JP2018159114A - Martensitic stainless steel having excellent corrosion resistance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide martensitic stainless steel having excellent corrosion resistance in an environment where there is formic acid or chloride.SOLUTION: The present invention provides martensitic stainless steel having excellent corrosion resistance, the stainless steel containing, in mass%, C: 0.200-0.300%, Si: 0.10-1.00%, Mn: 0.10-1.00%, P:≤0.040%, S:≤0.030%, Ni: 0.05-1.20%, Cr: 12.00-16.50%, Mo: 0.10-2.00%, Cu: 0.10-1.50%, N: 0.070-0.090%, with the balance being Fe and unavoidable impurities, the stainless steel satisfying the following relations: (Cr+1.37Mo+1.5Si)/(Ni+0.31Mn+22C+14.2 N+Cu)≤1.9, (45.5C-2.04Cr-2.92Mo-2.24Cu+86.1 N)≥-18.5, (Cr+3.3Mo+16 N-30C)≥8, (3.6Ni-Cr+4.7Mo+11.5Cu+1.4 N-2.1Mn)≥-8.0, carbide content≤0.3 vol%, delta ferrite phase content≤0.5 vol%.SELECTED DRAWING: None

Description

  This application is used for fuel pump parts and combustion supply system parts of automobiles, and has excellent corrosion resistance even in an environment containing formic acid such as deteriorated gasoline and an environment containing chloride such as a snow melting agent. It relates to martensitic stainless steel having

  For example, since high strength and corrosion resistance are required for automobile fuel pump members, general-purpose martensitic stainless steels such as SUS440C and SUS420J2 have been conventionally used. Even these general-purpose martensitic stainless steels do not face the problem of corrosion resistance for high-quality gasoline. However, in an environment containing formic acid such as deteriorated gasoline or an environment containing chloride, general-purpose martensitic stainless steel has insufficient corrosion resistance.

By the way, the inventors aimed to improve the corrosion resistance in an environment containing formic acid while suppressing the use of expensive elements such as Mo and V, and ferritic stainless steel and martensitic stainless steel added with Cu. Steel is being developed (see Patent Document 1).
However, in the martensitic stainless steel described in this document, corrosion resistance in a chloride environment is not considered, and it cannot be said that the corrosion resistance in a chloride environment is sufficient.
Of the stainless steels described in this document, No. 1 is an example relating to the same martensitic stainless steel as in the present application. When referring to 24-46 steels, none of them is consistent with the composition of the present application and the amount of N is generally too low, and these examples show that the C content is too high, Cr Is excessive or excessive, Cu is excessive, Mo is excessive or excessive, and does not match the numerical range of the present application. It did not satisfy at least one of the values of c, d, and e.

  Furthermore, the applicant has adjusted the content of Cr, Mo, N, Ni, Cu, C, and Mn to improve the corrosion resistance in an environment where carboxylic acid and chloride such as formic acid are present, and has improved martensitic stainless steel. An invention for steel has been filed (see Japanese Patent Application No. 2006-035043). However, even in the invention of this application, since deterioration of corrosion resistance due to carbide precipitation was not taken into consideration, further improvement in corrosion resistance including formic acid resistance is desired.

JP, 2006-050320, A

  The problem to be solved by the invention of the present application is to provide martensitic stainless steel having excellent corrosion resistance in an environment containing formic acid or an environment containing chloride.

Means for solving the above-mentioned problems are, in the first means, mass%, C: 0.200 to 0.300%, Si: 0.10 to 1.00%, Mn: 0.10 to 1.00. %, P: ≦ 0.040%, S: ≦ 0.030%, Ni: 0.05-1.20%, Cr: 12.00-16.50%, Mo: 0.10-2.00% , Cu: 0.10 to 1.50%, N: 0.070 to 0.090%, the balance consisting of Fe and inevitable impurities, a, b, c, d, represented by the following formula e is a / b ≦ 1.9, c ≧ −18.5, d ≧ 8, e ≧ −8.0, carbide amount ≦ 0.3 vol%, delta-ferrite phase amount ≦ 0.5 vol% It is a martensitic stainless steel excellent in corrosion resistance characterized by being.
However,
a = Cr + 1.37Mo + 1.5Si
b = Ni + 0.31Mn + 22C + 14.2N + Cu,
c = 45.5C-2.04Cr-2.92Mo-2.24Cu + 86.1N,
d = Cr + 3.3Mo + 16N-30C,
e = 3.6Ni-Cr + 4.7Mo + 11.5Cu + 1.4N-2.1Mn,
In addition, each element name in a formula shows content (%) of each element of the said means.

The second means contains 0.01 to 0.20% in total of one or more selected from V, Ti, Nb and Zr by mass% in addition to the chemical component of the first means. A, b, c, d, e represented by the following formula are a / b ≦ 1.9, c ≧ −18.5, d ≧ 8, e ≧ −. It is a martensitic stainless steel excellent in corrosion resistance, characterized in that it is 8.0, the carbide amount ≦ 0.3 vol%, and the delta-ferrite phase amount ≦ 0.5 vol%.
However,
a = Cr + 1.37Mo + 1.5Si
b = Ni + 0.31Mn + 22C + 14.2N + Cu,
c = 45.5C-2.04Cr-2.92Mo-2.24Cu + 86.1N,
d = Cr + 3.3Mo + 16N-30C,
e = 3.6Ni-Cr + 4.7Mo + 11.5Cu + 1.4N-2.1Mn,
In addition, each element name in a formula shows content (%) of each element of the said means.

  The martensitic stainless steel of the first and second means of this application can be used as a fuel pump member or a combustion supply system part of an automobile, and is an environment or snow melting agent containing formic acid such as deteriorated gasoline. It has excellent corrosion resistance even in an environment containing chlorides. Moreover, since the formation of a Cr-deficient layer accompanying carbide precipitation can be suppressed by limiting the amount of carbide, more excellent anti-acidity can be obtained.

  Prior to the description of the mode for carrying out the present invention, the reasons for limitation of each chemical component and other constituent elements of the invention in this application will be described. In addition,% in a chemical component is the mass%.

C: 0.200 to 0.300%
C is an element necessary for ensuring the hardness of martensitic stainless steel. If C is less than 0.200%, the hardness cannot be secured, and if C is more than 0.300%, the corrosion resistance decreases due to an increase in carbides. Therefore, C is set to 0.200 to 0.300%.

Si: 0.10 to 1.00%
Si is a deoxidizing element. When Si is less than 0.10%, sufficient deoxidation cannot be obtained, and when Si is more than 1.00%, toughness is lowered. Therefore, Si is set to 0.10 to 1.00%.

Mn: 0.10 to 1.00%
Mn is a deoxidizing element. When Mn is less than 0.10%, sufficient deoxidation cannot be obtained, and when Mn is more than 1.00%, the corrosion resistance is lowered. Therefore, Mn is set to 0.10 to 1.00%.

P: ≦ 0.040%
P is an impurity element, and when it exceeds 0.040%, hot workability deteriorates. Therefore, P is set to 0.040% or less.

S: ≦ 0.040%
S is an impurity element, and when it exceeds 0.040%, hot workability deteriorates. Therefore, S is set to 0.040% or less.

Ni: 0.05-1.20%
Ni is an element inevitably mixed from the raw material, and excessive reduction leads to an increase in manufacturing cost, so the lower limit is made 0.05%. By the way, Ni is an austenite stabilizing element, and the increase of Ni is effective in reducing the delta-ferrite phase. In order to obtain this effect, Ni may be added up to 1.20%. On the other hand, when Ni is contained in excess of 1.20%, cold workability is lowered. Therefore, Ni is set to 0.05 to 1.20%.

Cr: 12.00-16.50%
Cr is an element necessary for ensuring corrosion resistance. For that purpose, Cr needs to be 12.00% or more. On the other hand, if the Cr content exceeds 16.50%, the delta-ferrite phase increases and the corrosion resistance decreases. Therefore, Cr is set to 12.00 to 16.50%.

Mo: 0.10 to 2.00%
Mo is an element necessary for ensuring corrosion resistance. For that purpose, Mo needs to be 0.10% or more. On the other hand, if the Mo content exceeds 2.00%, the delta-ferrite phase increases and the corrosion resistance decreases. Therefore, Mo is set to 0.10 to 2.00%.

Cu: 0.10 to 1.50%
Cu is an element necessary for ensuring forgi acid resistance. For that purpose, Cu needs to be 0.10% or more. On the other hand, if the amount of Cu is more than 1.50%, the carbon solid solution amount of the steel substrate decreases and precipitation of carbides is promoted, so that the corrosion resistance decreases. Therefore, Cu is set to 0.10 to 1.50%.

N: 0.070-0.090%
N is an element necessary for ensuring corrosion resistance. For that purpose, N needs to be 0.070% or more. On the other hand, if N is more than 0.090%, the weldability is lowered. Therefore, N is set to 0.070 to 0.090%.

One or more selected from V, Ti, Nb, and Zr are contained in a total of 0.01 to 0.20%. V, Ti, Nb, and Zr are elements that improve strength. For that purpose, it is necessary to contain 0.01% or more in total of one or more selected from V, Ti, Nb, and Zr. However, in these elements, if the content exceeds 0.20%, the toughness decreases. Therefore, the content of one or more selected from V, Ti, Nb, and Zr is 0.01 to 0.20% in total.

a / b ≦ 1.9
a and b are expressed by the following equations, and the value of a / b is an index indicating the degree of existence of the delta-ferrite phase. That is, when the value of a / b is larger than 1.9, a delta-ferrite phase is precipitated and the corrosion resistance is lowered. Therefore, the value of a / b is set to 1.9 or less.
here,
a = Cr + 1.37Mo + 1.5Si
b = Ni + 0.31Mn + 22C + 14.2N + Cu.

c ≧ −18.5
c is expressed by the following formula, and the value is an index indicating the degree of hardness. That is, when the value of c is smaller than −18.5, the hardness cannot be ensured. Therefore, the value of c is set to −18.5 or more.
here,
c = 45.5C-2.04Cr-2.92Mo-2.24Cu + 86.1N.

d ≧ 8
d is represented by the following formula, and the value is an index representing weather resistance. That is, if the value of d is smaller than 8, weather resistance cannot be ensured. Therefore, the value of d is 8 or more.
Here, d = Cr + 3.3Mo + 16N-30C.

e ≧ −8.0
e is represented by the following formula, and the value thereof is an index representing the resistance to formic acid. That is, when the value of e is less than −8.0, the forgi acid resistance cannot be ensured. Therefore, the value of e is set to −8.0 or more.
here,
e = 3.6Ni-Cr + 4.7Mo + 11.5Cu + 1.4N-2.1Mn.

  In addition, the element symbol in each formula of said a, b, c, d, e shows content (%) of each element of this application.

Carbide content ≤ 0.3% (vol%)
When carbide is deposited on martensitic stainless steel, a Cr-deficient layer is formed, resulting in a decrease in corrosion resistance. If the amount of carbide exceeds 0.3 vol%, formic acid resistance cannot be ensured. Therefore, the amount of carbide is set to 0.3 vol% or less.

Amount of delta ferrite phase ≤ 0.5% (vol%)
When the delta-ferrite phase precipitates, carbide precipitates at the interface between the delta-ferrite phases and a Cr-deficient layer is generated, resulting in a decrease in corrosion resistance. When the amount of delta-ferrite phase exceeds 0.5 vol%, corrosion resistance cannot be ensured. Therefore, the amount of delta-ferrite phase is 0.5 vol% or less.

  Here, the form for implementing invention of this application is demonstrated below. First, invention steel No. which consists of a chemical component value of Table 1 and the value of a / b, c, d, e. 1 to 24 and comparative steel No. 25-38 were melted in a 100 kg vacuum induction melting furnace and cast into ingots.

  The obtained ingot was heated to 1270 ° C., forged into a 20 mm diameter steel bar, then held at 1100 ° C. for 1 hour, then oil-cooled, further held at 150 ° C. for 1 hour, and then air-cooled. A heat treatment material was applied.

  Each heat treatment material created above is cut out so that the cross section passing through the center of the diameter parallel to the forging direction becomes the observation surface, the surface is polished to a mirror surface using emery paper and buff, and then by planar ion milling Carbide was made to appear, 5 fields of view were photographed with an electron microscope, and the amount of carbide was determined as a volume fraction (vol%) by image analysis. The amount of carbide was 0.3 vol% or less as ◯, and the amount exceeding 0.3 vol% as x.

  Each heat treatment material created above is cut out so that the cross section passing through the center of the diameter parallel to the forging direction becomes the observation surface, the surface is polished to a mirror surface using emery paper and buff, and then by planar ion milling Grain boundaries were revealed, five fields of view were photographed with an electron microscope, and the amount of delta-ferrite phase (δ phase) was determined as a volume fraction (vol%) by image analysis. The amount of the delta-ferrite phase was 0.5 vol% or less as ◯, and more than 0.5 vol% as x.

  Evaluation of corrosion resistance to chloride environment was performed by CASS test (ASTM B 368-86). The spray solution is a mixture of 50 g / l sodium chloride, 0.205 g / l copper (II) chloride hydrate, and acetic acid acidity (pH = 3). The spray temperature is 50 ° C. and the spray time is 24 hours. The test was conducted and the rusting state of the corrosion test piece after the test was investigated.

The corrosion resistance evaluation with respect to formic acid was carried out by an immersion test. This was achieved by immersing each heat-treated material prepared above in boiling 1% formic acid aqueous solution for 24 hours, measuring the mass loss before and after the test, and setting the mass loss to 1 g / (m ² / hr) or less, and 1 g / Evaluation was made in Table 2 with x exceeding (m ² / hr).

  About the heat processing material of diameter 20mm created above, the hardness of the location between the edge part and center part of a cross section perpendicular | vertical to those forging directions was measured 5 points | pieces with the Rockwell hardness meter C scale. With respect to the average value of the five points, a value of 50 HRC or more was evaluated as ◯, and a value less than 50 HRC was evaluated as ×.

  The results of the above carbide content, delta ferrite content, corrosion resistance evaluation for chloride environment, corrosion resistance evaluation for formic acid and hardness measurement are shown in Table 2 above. If all of these items were “good”, the comprehensive judgment was “good”, and if any one of the items had “x”, the comprehensive judgment was evaluated as “poor”.

  As a result of the above, No. of invention steel which is the martensitic stainless steel of the present application. In all the steels 1 to 24, the overall judgment was “good”. In contrast, the comparative steel No. For all steels 25-38, each No. There is a cross in any of the items, and accordingly, the comparative steel No. In all the steels 25 to 38, the overall judgment was x.

Claims (2)

In mass%, C: 0.200 to 0.300%, Si: 0.10 to 1.00%, Mn: 0.10 to 1.00%, P: ≦ 0.040%, S: ≦ 0.0. 030%, Ni: 0.05 to 1.20%, Cr: 12.00 to 16.50%, Mo: 0.10 to 2.00%, Cu: 0.10 to 1.50%, N: 0 A, b, c, d, and e represented by the following formula are a / b ≦ 1.9 and c ≧ −18. 5, d ≧ 8, e ≧ −8.0, carbide amount ≦ 0.3 vol%, delta / ferrite phase amount ≦ 0.5 vol%, martensitic stainless steel excellent in corrosion resistance,
However,
a = Cr + 1.37Mo + 1.5Si
b = Ni + 0.31Mn + 22C + 14.2N + Cu
c = 45.5C-2.04Cr-2.92Mo-2.24Cu + 86.1N
d = Cr + 3.3Mo + 16N-30C
e = 3.6Ni-Cr + 4.7Mo + 11.5Cu + 1.4N-2.1Mn
In addition, the element in a formula is the magnitude | size of the numerical value of% of each chemical component of Claim 1. In addition to the chemical component of claim 1, in a mass%, one or more selected from V, Ti, Nb and Zr are contained in a total of 0.01 to 0.20%, the balance being Fe and inevitable impurities A, b, c, d, and e represented by the following formula are a / b ≦ 1.9, c ≧ −18.5, d ≧ 8, e ≧ −8.0, and carbides A martensitic stainless steel excellent in corrosion resistance, characterized in that the amount is ≦ 0.3 vol% and the amount of delta-ferrite phase is ≦ 0.5 vol%.
However,
a = Cr + 1.37Mo + 1.5Si
b = Ni + 0.31Mn + 22C + 14.2N + Cu
c = 45.5C-2.04Cr-2.92Mo-2.24Cu + 86.1N
d = Cr + 3.3Mo + 16N-30C
e = 3.6Ni-Cr + 4.7Mo + 11.5Cu + 1.4N-2.1Mn
In addition, the element of a formula is a magnitude | size of the numerical value of% of each chemical component of the said means.