising no more than 1.0 wt % Niobium plus Tantalum and maximum of 0.10 wt % of Tantalum, wherein the Niobium and Tantalum is more than Nb+Ta (min); wherein Nb+Ta (min) is calculated from 10×C (min); whereinC (min) is minimum amount of the Carbon, (with 0.10 wt % Ta max). 39. Austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 0.40 to 0.70 wt % of Nitrogen and an alloy composition having a specified Pitting Resistance Equivalent (PREN) of ≧25; wherein PREN=wt % of Chromium+(3.3×wt % of Molybdenum)+(16×wt % of Nitrogen), and wherein the alloy composition further includes 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 1.0 wt % of Manganese to less than 4.00 wt % of Manganese (Mn), no more than 1.0 wt % of Niobium (Nb), less than 0.10 wt % of Carbon (C), ≦0.070 wt % Oxygen, no more than 2.00 wt % of Silicon (Si), ≧0.03 wt % of Cerium and ≦0.08 wt % of Cerium, and a balance of iron and inevitable impurity,wherein ratio of the Manganese (Mn) to the Nitrogen (N) is controlled to less than 10.0; andwherein ratio of Chromium Equivalent [Cr] to Nickel Equivalent [Ni] is determined and controlled to more than 0.40 and less than 1.05; and wherein the Chromium Equivalent is determined and controlled according to a first formula: [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)−4.99; andwherein the Nickel Equivalent is determined and controlled according to a second formula: [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+2.77;and wherein the ratio of the [Cr] equivalent divided by the [Ni] equivalent is optimized at a melting stage in order to primarily obtain an austenitic microstructure in the base stainless steel after solution heat treatment performed in the range 1100 deg C. to 1250 deg C. followed by water quenching. 40. Austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 0.40 to 0.60 wt % of Nitrogen and an alloy composition having a specified Pitting Resistance Equivalent (PREM) of ≧25; wherein PREN=wt % of Chromium+(3.3×wt % of Molybdenum)+(16×wt % of Nitrogen) and wherein the alloy composition further includes 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 1.0 wt % of Manganese to less than 4.00 wt % of Manganese (Mn), no more than 1.0 wt % of Niobium (Nb), less than 0.10 wt % of Carbon (C), ≦0.070 wt % Oxygen, no more than 2.00 wt % of Silicon (Si), ≧0.03 wt % of Cerium and ≦0.08 wt % of Cerium, and a balance of iron and inevitable impurity,wherein ratio of the Manganese (Mn) to the Nitrogen (N) is controlled to less than 10.0; andwherein ratio of Chromium Equivalent [Cr] to Nickel Equivalent [Ni] is determined and controlled to more than 0.40 and less than 1.05; and wherein the Chromium Equivalent is determined and controlled according to a first formula: [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)−4.99; andwherein the Nickel Equivalent is determined and controlled according to a second formula: [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+2.77;and wherein the ratio of the [Cr] equivalent divided by the [Ni] equivalent is optimized at a melting stage in order to primarily obtain an austenitic microstructure in the base stainless steel after solution heat treatment performed in the range 1100 deg C. to 1250 deg C. followed by water quenching. 41. Austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 0.50 wt % to 1.00 wt % of Tungsten, 0.40 to 0.70 wt % of Nitrogen, and an alloy composition having a specified Pitting Resistance Equivalent (PRENW)≧27; wherein PRENW=wt % of Chromium+[(3.3×wt % (Molybdenum+Tungsten)]+(16×wt % Nitrogen)and wherein the alloy composition further includes 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 1.0 wt % of Manganese to less than 4.00 wt % of Manganese (Mn), no more than 1.0 wt % of Niobium (Nb), less than 0.10 wt % of Carbon (C), ≦0.070 wt % Oxygen, no more than 2.00 wt % of Silicon (Si), >0.03 wt % of Cerium and ≦0.08 wt % of Cerium, and a balance of iron and inevitable impurity,wherein ratio of the Manganese (Mn) to the Nitrogen (N) is controlled to less than 10.0; andwherein ratio of Chromium Equivalent [Cr] to Nickel Equivalent [Ni] is determined and controlled to more than 0.40 and less than 1.05; and wherein the Chromium Equivalent is determined and controlled according to a first formula: [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)−4.99; andwherein the Nickel Equivalent is determined and controlled according to a second formula: [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+2.77;and wherein the ratio of the [Cr] equivalent divided by the [Ni] equivalent is optimized at a melting stage in order to primarily obtain an austenitic microstructure in the base stainless steel after solution heat treatment performed in the range 1100 deg C. to 1250 deg C. followed by water quenching. 42. Austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 0.40 to 0.60 wt % of Nitrogen, 0.50 wt % to 1.00 wt % of Tungsten and an alloy composition having a specified Pitting Resistance Equivalent (PRENW)≧27; wherein PRENW=wt % of Chromium+[(3.3×wt % (Molybdenum+Tungsten)]+(16×wt % Nitrogen)and wherein the alloy composition further includes 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 1.0 wt % of Manganese to less than 4.00 wt % of Manganese (Mn), no more than 1.0 wt % of Niobium (Nb) and less than 0.10 wt % of Carbon (C), ≦0.070 wt % Oxygen, no more than 2.00 wt % of Silicon (Si), ≧0.03 wt % of Cerium and ≦0.08 wt % of Cerium, a balance of iron and inevitable impurity,wherein ratio of the Manganese (Mn) to the Nitrogen (N) is controlled to less than 10.0; andwherein ratio of Chromium Equivalent [Cr] to Nickel Equivalent [Ni] is determined and controlled to more than 0.40 and less than 1.05; and wherein the Chromium Equivalent is determined and controlled according to a first formula: [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)−4.99; andwherein the Nickel Equivalent is determined and controlled according to a second formula: [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+2.77;and wherein the ratio of the [Cr] equivalent divided by the [Ni] equivalent is optimized at a melting stage in order to primarily obtain an austenitic microstructure in the base stainless steel after solution heat treatment performed in the range 1100 deg C. to 1250 deg C. followed by water quenching. 43. Austenitic stainless steel base metal according to claim 1, wherein the ratio of the Chromium Equivalents to Nickel Equivalents is determined and controlled to more than 0.45 and less than 0.95. 44. Wrought steel comprising the austenitic stainless steel base metal of claim 1. 45. Cast steel comprising the austenitic stainless steel base metal of claim 1. 46. Austenitic stainless steel base metal according to claim 1, wherein [Cr] and [Ni] are further defined by: Chromium Equivalent, [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)+(0.72×wt % W)+(2.27×wt % V)+(2.20×wt % Ti)+(0.21×wt % Ta)+(2.48×wt % Al)−4.99; andNickel Equivalent, [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+(0.44% x wt % Cu)+2.77, wherein the wt % of Nb, W, V, Ti, Ta, Al and Cu are non-zero; andwhereNb=NiobiumW=Tungsten;V=Vanadium;Ti=Titanium;Ta=Tantalum;Al=Aluminium; andCu=Copper. 47. A method of manufacturing austenitic stainless steel base metal having a non-magnetic austenitic base metal microstructure comprising 16.00 wt % of Chromium to 30.00 wt % of Chromium (Cr); 8.00 wt % of Nickel to 27.00 wt % of Nickel (Ni); no more than 7.00 wt % of Molybdenum (Mo); 0.40 wt % of Nitrogen to 0.70 wt % of Nitrogen (N), 1.0 wt % of Manganese to less than 4.00 wt % of Manganese (Mn), no more than 1.0 wt % of Niobium (Nb), less than 0.10 wt % of Carbon (C), ≦0.070 wt % Oxygen, no more than 2.00 wt % of silicon, ≧0.03 wt % of Cerium and ≦0.08 wt % of Cerium, and a balance of iron and inevitable impurity, the method comprising: (i) performing solution heat treatment of a metal alloy composition at a temperature between 1100° C. and 1250° C., wherein a ratio of Chromium equivalent divided by Nickel equivalent is optimized at a melting stage in order to primarily obtain an austenitic microstructure in the base stainless steel after solution heat treatment performed in the range 1100 deg C. to 1250 deg C. followed by water quenching to form the non-magnetic austenitic stainless steel base metal microstructure;wherein, ratio of the Manganese (Mn) to the Nitrogen (N) is controlled to less than 10.0; andratio of Chromium Equivalent [Cr] to Nickel Equivalent [Ni] is determined and controlled to more than 0.40 and less than 1.05; andwherein the Chromium Equivalent is determined and controlled according to a first formula: [Cr]=(wt % Cr)+(1.5×wt % Si)+(1.4×wt % Mo)+(wt % Nb)−4.99; andwherein the Nickel Equivalent is determined and controlled according to a second formula: [Ni]=(wt % Ni)+(30×wt % C)+(0.5×wt % Mn)+((26×wt % (N−0.02))+2.77.
Rossomme Paul A. (Midland PA) Eckenrod John J. (Coraopolis PA) Kovach Curtis W. (Pittsburgh PA) Pinnow Kenneth E. (Pittsburgh PA), Austenitic stainless steel.
Dupoiron Francois (Le Creusot FRX) Gagnepain Jean-Christophe (Lyon FRX) Cozar Richard (La Fermette FRX) Mayonobe Bernard (Nevers FRX), Austenitic stainless steel having high properties.
Wegman Dwight D. (Oley PA) Wanner Edward A. (Leesport PA) Rehrer Wilson P. (Reading PA) Widge Sunil (Dryville PA), Heat, corrosion, and wear resistant steel alloy and article.
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