AU718297B2 - Process for producing a ferritic stainless steel having an improved corrosion resistance, especially resistance to intergranular and pitting corrosion - Google Patents

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(ORIGINAL)

Class Int. Class Application Number: Lodged: Complete Specification Lodged: Accepted: Published: Priority Related Art:

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Name of Applicant: 104 Actual Inventor(s): 7 Jean-Michel Hauser Pascale Haudrechy Address for Service: PHILLIPS ORMONDE FITZPATRICK Patent and Trade Mark Attorneys 367 Collins Street Melbourne 3000 AUSTRALIA Invention Title: PROCESS FOR PRODUCING A FERRITIC STAINLESS STEEL HAVING AN IMPROVED CORROSION RESISTANCE, ESPECIALLY RESISTANCE TO INTERGRANULAR AND PITTING CORROSION Our Ref: 483274 POF Code: 288070/288070 The following statement is a full description of this invention, including the best method of performing it known to applicant(s): -1n0.8o -i fl Process for producing a ferritic stainless steel having an improved corrosion resistance, especially resistance to intergranular and pitting corrosion The present invention relates to a process for manufacturing a ferritic steel having an improved corrosion resistance, and especially resistance to intergranular and pitting corrosion.

Japanese Patent No. 62,250,150 (Nippon Kokan) discloses a corrosion-resistant ferritic stainless steel whose composition is as follows: carbon less than 0.04%, silicon less than manganese less than nickel less than chromium between 19 and 28%, molybdenum between 1 and nitrogen less than 0.03%, phosphorus less than 0.06% and sulphur less than 0.03%. This steel may also contain niobium and/or titanium.

That document presents a ferritic steel having a high corrosion resistance, used for withstanding a mixture of phosphoric acid, of sulphuric acid and of chlorine and fluorine ions.

Without a specific conversion, this steel remains difficult to produce. In addition, it is known that steels resistant to acid media are steels containing, in their composition, a relatively large amount of nickel.

Also known is Patent DE 3,221,087 (Thyssen) relating to the manufacture of a so-called superferritic CrMoNi stainless steel which includes conventional oxygen refining using an AOD or VOD process, continuous casting of billets or slabs, optional intermediate cooling, and annealing followed by conversion into blooms and end- or semi-finished products. The superferritic stainless steel has the following composition: carbon between 0.01 and 0.05%, silicon less than manganese less than 1%, nickel between 1 and chromium between 21 and 31%, molybdenum between 1.5 and nitrogen between 0.01 and 0.08%, phosphorus less than 0.0025%, sulphur less than 0.01%, titanium less than 0.24%, zirconium between 0.005 and aluminium between 0.002 and 0.12%, niobium between 0.1 and 0.6% and copper less than 3%.

-2- This steel may also contain calcium, magnesium, cerium and boron, and the elements of the composition satisfy the following relationships: %Cr 10x(%Mo) 6x(%Si) lying between 48 and 58; %Nb %Zr 3.5x(%AI 2x%Ti) lying between 8 and 16x(%C %N) In this document, it is specified that some of the aluminium may be replaced by doubling the amount of titanium on condition that there is at least 0.002% of aluminium.

The steel is preferably hot rolled or forged directly after continuous casting, without intermediate cooling.

10 The present invention provides a ferritic stainless steel, and a process for producing same, which overcomes, or at least alleviates, one or more disadvantages of the prior art.

An advantage of the invention is the improvement in the corrosion resistance of a ferritic steel, especially the resistance to intergranular and pitting 15 corrosion, while at the same time maintaining a conversion process compatible with the conversions of common so-called 17% chromium ferritic steels.

The subject of the invention is a process for producing a ferritic stainless steel having an improved corrosion resistance, and especially resistance to intergranular corrosion and to pitting corrosion, wherein the steel, in slab form, 0. 20 containing in its composition by weight: S' 18% chromium 27% 1% molybdenum 3% 1% nickel 3% manganese 1% silicon 1% carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 0.20% niobium 0.50% sulphur 0.01% phosphorus 0.1% RA- the balance being iron and impurities resulting from the smelting of the materials necessary for the production, is subjected, in a first phase, to cooling at a rate of

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"C C:\WINWORD\SUEMMH\SPECIES\15080-97.DOC -3between 4000C and 600°C/hour down to a temperature of 900°C and then, in the second phase, to rapid cooling at a rate of between 1200°C and 1400 0 C/h.

The other characteristics of the invention are: after hot rolling, the strip obtained is subjected to rapid cooling and then coiled at a temperature of less than 6000C and preferably at a temperature close to 5500C.

preferably, the steel, in slab form, contains in its composition by weight: 22% chromium 27% 1% molybdenum 3% 10 1% nickel 3% manganese 1% silicon 1% nos carbon 0.030% 0 .e nitrogen 0.030% 15 0.075% titanium 0.20% 0.20% niobium 0.50% sulphur 0.01% phosphorus 0.1% the steel furthermore contains, in its composition by weight, less than 0.20% of 20 copper.

the elements of the composition of the steel furthermore satisfy the following relationship: 0.07% ANb %Nb 7/4 %Ti 7(%C 0.4%.

The invention also relates to a ferritic stainless steel obtained by the process of the invention having an improved corrosion resistance, especially resistance to intergranular and pitting corrosion, having a composition by weight: 18% chromium 27% 1% molybdenum 3% 1% nickel 3% manganese 1% silicon 1% Scarbon 0.030% C:\WINWORD\SUE\MMH\SPECIES\15080-97.DOC 3a silicon 1 carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 0.20% niobium 0.50% see* 9 0~ C:WIN WORD\SUE\MMH\SPECIES\1 5080-97. DOC 4 sulphur 0.01% phosphorus 0.1% the balance being iron and impurities resulting from the smelting of the materials necessary for the production.

Preferably, the steel is characterized in its composition by weight: 22% chromium 27% 1% molybdenum 3% 1% nickel 3% 0.3% manganese 0.3% silicon carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 0.20% niobium 0.50% aluminium 0.05% sulphur 0.01% phosphorus 0.1% the balance being iron and impurities resulting from the 20 smelting of the materials necessary for the production.

The other characteristics of the invention are: the elements of the composition satisfy the following relationship: 0.07% s ANb %Nb 7/4 %Ti 7(%C s 0.4%.

25 the composition furthermore contains less than 0.20% of copper.

The description which follows, and the appended figures, all given by way of non-limiting example, will make the invention clearly understood.

Figure 1 shows three ductile-brittle transition curves for a steel of composition A (11721) according to the invention.

Figure 2 shows two ductile-brittle transition curves for a steel of composition B (11722) according to the invention.

Figure 3 shows ductile-brittle transition curves after rapid cooling of the hot-rolled steel strip.

Figure 4 shows ductile-brittle transition curves as a function of varying contents of nickel and molybdenum Figure 5 shows comparative pitting-corrosion test curves.

The invention relates to a process for producing a ferritic stainless steel having improved corrosion resistance, especially resistance to intergranular and pitting corrosion.

The group of steels having more than 18% of chromium includes steels which are difficult to convert because of the high proportion of chromium which they contain. However, the high chromium contents have the effect of increasing the corrosion resistance, compared with so-called 17% chromium ferritic steels.

Aluminium and zirconium, introduced into the composition in residual amounts, are contained in a proportion of impurities due to the production.

Copper cannot be introduced in a smaller amount since it is contained in the composition of the base materials used for production of the steel.

Molybdenum improves the resistance to generalized corrosion in acid medium and to pitting corrosion.

However, it must be limited in concentration in order to avoid problems in the area of hot fracture toughness.

Nickel improves the resistance to corrosion in acid medium, but a maximum limit is imposed since too great an amount of nickel embrittles the steel.

The steel according to the invention, in the form of slab, undergoes a particular heat treatment in order to reduce its embrittlement, especially when the steel is highly stabilized.

This is because it has been observed that uncontrolled cooling of the steel during its conversion produces embrittlement of the said steel.

According to the invention, a slab of the steel is subjected to through-cooling at a rate of between 400 and 600 0 C/hour down to a temperature of 900 0 C. Next, the slab is subjected to rapid through-cooling at a rate of between 1200 and 1400CC/hour, for example by immersing the slab in a pool until this reaches a temperature of 6 approximately 550 0

C.

Three types of cooling were tested and compared, by applying the process to a slab highly stabilized with niobium and titanium, with ANb equal to 0.33.

In the heat treatment, the slab is subjected to cooling in a pool for a period of less than 10 min.

Before entering the pool at a temperature of approximately 900C, the slab is cooled through at a rate of about 6000C/h, and then at a rate of 1300 0 C/h on going into the pool down to at least a temperature of approximately 550 0

C.

The chemical compositions of steels A (11721) and B (11722) according to the invention are given in Table 1.

S

Table 1 Chemical compositions of the steels Steels Composition S, 1 M. 1 N, 1 Cr 1 H. Cu S Al Ti MNb 10, 1

N

2

AM

Ref. 316 L. .017 .588 1.636 11.51 _17.65 2.-15 .056 .0032 .003 .004 .004 .030 Ref. F1814T .010 .351 .401 .233 17.96 2.109 .007 .0012 .041 .071 .375 19/23 .019 .296 Steel A (11721) .017 .347 .391 2.032 22.79 2.015 .011 .0017 .005 .113 .374 32/32 .018 .327 Steel B (11722) .018 .368 .397 1.98 23.00 2.021 .010 .0021 <.002 .110 .373 33/36 .017 .320 Steel C (11519) .017 .322 .405 2.05 23.08 2.02 .121 .0053 .025 .117 .440 43/42 .015 .421 Steel D (11694) .027 .307 .419 2.04 23.22 2.10 .010 .0016 .035 .049 .300 25/29 .022 .043 Steel 9 (11605) .016 .404 .406 1.99 23.12 1.94 .010 .0011 .033 .099 .352 29/36 .015 .308 Steel F (11606) .017 .313 1 .409 1.97 23.09 1.93 .009 .0019 .0481 .072 .250 27/32 .020 117 8 Figure 1 shows three ductile-brittle transition curves for steel A (11721). Curves 1 and 2 are the ductile-brittle transition characteristics of steel A, according to the invention, this steel having been rapidly cooled in the pool for 10 to 5 min, respectively.

Curve 3 shows the brittle-ductile transition characteristic of steel A, this steel not having been rapidly cooled.

Curve 2 shows a transition temperature at 140 0

C

and relatively high hot fracture toughness values at a temperature of between 190 0 C and 360*C, while without cooling, as shown by Curve 3, the steel remains brittle with a transition temperature of 296 0 C and a low hot fracture toughness, that is to say approximately 80 J/cm 2 at a temperature of 350 0

C.

*The fact of increasing the time spent in the pool o improves the fracture toughness characteristics little.

With 10 minutes spent in the pool, a transition temperature of 113 0 C and hot fracture toughness values greater 20 than only approximately 30% are obtained. In addition, the temperature of the slab on leaving the pool is lower, which can cause problems, for example when grinding the slab.

The cooling according to the invention avoids the a. 25 precipitation of embrittling intermetallic compounds of the Mo-enriched Fe 2 Nb type.

Figure 2 shows two characteristic ductile-brittle transition curves for steel B (11722) compared with a fracture toughness characteristic of steel A. It will be observed that the cooling gives a ductile-brittle transition temperature of 124 0 C and hot fracture toughness values at temperatures of between 180*C and 260 0 C of about 160 J/cm 2 These values show that steel B according to the invention has improved characteristics compared with steel A, this being explained by the fact that steel A is less stabilized. In fact, the composition of the steel A satisfies the relationship: ANb 0.32%.

According to the invention, after the slab has -9been hot rolled, the strip obtained is subjected to rapid cooling and is then coiled at a temperature of less than 600 0 C, preferably at a temperature close to 550 0

C.

Tests were carried out using steel C (11519) whose composition is given in Table 1. This steel is highly stabilized.

The fracture toughness characteristics shown in Figure 3 relating to the steel according to the invention are compared with a reference steel of the F18MT type, a 17% chromium steel, which has not undergone rapid cooling.

A very marked improvement resulting from the rapid cooling of the hot-rolled strip is observed. The transition temperature moves, from approximately 220 0

C,

to 172 0 C for rapid cooling and coiling at 600 0 C and to o o 147C for coiling at 5500C. It may be noted that Curve 1, o o:owhich represents steel C (11519) subjected to rapid o .cooling and coiling at 5500C, is similar to the characteristic of the reference steel. The same applies to 0 20 Curve 2 which represents the characteristic of steel C (11519) subjected to rapid cooling and coiling at 600*C, Curve 3 being a comparative curve of a characteristic of steel C according to the invention, but which has not been subjected to rapid cooling.

25 The heat treatment according to the invention makes it possible to obtain, for a steel containing more than 18% chromium, characteristics comparable to those of so-called 17% chromium steels. It substantially improves its fracture toughness properties, especially by lowering the ductile-brittle transition temperatures.

The carbon and nitrogen contents of the steel according to the invention are limited in order to reduce the intergranular corrosion phenomena.

It has been observed that the nickel and molybdenum contents must be limited.

Figure 4 shows a characteristic ductile-brittle transition curve of a steel C according to the invention containing 2% molybdenum and 2% nickel, this characteristic being, on the one hand, compared with that of a steel 10 of the same general composition and containing 3.2% molybdenum and 2% nickel, and, on the other hand, with that of a steel of the same general composition and containing 2% molybdenum and 4% nickel.

Comparison of these three curves shows that it is necessary, according to the invention, to limit the molybdenum and nickel contents to a value of less than 3%.

From the corrosion standpoint, it is necessary to define the minimum contents of the stabilizing elements titanium and niobium in order to ensure intergranular corrosion resistance. As previously, the relationship: ANb %Nb 7/4x%Ti 7x(%C corresponds to the excess of stabilizers after the carbides and nitrides have precipitated.

The intergranular corrosion resistance is evaluated by the Strauss test applied to specimens on which a line of TIG melting has been traced.

The tested specimens of steel D (11694) satisfy- 20 ing the relationship ANb equal to 0.043 showed no cracking.

Likewise, on more stabilized steels, such as steel E (11605) and steel F (11606) for example, it is observed that there is no disbondment after the Strauss 25 test. At greater levels of stabilization, for example ANb greater than 0.1, there is no loosening, while at the stabilization level of steel D this is observed, without thereby leading to the appearance of cracks. The value of ANb equal to 0.043 is therefore really a minimum level to ensure intergranular corrosion resistance, below which cracks will occur.

Figure 5 shows pitting corrosion characteristics on polished specimens, aged in air and then subjected to polarization with a 100 mV min' 1 scan, in a 0.5 M aqueous sodium chloride solution having a pH equal to 6.6 and a temperature of 70 0

C.

The various characteristics shown in the figure indicate that steels E and F have greater pitting corrosion resistance than steels taken as a reference, such 11 as 316 L and F 18 MT steels.

From the standpoint of crevice corrosion, steel C (11519) and steel D (11694) have been compared with a 316 L reference steel. Steel C has titanium and niobium contents higher than steel D. These elements appear to have no appreciable influence on the crevice corrosion behaviour of the steel.

This comparison was made on polished specimens, aged in air and then subjected to polarization at a potential of -750 mV/SCE for 2 min followed by holding at a floating potential for 15 min. The specimens are then subjected to a 10 mV.min' 1 scan between -750 mV/SCE and 1000 mV/SCE, the specimens being immersed in a 2 M aqueous sodium chloride solution having a pH of and The table below collates, for the steels tested, the values of the potentials and current densities corresponding to the activity peaks measured on the polarization curves in a 2M NaC1 solution.

pH 1.0 pH .I (tA/cm 2 E (mV/SCE) I (A/cm 2 E (mV/SCE) 316 L 70 -335 15 -370 SSteel C 91 -474 1.5 -340 Steel D 47 -478 1.0 -338 These results show that steel D, less stabilized than steel C from the standpoint of the titanium and niobium concentration, behaves in the same way as the said steel C. The activity peaks occur at the same potential and have a maximum intensity of the same order of magnitude.

It will be noted that the variations in the titanium and niobium contents do not alter the crevice corrosion behaviour of the steels according to the invention.

In general, a value of ANb equal to 0.040% is regarded as a minimum value in order to ensure intergran- 12 ular corrosion resistance.

As a titanium content greater than 0.075% is fixed by the requirements for pitting corrosion resistance, the minimum niobium content is therefore pref erably greater than 0.30%.

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Claims (11)

1. Process for producing a ferritic stainless steel having an improved corrosion resistance, and especially resistance to intergranular corrosion and to pitting corrosion, wherein the steel, in slab form, containing in its composition by weight: 18% chromium 27% 1% molybdenum 3% 1% nickel 3% manganese 1% silicon 1% carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 15 0.20% niobium 0.50% sulphur 0.01% phosphorus 0.1% the balance being iron and impurities resulting from the smelting of the materials necessary for the production, is subjected, in a first phase, to cooling 20 at a rate of between 4000C and 600C/hour down to a temperature of 9000C *o and then, in a second phase, to rapid cooling at a rate of between 12000C and 1400°C/h.

2. Process according to claim 1, wherein the slab is subjected to hot rolling to form a strip which is subjected to rapid cooling and then coiled at a temperature of less than 6000C and preferably at a temperature close to 5500C.

3. Process according to claim 1 or 2, wherein the steel, in slab form, contains in its composition by weight: 22% chromium 27% 1% molybdenum 3% 1% nickel 3% R A manganese 1% silicon 1% W:\mary\MMHNODEL\15080.doc -14- carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 0.20% niobium 0.50% sulphur 0.01% phosphorus 0.1%

4. Process according to any one of claims 1 to 3, wherein the steel furthermore contains, in its composition by weight, less than 0.20% of copper.

Process according to any one of claims 1 to 4, wherein the elements of the composition of the steel furthermore satisfy the following relationship: 0.07% ANb %Nb 7/4 %Ti 7(%C 0.4%. 15

6. Ferritic stainless steel obtained by the process according to any one of claims 1 to 5 having an improved corrosion resistance, especially resistance to intergranular and pitting corrosion, having a composition by weight: 18% chromium 27% 1% molybdenum 3% 20 1% nickel 3% manganese 1% silicon 1% carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 0.20% niobium 0.50% sulphur 0.01% phosphorus 0.1% the balance being iron and impurities resulting from the smelting of the materials necessary for the production.

7. Steel according to claim 6, having a composition by weight: W:\mary\MMHNODEL\15080.doc 22% chromium 27% 1% molybdenum 3% 1% nickel 3% manganese 1% silicon 1% carbon 0.030% nitrogen 0.030% 0.075% titanium 0.20% 0.20% niobium 0.50% 10 sulphur 0.01% phosphorus 0.1% the balance being iron and impurities resulting from the smelting of the materials necessary for the production. e p 5O 15

8. Steel according to claims 6 or 7, wherein the elements of the composition satisfy the following relationship: 0.07% ANb %Nb 7/4 %Ti 7(%C 0.4%.

9. Steel according to any one of claims 6 to 8, wherein the composition 20 furthermore contains less than 0.20% of copper. S

10. A process according to claim 1, substantially as herein described with I' reference to the accompanying drawings.

11. A ferritic stainless steel according to claim 6, substantially as herein described with reference to the accompanying drawings. DATED: 28 February 1999 PHILLIPS ORMONDE FITZPATRICK Attorneys for: USINOR SACILOR (SOCIETE ANONYME) C:\WINWORD\SUEMMH\SPECIES\15O8-97.DOC