US20120237389A1

US20120237389A1 - Heat-resistant austenitic steel having high resistance to stress relaxation cracking

Info

Publication number: US20120237389A1
Application number: US13/386,141
Authority: US
Inventors: Bernard Bonnefois; Amelie Fanica; Lionel Coudreuse; Tassa Oriana; Johannes Cornelis Van Wortel
Original assignee: ArcelorMittal Investigacion y Desarrollo SL; Centro Sviluppo Materiali SpA; Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek TNO
Current assignee: ArcelorMittal Investigacion y Desarrollo SL; Rina Consulting Centro Sviluppo Materiali SpA; Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek TNO
Priority date: 2009-07-22
Filing date: 2010-07-20
Publication date: 2012-09-20
Also published as: AU2010274717A1; US20230040035A1; US11884997B2; JP2012533689A; CN102482749A; EP2287351A1; JP5705847B2; EP2456901B1; AU2010274717B2; CA2768719A1; BR112012001328B1; WO2011010206A3; BR112012001328A2; UA105534C2; RU2528606C2; KR20120047260A; CA2768719C; SI2456901T1; PL2456901T3; RU2012106247A

Abstract

An austenitic steel not susceptible to relaxation cracking, with composition comprising, in percentages by weight: 0.019% ≦C ≦0.030%, 0.5% ≦Mn ≦2%, 0.1% ≦Si ≦0.75%, Al >0.25%, 18% ≦Cr ≦25%, 12% ≦Ni ≦20%, 1.5% ≦Mo ≦3%, 0.001 % <B ≦0.008%, 0.25% ≦V ≦0.35%, 0.23% ≦N ≦0.27%, the balance being iron and unavoidable impurities wherein: Ni(eq.) ≧1.11 Cr(eq.) −8.24, wherein: Cr(eq)=Cr+Mo+1.5 Si+5V+3AI+0.02, Ni(eq)=Ni+30C+x(N−0.045)+0.87 wherein: x=30 for N≦0.2, x=22 for 0.2<N≦0.25, x=20 for 0.25<N≦0.35.

Description

The invention relates to austenitic heat resistant steel and its use for the fabrication of installations such as reactor vessels, forgings and pipelines operating at temperatures above 550° C. In particular, the invention pertains to a steel which is not susceptible to stress relaxation cracking.
Various industries, such as for example chemical industry, are using heat resistant steel types for applications operating at temperatures between 550 and 900° C., often under high pressures. The main degradation mechanisms at these temperatures are creep, chemical attack/oxidation and stress relaxation cracking. The first two degradation mechanisms have been thoroughly studied and taken into account in construction codes. Materials such as AISI 304H steel (whose main alloying elements are 18-20% Cr, 8-10.5% Ni), AISI is 316H (16-18% Cr, 10-14% Ni, 2-3% Mo), 800H (19-23% Cr, 30-35% Ni) display high creep fracture strength. Under this respect, alloy 800H is favourable because it displays high fracture strength in the range 550-950° C. However, alloy 800H is expensive due to its high nickel content. In addition, the three aforementioned alloys are susceptible to stress relaxation cracking (SRC). Cracking occurs in intergranular mode, i.e. at grain boundaries. This phenomenon does not occur when susceptible alloys are subjected to thermal treatments to reduce residual stresses. It has been shown that heat treatments between 875 and 980° C. are effective to avoid SRC. However, these treatments at high temperature can hardly be performed on industrial sites. The components in the chemical industry are generally very complex and huge. It is also a cost consuming and risky procedure.
Thus, there is a need for a heat-resisting steel with high creep and oxidation resistance at high temperature, non-susceptible to stress relaxation cracking. An object of the present invention is to provide a heat resistant steel which is intrinsically not susceptible for relaxation cracking, so that extra heat treatments after manufacturing processes can be avoided.
Another object of the invention is to provide a steel composition having excellent creep and oxidation properties in the large range of temperature range of 550 up to 900° C., especially in the temperature range between 550 and 750° C.
Another object of the invention is to provide a steel composition which has high ductility at high temperature and which displays also satisfactory toughness at ambient temperature after a holding at high temperature.
A further object of the invention is to provide a steel composition with limited amount of costly elements of additions such as nickel.
As a result of numerous tests and investigations, the inventors have found that when some elements, and in particular carbon, aluminium, chromium, nickel, molybdenum, boron, vanadium, nitrogen, are present in suitable ranges in steel , the aim of the invention is attained.
The structure of the steel according to the invention is fully austenitic.
For this purpose, the subject of the invention is an austenitic steel not susceptible to relaxation cracking, with composition comprising, in percentages by weight: 0.019% ≦C ≦0.030%, 0.5% ≦Mn ≦3%, 0.1% ≦Si ≦0.75%, Al ≦0.25%, 18% ≦Cr ≦25%, 12% ≦Ni ≦20%, 1.5% ≦Mo ≦3%, 0.001% ≦B ≦0.008%, 0.25% ≦V ≦0.35%, 0.23% ≦N ≦0.27%, the balance being iron and unavoidable impurities, and wherein: Ni(eq.) ≧1.11 Cr(eq.) −8.24, wherein: Cr(eq)=Cr+Mo+1.5Si+5V+3AI+0.02, Ni(eq)=Ni+30C+x(N−0.045)+0.87 wherein: x=22 for 0.23% ≦N ≦% ≦N≦0.25%, x=20 for 0.25% <N≦0.27% According to a preferred embodiment, the steel composition comprise: 14% ≦Ni ≦17%.
Another subject of the invention is a steel product with composition above and wherein the elongation is higher than 30% at the temperature of 750° C. Another subject of the invention is a steel product with composition above wherein the lifetime under 36 MPa at 750° C. is higher than 0.5×10⁵h.
Another subject of the invention is the use of a steel product having a composition above, for the fabrication of reactor vessels, forgings and pipelines.
As regarding to steel composition, carbon is an effective element for forming fine M₂₃C₆precipitates which will increase tensile and creep strength. When the carbon content is 0.019% in weight or less, these effects are not sufficient. But when carbon content exceeds 0.030%, excessive carbides precipitation occurs and the steel becomes susceptible to SRC. Furthermore, toughness is lowered as a consequence of the increased precipitation of carbonitrides, coarse sigma phases and M₂₃C₆carbides.
Manganese is added as a deoxidizer of the molten steel. Manganese combines also with sulphur, thus improving hot workability. These effects are obtained when manganese content is higher than 0.5% in weight. When it exceeds 3%, the kinetics of formation of some undesirable phases, such as brittle sigma phase, is increased. A preferable range for manganese is 1.3-1.7%.
As manganese, silicon has also a deoxidizing effect. It enhances also oxidation resistance. Below 0.1%, these effects are not achieved. But when silicon exceeds 0.75%, steel toughness decrease. A preferable range for silicon is 0.2-0.55%.
Aluminium is a strong deoxidizing element of the molten steel. But when aluminium exceeds 0.25% in weight, precipitation of intermetallic is promoted at elevated temperatures during long holding times and toughness is decreased. The precipitation of undesirable AIN is also promoted. Thus, aluminium is maintained less than 0.25%. Preferably, the aluminium content is lower than 0.2% in order to fully avoid a precipitation of AIN.
Chromium improves oxidation resistance between 550 and 950° C. and increases strength with the formation of carbonitrides. If the chromium content is less than 18% in weight, these effects are not achieved. On the other hand, if the chromium content exceeds 25%, the formation of intermetallic phases such as brittle sigma phase is promoted. Furthermore, as chromium content increases, the nickel content has to be also increased in order to keep a fully austenitic structure, thus yielding high production costs. A preferable content range for chromium is 19-21%.
Nickel is a gammagene element ensuring the stability of the austenitic structure together with other elements such as carbon and nitrogen. Taking into account the chromium content together with the other ferrite stabilizing elements such as molybdenum, the nickel content has to be higher than 12% in order to form a stable austenitic structure. If the nickel content exceeds 20%, its effect is saturated and production cost increases unnecessarily. A preferred range for nickel is 14-17%.
Molybdenum increases the strength at elevated temperatures as well as the resistance to hot cracking. Molybdenum additions less than 1.5% are not sufficient in order to obtain the desired creep strength at high temperature. But when Mo exceeds 3%, the effect for enhancing strength is saturated, and hot workability decreases. Precipitation of sigma-phase may also occur, reducing room-temperature ductility. A preferred range for molybdenum content is 2.2 to 2.8%.
At content higher than 0.001% in weight, boron increases the creep resistance by the precipitation of fine carbonitrides or borides in the matrix and strengthens also the grain boundaries. Above 0.008%, the risk of hot cracking is increased and weldability is reduced. The most preferable range for boron is 0.003 to 0.005%.
Vanadium is an important element in the invention since it forms fine intragranular carbonitrides. Precipitation occurs also under the form of vanadium borides. These precipitates improve creep strength and toughness. These effects are optimally obtained when vanadium content is not less than 0.25% in weight. But when vanadium exceeds 0.35%, coarse carbonitrides and sigma phase tend to reduce too much the strengthening effect and the room-temperature ductility.
As carbon, nitrogen is an effective element for increasing yield, tensile and creep strengths. As a gammagene element, it contributes also to the formation of a fully austenitic structure. Less than 0.23%, nitrogen cannot form carbonitrides in a sufficient and optimum quantity for obtaining these effects. On the other hand, more than 0.27% nitrogen yields too much the formation of coarse nitrides which reduce temperature ductility and toughness. Nitrogen is also restricted together with aluminium for preventing AIN precipitation.
Apart from iron, steel of the invention may contain incidental impurities resulting from the elaboration or smelting. Among these impurities, sulphur, phosphorus and oxygen have adverse effects on ductility, either at ambient temperature or at high temperature, and on weldability. Thus, they should be restricted at quantities as low as possible. Preferably, sulphur should be lower than 0.005%, phosphorus lower than 0.030%, and oxygen lower than 0.010% in weight.
The steels according to the invention have an austenitic microstructure. Thus, no further decomposition of ferrite in brittle sigma phase is susceptible to occur at elevated temperatures. A fully austenitic structure is obtained when the “chromium equivalent” (Cr(eq)) and the “nickel equivalent” (Ni(eq)) are such as:
Ni(eq.) 1.11 Cr(eq.) −8.24, wherein:
Cr(eq)=Cr+Mo+1.5Si+5V+3AI+0.02
Ni(eq)=Ni+30C+x(N−0.045)+0.87 wherein:
x=22 for 0.23% ≦N≦0.25%
x=20 for 0.25% <N≦0.27% all the elements being expressed in weight %.
Thanks to vanadium addition, carbon and nitrogen contents, vanadium carbonitrides are present in the range of 550-950° C. These stable carbonitrides have a positive effect on creep strength without impairing SRC susceptibility.
The invention covers besides various products which can be obtained by the processes as well as their uses, such as:
Quarto hot rolled plates, and presenting a thickness included between 5 and 100 mm,
Forgings which can be used for the manufacturing of flanges or connection.
The following examples are presented as an illustration of the present invention. It should be understood, however, that the invention is not limited to the particular details in these examples.

Example

Steel compositions were elaborated, of which elements are indicated on table 1 with their compositions in weight %. Compositions of steels A and B correspond to the invention. Ingots were cast, pre-forged under the form of flat products and hot-rolled down to plates with thicknesses ranging from 15 to 40 mm. The plates were solution-annealed at 1100° C. and water-quenched. Steels with references C to I are comparative steels.

TABLE 1

Steel chemical compositions (% weight).

Steel

Other elements

Reference

C (%)

Mn (%)

Si (%)

Al (%)

Cr (%)

Ni (%)

Mo (%)

B (%)

V (%)

N (%)

(%)

Invention	A	0.023	1.44	0.26	0.005	19.87	14.61	2.49	0.0034	0.31	0.23	S: 0.0017 P:
												0.014 O: 0.007
	B	0.019	1.49	0.51	0.010	20.1	14.82	2.51	0.004	0.30	0.26	S: 0.001 P:
												0.003 O:
												O.004
Reference	C	0.02	1.51	0.49	0.005	20	11.9	—	0.0033	—	0.276	S: 0.001 P:
												0.004 O: 0.006
	D	0.02	1.5	0.52	0.29	20	13.3	2.54	0.004	—	0.25	S: 0.002 P:
												0.005 O: 0.004
	E	0.072	1.47	0.50	0.005	20.1	12.1	2.52	0.0044	—	0.267	S: 0.001 P:
												0.002 O: 0.006
	F	0.022	1.50	0.51	0.005	25.9	17.3	—	0.0037	—	0.351	S: 0.002 P:
												0.003
												O: 0.006
	G	0.06	1.04	0.53	0.23	20.6	31.3	0.16	0.0013	0.065	0.015	S: 0.005 P:
												0.012 O: 0.001
	H	0.016	1.71	0.38	0.015	17.0	12.86	2.26	0.004	0.049	0.12	S: 0.005 P:
												0.020 O: 0.002
	I	0.064	1.71	0.39	0.030	18.2	10.5	—	—	—	0.05	S: 0.005 P:
												0.035 O: 0.002

Underlined values: non conform to the invention

The following tests were performed:
Tensile tests at 750 and 850° C. in order to determine the tensile strength (TS) and the total elongation (A) An elongation higher than to 30% is desired in order to attest a good ductility at high temperature.
Charpy V tests were performed in the following condition: After thermal treatment (ageing) at 650° C. for 1000 hours, the plates were cooled down to ambient temperature and tested in such condition. Specimens were machined in the plates and tested at 20° C. on a Charpy V pendulum. A Charpy V fracture energy greater than 100 Joules is desired in order to ensure satisfactory toughness. This criterion is severe since the ageing usually corresponds to a marked toughness drop for this kind of materials.
Isocreep tests were performed for determining rupture lifetime at 750° C. under a stress level of 36 MPa, and at 850° C. under a stress level of 16 MPa. A creep rupture lifetime superior or equal to 0.5×10⁵h at 750° C. under 36 MPa is desired
Total scale thickness after 3000h at 750° C. was measured on some specimens, indicating the level of resistance to the oxidation at high temperatures.
Results of tensile, creep and Charpy V tests, scale thickness, are indicated in table 2.

TABLE 2

Results obtained on steels compositions of table 1

					Lifetime at	Lifetime at
				Charpy	750° C.	850° C.	Scale
				energy after	creep	creep	thickness
	TS at			1000 h at	stress	stress	after 750° C. -
	750° C.	TS at 850° C.	A at 750° C.	650° C.	36 MPa	16 MPa	3000 h
Alloy	(MPa)	(MPa)	(%)	(Joules)	(×10⁵h)	(×10⁵h)	(micrometers

Invention	A	n.d	n.d	50	133	n.d	n.d	50
	B	407	269	40	130	1	0.8	n.d
Reference	C	300	175	30	126	0.1	0.02	n.d
	E	370	275	50	41	1	0.7	n.d
	F	350	220	35	61	0.3	0.1	n.d
	G	270	150	40	182	1	1	150
	H	275	nd	65	166	0.25	n.d.	n.d

The susceptibility to relaxation cracking was evaluated by the following procedure: After three-point bending of at ambient temperature, full-thickness specimens were submitted to a constant strain at temperature ranging from 500 to 900° C. during 150 hours. Load variation was recorded and an eventual damage by relaxation cracking was assessed by examining polished cross sections of the specimens. Some of them showed no damage or very minor cavities: these were classified as Non-Susceptible (“NS”). On the other hand, specimens with micro- or macro-cracks and cavities reveal a susceptibility (“S”) to SRC. For the purpose of use in industrial conditions, a non-susceptibility in the range of 550 to 900° C., and particularly in the range of 550-750° C., is desired. Results of the SRC tests are indicated in table 3.

TABLE 3

Results of stress relaxation cracking tests
at different temperatures on steel compositions of Table 1.

	Alloy	500° C.	550° C.	600° C.	650° C.	700° C.	750° C.	800° C.	850° C.	900° C.

Invention	A	NS	NS	NS	NS	NS	NS	NS	NS	NS
	B	NS	NS	NS	NS	NS	NS	NS	NS	NS
Reference	C	n.d	n.d	S	S	S	n.d	n.d	n.d	n.d
	E	n.d	n.d	S	S	S	n.d	n.d	n.d	n.d
	F	n.d	n.d	S	S	S	n.d	n.d	n.d	n.d
	G	NS	NS	S	S	S	NS	NS	NS	NS
	H	NS	NS	NS	NS	NS	NS	NS	NS	NS
	I	NS	NS	S	NS	NS	NS	NS	NS	NS

S = Susceptible to SRC
NS = Non Susceptible to SRC
n.d.: Not determined

From the results above, steels according to the invention display a particular combination of properties: non susceptibility to relaxation cracking on the temperature range 500-900° C., excellent creep resistance, high ductility in a large range of temperatures. These steels display also good toughness at ambient temperature after a holding at high temperature, and limited scale thickness.
The susceptibility to hot cracking in welding for the steels according to the invention was also assessed by the following test : the surface of the plates is was melted with Gas Tungsten Arc Welding with heat inputs ranging from 4.5 up to 10.3 kJ/cm and travelling speeds ranging from 5.7 up to 24.3 cm/mn. In all cases, no cracks were detected in the remelted material and in the Heat Affected Zones. Thus, the compositions according to the invention display good resistance to hot cracking.
By comparison, the results obtained on the reference steels are as follows:
Alloy C which is a reference steel without molybdenum and vanadium, is extremely susceptible to stress relaxation cracking since macro-cracks initiate even after a relaxation time of 75 h. Furthermore, the elongation at 750° C. is not satisfactory.
Alloy D does not contain vanadium and has an excessive aluminium content, thus leading to insufficient ductility at elevated temperature.
Alloy E has excessive carbon content and does not contain vanadium. As a consequence, precipitation of carbonitrides, coarse sigma-phase and M₂₃C₆carbides occur, which cause Charpy energy reduction after 1000 h at 650° C. Furthermore, this alloy was susceptible to SRC, particularly at temperatures around 650° C.
Alloy F has excessive chromium content, but no molybdenum and no vanadium. As a consequence, intermetallic phases form and reduce Charpy toughness, and on the other hand this alloy is very susceptible to SRC.
Alloy G has excessive contents in carbon and nickel but insufficient contents in molybdenum, vanadium and nitrogen. Consequently, after treatments at 600-700° C., alloy G shows damage with SRC since macro-cracks appear. Even if the alloy H is not susceptible to SRC, its lifetime at 750° C. is less than the desired value of 0.5×10⁵h, due to its low contents in vanadium and nitrogen.
In accordance with its inadequate contents in carbon, nickel, molybdenum, boron, vanadium, nitrogen, alloy I is susceptible to SRC at 600° C.
The steels according to the invention are used with profit for the fabrication of installations such as reactor vessels, forgings and pipelines operating at temperatures above 550° C.

Claims

1. An austenitic steel not susceptible to relaxation cracking, with composition comprising, in percentages by weight:

0.019% ≦C≦0.030%

0.5% ≦Mn ≦3%

0.1≦Si ≦0.75%

AI ≦0.25%

18% ≦Cr ≦25%

12% ≦Ni ≦20%

1.5% ≦Mo ≦3%

0.001% ≦B ≦0.008%

0.25% ≦V ≦0.35%

0.23% ≦N ≦0.27%

the balance being iron and unavoidable impurities, and wherein:

Ni(eq.) ≧1.11 Cr(eq.) −8.24, wherein:

Cr(eq)=Cr+Mo+1.5Si+5V+3AI+0.02

Ni(eq)=Ni+30C+x(N−0.045)+0.87 wherein:

x=22 for 0.23% ≦N≦0.25%

x=20 for 0.25% <N≦0.27%

2. A steel according to claim 1, wherein:

14% ≦Ni ≦17%

3. A steel product with composition according to any of claim 1 or 2, wherein the elongation is higher than 30% at the temperature of 750° C.

4. A steel product with composition according to any of claims 1 to 3, wherein the lifetime under 36 MPa at 750° C. is higher than 0.5×10⁵h

5. Use of a steel product having a composition according to any of claims 1 or 2, or of steel product according to claim 3 or 4, for the fabrication of reactor vessels, forgings and pipelines