KR20030011628A - Austenic stainless steel for deformation followed by manufacturing - Google Patents

Abstract

PURPOSE: An austenitic stainless steel for cold forming suitable for later machining exhibiting improved mechanical properties over standard austenitic stainless steels in which these properties are very valuable for cold working applications, particularly cold heading is provided. CONSTITUTION: The austenitic stainless steel for cold working suitable for later machining has a composition by weight comprising carbon<0.030%, 0.3%<silicon<1%, 5%<manganese<9%, 4.55%<nickel<7%, 15%<chromium<18%, molybdenum<0.8%, 2%<copper<4%, 0.02%<nitrogen<0.060%, sulfur<0.01% and phosphorus<0.030%, wherein the composition also comprises 50x10¬-4% of boron, wherein the Md30 index, defined by the formula: Md30=551-462(C%+N%)-9.2Si%-20Mn%-13.7Cr%-29Ni%-29Cu%-18.5Mo%, is -60 or less, and wherein the ferrite rate after reheating of the raw solidification structure to 1,240 deg.C. is 10% or less, as per the following formula: % Ferrite=0.034x¬2+0.284x-0.347, where x=6.903 £Creq-Nieq/1.029-6.998|, with Creq=Cr% and Nieq=Ni%+20.04C%+21.31N%+0.46Cu%+0.08Mn%.

Description

Austenic stainless steel for deformation followed by manufacturing}

The present invention relates to austenitic stainless steels suitable for deformation at low temperatures (cold polishing type). Stainless steel contains at least 11% chromium and is highly resistant to corrosion. In addition, austenitic stainless steel contains nickel, which provides stainless steel suitable for deformation at work, especially at low temperatures.

One of the most used austenitic steels is weight percent such as C <0.08, Si <1%, Mn <2%, S <03%, P <0.045%, 18 <Cr20%, 8 <Ni <12% It is a steel having a composition of. This steel is suitable for deformation at low temperatures but requires a relatively high cold rolling coefficient. This steel has its limitations in the field of deformation, which must exhibit high reinforcement due to martensite formation.

Another austenitic stainless steel is well known, with the following configurations: C <0.12%, Si <1%, Mn <2%, S <0.03%, P <0.045%, 17 <Cr <19 %, 10 <Ni <13%. This steel offers a solution to the problem of cold rolling due to its relatively high nickel content, thereby reducing the formation of martensite in cold rolling. However, the presence of nickel also limits the extensibility of the steel, and the high content of nickel makes it expensive.

An alternative to the steel is steel with copper in its components. Copper, like nickel, plays a role in limiting the formation of martensite in cold rolling. However, there is a high limit for the use of copper, which is 3.5% and should not exceed this limit. This is to avoid overheating phenomenon when rolling at high temperature of steel. However, through the high content of copper, it is possible to obtain properties suitable for deformation, and also to reduce the nickel content to around 8%. This configuration of steel is particularly used when forging at low temperatures for long articles of stainless steel.

A more well-known concept for better treatment of austenitic stainless steels at low temperatures is the addition of manganese to the components of the steel, where manganese exhibits properties such as nickel and copper. Several documents suggest this type of solution. For example,

French patent FR 2229776 shows steel with the following constituents: 3 <Ni <15%, 6% <Mn <16%, 10% <Cr <25%, Si> 2%. The characteristic of this steel is its resistance to abrasion.

US Pat. No. 3,910,788 shows steel with the following constituents: 1% <Si <2.5%, 1.5% <Mn <5%, 1% <Cu <4%, 6% <Ni <9%, 15% <Cr <19%, N <0.03%, C + N <0.04%.

This steel is suitable for deformation at low temperatures and also for the mold work of flat steel products. The steel also resists subsequent breaks. This steel contains slightly higher levels of nickel and also contains some silicon. This increases the cold rolling rate of the steel.

Japanese documents J 63060051 and J 63060050 both propose steels with the following constituents: C <0.15%, Si <1.5%, 0.5% <Mn <6%, 17% <Cr <23%, 10% <Ni <15%, 0.1% <Cu <3%, 0.02% <N <0.35%. This steel is stabilized with Ti + Nb + V elements.

The high content of carbon and nitrogen leads to rapid high strength at deformation at low temperatures, a significant deficiency in the field of forging at low temperatures.

US document 3753693 shows steel with the following constituents: 17 <Cr <19%, 7% <Ni <10%, 11% <Mn <13%, 0.01% <N <0.07%, C <0.06%, Si <1%, Mo <2%, Cu <1.5%.

These components are particularly proposed for forging at low temperatures, and at low temperatures, they exhibit weak cold rolling rates due to the extremely high content of nickel and manganese.

These components may have high efficiency in terms of forging, but they do not show advantages in terms of economics because of the high content of nickel and chromium.

Japanese document JP 55031173 proposes steels which show only slight differences in the following components: C <0.02%, 0.04% <N <0.1%, 2.5% <Cu <4%, 6% <Ni <8 %, 17% <Cr <19%, 3% <Mn <4%, S <0.003%.

According to this document, the nickel content is relatively increased and the nitrogen content is greatly increased. These steels are used to make rivets or screws made of stainless steel.

US document US 4911883 relates to stainless steel for deformation at low temperatures, the composition of which is as follows: C <0.04%, Si <0.6%, 6% <Ni <8%, 2.2% <Mn <3.8 %, 17% <Cr <19%, 2.5% <Cu <4%, S <0.002%, N <0.010%.

This configuration is similar to that cited in the above Japanese literature, especially for a somewhat high nickel content.

International patent WO 00/26428 deals with steel of the following components: 0.025% <C <0.15%, 4% <Mn <12%, Si <1%, P <0.2%, S <0.1%, 15.5% <Cr <17.5%, 1% <Ni <4%, 0.25% <Mo <1.5%, 1.5% <Cu <4%, W <1%, Co <1%, 0.05% <N <0.3%. At this time, the relationship of Cr% + Mo% <17.75% and Cr% + 3.3Mo% + 13N%> 20.5% should be respected. These components exhibit low Ni content.

In the same field, 0.05% <C <0.5%, 6% <Mn <15%, Si <0.5%, S <0.03%, 10% <Cr <20%, 0.04% <Ni <0.3%, Mo <3 Also known is Japanese Patent JP 2001011579A, which represents the constituents of%, Cu <3%, Al <0.1%, 0.05% <N <0.3%, in which case the proportions of nitrogen and carbon are relatively high, as in the preceding literature. Indicates.

In summary, the proposed methods for obtaining the components of austenitic stainless steels suitable for deformation at low temperatures, including manganese, can be classified as follows.

Methods that show significant similarity to one another for a specific application;

Relatively similar methods with high mechanical properties and containing nitrogen and / or carbon

Relatively less similar methods that exhibit high nickel levels, ie relatively low manganese levels. This method is not a significant improvement over traditional methods in terms of use characteristics or cost savings.

The present invention relates to austenitic stainless steels that can be machined after deformation at low temperatures, in particular carbon <0.030%, 0.3% <silicon <1%, 5% <manganese <9%, 4.55% <nickel <7%, 15% <chromium <18%, molybdenum <0.8%, 2% <copper <4%, 0.02% <nitrogen <0.060%, sulfur <0.01%, phosphorus <0.030% .

Still other features of the present invention are as follows.

Boron content of 50.10 ^-4 % or less.

Md30 = 551-462 (C% + N%)-9.2 Si%-20 Mn%-13.7 Cr%-29 Ni%-29 Cu%-18.5 Mo% .

Ferrite ratio after reheating solidification infrastructure at 1240 ° C is less than 10%. At this time, the following relationship must be satisfied. : Ferrite% = 0.034 x ² + 0.284 x-0.347, of which x = 6.903 [Cr _eq -Ni _eq / 1.029-6.998], Cr _eq = Cr%, Ni _eq = Ni% + 20.04 C% + 21.31 N % + 0.46 Cu% + 0.08 Mn%.

The following description, indicated in a non-limiting manner, will aid in understanding the present invention. The present invention deals with austenitic stainless steels which can be processed after deformation at low temperatures, in particular carbon <0.030%, 0.3% <silicon <1%, 5% <manganese <9%, 4.55% <nickel <7%, 15% <chromium <18%, molybdenum <0.8%, 2% <copper <4%, 0.02% <nitrogen <0.060%, sulfur <0.01%, phosphorus <0.030% .

Carbon in the components according to the invention is controlled to a content of 0.030% or less in order to limit the martensite formation and hardening of cold rolling. In the same way and for the same reason it is necessary to control the carbon and nitrogen content below 0.07%.

Nitrogen content is controlled to be contained between 0.02% <N <0.060%, with 0.02% <N <0.04% being preferred to stabilize austenite and to maintain ferrite content at high temperatures <15%. . In fact, in order to facilitate deformation at high temperatures, the ferrite ratio after resolidification of the solidification infrastructure at 1240 ° C. should be kept below 10%. The following relationship should be established: Ferrite% = 0.034 x ² + 0.284 x-0.347, of which x = 6.903 [Cr _eq -Ni _eq / 1.029-6.998], Cr _eq = Cr%, Ni _eq = Ni% + 20.04 C% + 21.31 N% + 0.46 Cu% + 0.08 Mn%.

According to the configuration of the present invention, the nickel content is lowered between 4.55% and 7%, and the preferred value is about 5%. The decrease in Ni content is compensated for by the manganese content contained between 5% and 9%, with a preferred value of about 8%. Chromium content ensures corrosion protection and is chosen between 15% and 18%.

Copper is included in the components to stabilize the austenite. However, as stated in the prior art, the content is limited to 4% or less. A content of 2% or more is preferred here for the best stabilization of austenite.

Sulfur is limited to a content of 0.01% or less, with a content of 0.002% or less being particularly preferred. This is to limit the formation of sulfides of manganese which are detrimental to deformation and corrosion protection at high temperatures.

In addition, as other factors, silicon is controlled to have a content of less than 1% and a preferred value of about 0.3%. And molybdenum is controlled to have a content of less than 0.8% and phosphorus less than 0.030%.

In some cases, when boron is added, its content should be 50.10 ^-4 % or less, to facilitate deformation at high and low temperatures.

Ultimately, steel will have to reach a value of Md30 as low as possible, preferably below -60. The value of Md30 is linked to the following relationship: Md30 = 551-462 (C% + N%)-9.2 Si%-20 Mn%-13.7 Cr%-29 Ni%-29 Cu%-18.5 Mo%.

In one embodiment of the invention, the constituents of steel 1 according to the invention are called reference steels and compared with standard austenitic steels having the constituents shown in Table 1 below:

% C % Si % Mn % Ni % Cr % Mo % Cu % N % S Md3 % α Steel 1 0.023 0.36 8.1 5.1 15.0 0.30 3.3 0.035 0.001 -71.6 Reference steel 0.029 0.33 1.8 8.1 17.2 0.29 3.2 0.027 0.002 -59.3

In the field of forging at low temperatures, the steel according to the invention exhibits suitable properties for working at low temperatures and is better than standard reference steels. The non-persistent cross forging test revealed the following:

-Steel 1 according to the invention does not show cracks,

-Reference steels show clues of ductile breaks at each cross section.

As a property of corrosion, the steel according to the invention exhibits a strong resistance comparable to the corrosion resistance of 304 type standard steel.

As magnetic properties, welding properties, and processing properties, the steel according to the invention exhibits non-magnetic properties in the reheated state and weak magnetic properties in the cold worked state. The weldability shows the same properties as the weldability of the 304 type standard steel, and the workability shows similar properties to the workability of the 304 type standard steel.

From a commercial point of view, the steel according to the invention is cheaper because it uses an alloy material that is cheaper than nickel, and shows simplicity of processing at all stages of production, especially due to its structure at high temperatures. The steel also exhibits mechanical properties that are compatible with the production of standard types of austenitic stainless steel.

The steel according to the invention is suitable for making parts, including finishing, after the first forging at low temperatures.

Steel according to the present invention is used for fastening parts such as screws, bolts, nuts, corrugated rods, or special parts that require forging at low temperatures, such as parts of shipboards, for automobiles such as fixtures or airbags. It can be used in the field of parts, or parts formed by connecting several parts such as electric screw parts.

In addition, the steel according to the present invention can be used in the manufacture of parts that require significant deformation at low temperatures in order to reduce costs, for example, in the field of wire, fine metal wire, filter, filter or spring.

It is an object of the present invention to propose an austenitic stainless steel which is capable of processing after deformation at low temperatures, which exhibits more improved mechanical properties than standard types of austenitic stainless steel. This property shows great utility in deformation applications at low temperatures, in particular forging at low temperatures.

Claims (4)

Carbon <0.030%, 0.3% <Silicon <1%, 5% <Manganese <9%, 4.55% <Nickel <7%, 15% <Chromium <18%, Molybdenum <0.8%, 2% <Copper <4 Austenitic stainless steel capable of working after deformation at low temperatures, characterized by having weight percentages such as%, 0.02% <nitrogen <0.060%, sulfur <0.01%, phosphorus <0.030%. The austenitic stainless steel as claimed in claim 1, wherein the component comprises a boron content of 50.10 ^-4 % or less. The Md30 index according to claim 1, which is determined by the relationship of Md30 = 551-462 (C% + N%)-9.2 Si%-20 Mn%-13.7 Cr%-29 Ni%-29 Cu%-18.5 Mo% Austenitic stainless steel capable of processing after deformation at low temperatures, characterized in that less than -60. The method of claim 1, wherein the ferrite ratio after resolidification of the solidifying infrastructure at 1240 ° C. is 10% or less, wherein ferrite% = 0.034 x ² + 0.284 x-0.347, wherein x = 6.903 [Cr _eq -Ni _eq / 1.029 -6.998], Cr _eq = Cr%, Ni _eq = Ni% + 20.04 C% + 21.31 N% + 0.46 Cu% + 0.08 Mn% to satisfy the relationship of the deformation after low temperature possible processing Austenitic stainless steel.