JP5609668B2 - Stainless clad steel with excellent seawater pitting resistance - Google Patents

Description

  The present invention relates to a stainless clad steel excellent in seawater pitting resistance used in various applications represented by offshore structures and heat exchangers.

  In recent years, plant operation tends to increase in temperature and pressure from the viewpoint of higher efficiency, and in the design of chemical plants, the ratio of using thicker steel plates tends to increase in order to ensure strength. Furthermore, the needs of industrial equipment and structures are oriented toward durability, long life and maintenance-free, and stainless steel is attracting attention as a material that meets these needs. On the other hand, alloy elements typified by Ni, Mo, and Cr, which are the main raw materials for stainless steel, have a rising price and a rising and falling price. Therefore, instead of stainless steel, stainless steel clad steel has recently been attracting attention as a steel material that can use the excellent antirust performance of stainless steel more economically, is stable in price, and inexpensive.

  Stainless steel clad steel is a steel material in which two different types of metals are bonded together: stainless steel as a laminated material and ordinary steel as a base material. The clad steel is obtained by metallographically bonding dissimilar metals, and unlike the plating, there is no fear of peeling, and it can have new characteristics that cannot be achieved by a single metal and alloy.

Stainless steel clad steel has the same rust prevention as solid materials (full thickness stainless steel) by selecting the type of stainless steel that is suitable for each usage environment in order to ensure the anticorrosive ability suitable for the purpose of each usage environment. Performance is secured.
In this way, stainless steel clad steel requires only a small amount of stainless steel, and can secure the same rust prevention performance as solid wood (full thickness stainless steel). Have.

  From the above, it is considered that stainless clad steel is a very useful functional steel material, and in recent years its needs have been increasing in various industrial fields.

  When such stainless clad steel is used in various applications typified by heat exchangers, shipbuilding, etc. that are in contact with offshore structures or seawater, in addition to the above rust prevention performance, Therefore, seawater pitting resistance is required. The passive film of stainless steel is easily destroyed by chloride ions, and its corrosion form takes the form of pitting corrosion. Therefore, while corrosion forms in acids such as sulfuric acid and hydrofluoric acid exhibit general corrosion, pitting corrosion resistance, which is the starting point of local corrosion, is an important index in seawater.

  As a technique for improving seawater pitting resistance, Patent Document 1 defines the conditions for solution heat treatment and the base material carbon steel, and uses stainless steel with excellent seawater resistance as a combination material and carbon steel as a base material. A method of manufacturing a stainless clad steel pipe is disclosed. However, in Patent Document 1, in order to ensure the corrosion resistance and seawater pitting resistance required for each use of a stainless clad steel pipe (for example, an offshore structure or a heat exchanger), stainless steel used as a laminated material is used for each application. Must be selected. That is, only the method of adjusting with the components of stainless steel is shown, and in the case of stainless clad steel, high-grade steel materials that maintain the soundness and reliability of the joint interface and maintain the performance of the base material and the laminated material at the same time. It is difficult to deal with all kinds of variety.

  Patent Document 2 discloses a technology for providing a seawater corrosion-resistant austenitic stainless cast steel having excellent pitting corrosion resistance and a seawater pump. In Patent Document 2, in order to solve the problem, by weight, C: 0.08 wt% or less, Si: 0.5-1.5 wt%, Mn: 0.5-2 wt%, P: 0.04 wt% or less, About austenitic stainless cast steel containing S: 0.01 wt% or less, Ni: 8.0 to 9.5 wt%, Cr: 18 to 21 wt%, the δ ferrite phase is set to 6 vol% or more, or the cleanliness is 0 Ingredients achieved by less than 0.1% are disclosed. However, Patent Document 2 merely defines the steel components and the precipitation amount of the second phase within a predetermined range, and does not disclose a sufficient technique regarding the surface properties. Moreover, since it is a cast steel, it is disadvantageous in terms of strength and the like, and it cannot be a raw material for clad steel as it is.

Japanese Patent No. 4179133 Japanese Patent No. 3336820

  In view of such circumstances, an object of the present invention is to provide a stainless clad steel excellent in seawater pitting resistance.

In order to solve the problem, various mirror finishing treatments were applied to a plurality of stainless clad steels having the same components (steel composition) and the same history and completed from rolling to heat treatment, and the surface properties were examined in detail.
And we examined the surface roughness, inclusions, and the strength Cr / Fe ratio of the passive film that affects the corrosion resistance (pitting corrosion resistance) of stainless steel. An average roughness Rz _JIS (L) in the rolling (longitudinal) direction (L) of the stainless clad steel surface measured according to JIS B 0601-2001. ) the 1.0 .mu.m or less, 1.0 .mu.m or less vertical (average C) roughness Rz _JIS (C) to the rolling direction, the average roughness Rz _JIS of the rolling at each measurement point (lengthwise) direction (L) (L) and the average L / C, which is the average of the ratio (L / C) of the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C), in the range of 0.5 to 2.0, It has been found that seawater pitting resistance is improved. Furthermore, the number of sulfide inclusions on the surface of the stainless clad steel is 2.5 × 10 ⁵ pieces / mm ² or less, and the Cr concentration (at%) / Fe concentration (at%) in the passive film part and the parent phase. It has also been found that seawater pitting resistance is further improved by setting the Cr concentration (at%) / Fe concentration (at%) ratio of stainless steel to 1.2 or more.

This invention is made | formed based on the above knowledge, The summary is as follows.
[1] Rolling (longitudinal) direction measured according to JIS B 0601-2001 on a stainless steel clad steel having a pitting corrosion index PI of 35.0 or more as a combination material The average roughness Rz _JIS (L) of (L) is 1.0 μm or less, the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) is 1.0 μm or less, and the rolling at each measurement point (longitudinal) ) Direction (L) average roughness Rz _JIS (L) and average L / C which is the average of the ratio (L / C) of the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) Is a stainless clad steel excellent in seawater pitting corrosion resistance, characterized by being in the range of 0.5 to 2.0.
The pitting index PI is an index represented by Cr (mass%) + 3Mo (mass%) + 16N (mass%).
[2] The stainless clad steel excellent in seawater pitting corrosion resistance according to [1], wherein the number of sulfide inclusions on the surface of the stainless clad steel is 2.5 × 10 ⁵ pieces / mm ² or less.
[3] In the above [1] or [2], Cr concentration (at%) / Fe concentration (at%) in the passive film portion formed on the surface of the stainless clad steel and Cr of the stainless steel as the parent phase Stainless steel clad steel with excellent seawater pitting corrosion resistance, characterized in that the ratio of concentration (at%) / Fe concentration (at%) is 1.2 or more.

  “Excellent seawater pitting corrosion resistance” means that CPT (critical pitting corrosion occurrence temperature), which is an index of seawater pitting corrosion resistance described later, is 40 ° C. or higher, and CCT (critical crevice corrosion occurrence temperature) is 20 ° C. or higher.

According to the present invention, a stainless clad steel excellent in seawater pitting resistance can be obtained.
It can be suitably used in applications that require seawater pitting resistance, such as marine structures and heat exchangers.

It is a figure which shows the example of a measurement of Cr density | concentration (at%) and Fe density | concentration (at%) of a passive film and a stainless steel mother phase.

The stainless clad steel of the present invention is a stainless clad steel having a pitting corrosion index PI represented by Cr (mass%) + 3Mo (mass%) + 16N (mass%) of 35.0 or more as a combination material. The average roughness Rz _JIS (L) in the rolling (longitudinal) direction (L) measured according to JIS B 0601-2001 on the surface of the stainless clad steel is 1.0 μm or less, and the direction perpendicular to the rolling direction ( The average roughness Rz _JIS (C) of C) is 1.0 μm or less, the average roughness Rz _JIS (L) in the rolling (longitudinal) direction (L) at each measurement point, and the direction perpendicular to the rolling direction (C ) Average roughness Rz _JIS (C) ratio (L / C) average L / C is in the range of 0.5 to 2.0. Furthermore, it is preferable that the number of sulfide inclusions on the surface of the stainless clad steel is 2.5 × 10 ⁵ pieces / mm ² or less. In addition, Cr concentration (at%) / Fe concentration (at%) in the passive film formed on the surface of the stainless clad steel and Cr concentration (at%) / Fe concentration (at%) of the stainless steel as the parent phase ) Ratio is preferably 1.2 or more.

And by controlling the surface properties as described above, a stainless clad steel having excellent seawater pitting resistance can be obtained. As the stainless clad steel of the present invention, hot-rolled steel sheets, steel sheets subjected to Annealing Rashi heat treatment after hot rolling treatment, both included, the same effect can be obtained.

  Further, by combining chemical treatment with chemical treatment, the surface properties can be controlled and the surface characteristics can be kept within a predetermined range. Examples of the mechanical treatment include ordinary belt polishing, grinding wheel polishing, and the like, and these existing various surface polishing methods can be combined. By combining these, the surface roughness can be kept low. Moreover, it is preferable to perform a chemical treatment from the viewpoint of removing inclusions on the surface and strengthening the passive film. The chemical treatment method is not particularly limited, but pickling treatment in nitric acid, hydrofluoric acid, sulfuric acid, hydrochloric acid or electrolytic treatment in these acid solutions or neutral salt solutions (for example, Lusner method: 20% by mass sodium sulfate) Solutions and sodium nitrate) are preferred.

Laminated material: Stainless steel is used unpainted in stainless steel marine structures and heat exchangers with a pitting corrosion index PI of 35.0 or more, expressed as Cr (mass%) + 3Mo (mass%) + 16N (mass%) Therefore, it is necessary to have sufficient pitting corrosion resistance in a seawater environment, that is, seawater pitting corrosion resistance. Stainless steel with a PI of less than 35.0 causes pitting corrosion in seawater. Even if the surface roughness, which is a feature of the present invention, is controlled, CPT (critical pitting corrosion temperature) conforming to JIS G 0578: 40 ° C or higher, CCT (Critical crevice corrosion occurrence temperature): A characteristic of 20 ° C. or higher cannot be achieved, and sufficient seawater pitting resistance cannot be obtained. Therefore, in the present invention, PI is 35.0 or more. Preferably it is 40.0 or more.

Average roughness Rz _JIS (L) in the rolling (longitudinal) direction (L) measured in accordance with JIS B 0601-2001 is 1.0 μm or less, average roughness Rz _{JIS in the} direction perpendicular to the rolling direction (C) (C) is 1.0μm or less, an average roughness Rz _JIS of the rolling at each measurement point (lengthwise) direction average roughness Rz _JIS (L) and the direction perpendicular to the rolling direction (L) (C) ( The average L / C, which is the average of the ratio (L / C), is in the range of 0.5 to 2.0. The surface roughness greatly affects the seawater pitting resistance of stainless clad steel. When the surface unevenness is large, during seawater immersion, deposits such as sea salt particles and Fujitsubo are likely to hit the surface of the stainless clad steel, and gaps are easily formed. In addition, since the surface area is widened, many soluble precipitates present in the grain boundaries and within the grains appear on the surface, and the fragile parts that are the starting points of pitting corrosion increase. In addition, when the roughness is anisotropic, the surface properties vary depending on the direction. Furthermore, there is a problem in practical use that deposits tend to adhere in a specific direction, and the clad steel must be applied with care when using the clad steel.

Therefore, in consideration of the above, when considering the improvement of seawater pitting corrosion resistance and the removal of deposits, the surface roughness was measured using a roughness Rz _JIS measured in accordance with JIS B 0601-2001, and rolled (longitudinal). ) The average roughness Rz _JIS (L) in the direction (L) is 1.0 μm or less, the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) is 1.0 μm or less, and the rolling at each measurement point (longitudinal) direction average of a mean L ratio of the average roughness (L) Rz _JIS (L) and the average roughness Rz _JIS of the direction perpendicular to the rolling direction (C) (C) (L / C) It was found that by setting / C in the range of 0.5 to 2.0, the surface of the stainless clad steel is less likely to adhere when immersed in seawater, and the seawater pitting resistance is improved. From the above, the average roughness Rz _JIS (L) in the rolling (longitudinal) direction (L) is 1.0 μm or less, and the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) is 1.0 μm or less. the rolling in the measurement points (lengthwise) direction average roughness Rz _JIS of the (L) (L) and the ratio of the average roughness Rz _JIS of the vertical (C) to the rolling direction (C) (L / C) The average L / C, which is the average of, is in the range of 0.5 to 2.0. Preferably, the average roughness Rz _JIS (L) in the rolling (longitudinal) direction (L) is 0.7 μm or less, the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) is 0.7 μm or less, and the average L / C is preferably in the range of 0.7 to 1.5. On the other hand, it is preferable that the surface roughness is small, but the polishing of stainless steel clad steel is very burdensome, so the lower limit of average roughness Rz _JIS (L) and average roughness Rz _JIS (C) is 0.1 μm. preferable. Further, it is industrially very difficult to make the roughness completely uniform in the rolling direction and the vertical direction, so the average L / C range is more preferably 0.9 or less or 1.1 or more.

The number of sulfide inclusions on the surface of stainless clad steel is 2.5 × 10 ⁵ / mm ² or less (preferred conditions)
In the case of stainless clad steel used in applications typified by offshore structures and heat exchangers, seawater pitting corrosion resistance is mainly required. As a result of the investigation, it was found that the presence of inclusions precipitated on the surface of the stainless clad steel was involved in seawater pitting resistance. Further, the inclusions precipitated on the surface of the stainless clad steel include oxides, carbides, nitrides, sulfides, etc. Among them, particularly coarse sulfides (for example, FeS, Fe ₂ S, MnS, CuS). , Cu ₂ S, CdS, SnS, NiS, ZnS, etc.) was found to be greatly involved in the decrease in seawater pitting resistance. From the results of the above studies, in the present invention, it is preferable to control sulfide inclusions so that the number thereof is 2.5 × 10 ⁵ pieces / mm ² or less. The sulfide inclusions are FeS, Fe ₂ S, MnS, CuS, Cu ₂ S, CdS, SnS, NiS, ZnS, and the like. The smaller the number of sulfide inclusions, the lower the probability of occurrence of pitting corrosion. However, in practice, it is difficult to remove all sulfide inclusions in actual production, so 1.0 × 10 ² pieces / mm ² or more is preferable.

  In addition, it can be identified whether it is a sulfide type | system | group deposit by performing an elemental analysis for each inclusion using an energy dispersive X-ray analyzer, and investigating a composition. However, if the size of the sulfide inclusions is less than 1.0μmΦ, even if the sulfide inclusions dissolve in contact with seawater and the like, and the pitting corrosion occurs, there is a high probability that the progress will stop. Inclusions that are sometimes counted are limited to a size of 1.0 μmΦ or more.

Ratio of Cr concentration (at%) / Fe concentration (at%) in the passive film formed on the surface of stainless clad steel and Cr concentration (at%) / Fe concentration (at%) of the stainless steel as the parent phase Is 1.2 or more (preferred conditions)
The Cr concentration (at%) / Fe concentration (at%) in the passive film part is a very important factor for improving the pitting corrosion resistance of the passive film. Basically, the ratio of Cr concentration (at%) / Fe concentration (at%) in the passive film part to Cr concentration (at%) / Fe concentration (at%) of the stainless steel as the parent phase (hereinafter referred to as Cr) The higher the (/ Fe concentration ratio), the more a stable passive film with excellent pitting corrosion resistance is formed on the surface layer. From the viewpoint of corrosion resistance, the higher Cr / Fe concentration ratio is better. As a result of the examination, it was found that the Cr / Fe concentration ratio is 1.2 or more so that the effect of improving the corrosion resistance (pitting corrosion resistance) appears clearly by the atmospheric exposure test and the accelerated corrosion test. Based on this knowledge, the Cr / Fe concentration ratio is preferably 1.2 or more. More preferably, it is 1.5 or more.

  On the other hand, in order to increase the Cr / Fe concentration ratio, acid dipping, pickling, and electrolytic treatment are required. Since stainless clad steel plate is a combination of plain steel and stainless steel, it is necessary to take care not to dissolve ordinary steel when it is immersed in a prescribed solution. It takes a load to improve the Cr concentration ratio. As described above, an excessive load on the Cr / Fe concentration ratio imposes an equipment load, so the Cr / Fe concentration ratio is preferably 100 or less.

  In some cases, mechanical polishing alone may not sufficiently improve the Cr / Fe concentration ratio. Therefore, it is important to combine with some chemical surface control technique.

  In the present invention, the Cr / Fe concentration ratio is measured by, for example, measuring the element concentration profile (at%) while sputtering in the depth direction, and determining the Fe and Cr atoms from each element (Fe, Cr, etc.) concentration profile. Ratio and Cr / Fe concentration ratio can be obtained. In this case, as shown in FIG. 1, it is assumed that the region in which the Cr and Fe concentration profile values (at%) are almost constant is the matrix phase, and the region with a shorter sputtering time is the passive film portion. Define. In the passive film portion, the value at the highest Cr / Fe value is defined as Cr concentration (at%) / Fe concentration (at%) in the passive film portion.

  Carbon steel or low alloy steel can be used as the base material of the stainless clad steel of the present invention. The stainless clad steel of the present invention is obtained by clad stainless steel as a mating material on one or both sides of the base material, and the manufacturing method for clad the base material and the mating material is not particularly limited. A hot rolling method, an explosive rolling method, a diffusion bonding method, a cast-in method, and the like can be used.

In addition, at a temperature of 700 ℃ ~1000 ℃, it is also possible to carry out the burn of better processing of 1 minute to 2 hour hold. When the content of Cr and Mo contained in the stainless steel used in the stainless steel clad steel is large, for example, in the case of a high alloy steel containing at least 18% by mass of Cr and 2% by mass of Mo, σ (Sigma) phase, cocoon phase, and M ₂₃ C ₆ , M ₆ C (M is mainly composed of Fe and Cr) are generated, and effective Cr is decreased and sensitization causes a significant decrease in corrosion resistance. There is. In such a case, the stainless clad steel having a controlled surface according to the present invention is effective, and can contribute to the removal of the Cr removal layer and the soundness of the sensitized portion.

The present invention is described in detail below.
Austenitic stainless steel composed of the components shown in Table 1 and SS400 component ordinary steel (hereinafter abbreviated as ordinary steel) are melted by a known method such as a converter, electric furnace, vacuum melting furnace, etc. A steel material (slab) was obtained by a casting method or an ingot-bundling method. Next, the obtained steel material is subjected to hot rolling, hot-rolled sheet annealing (for example, box annealing) and pickling in order under the conditions normally used to form a hot-rolled sheet, and further cold-rolled and finish-annealed (for example, Continuous annealing) to obtain a cold-rolled annealed sheet. Stainless steel clad steel was produced under the production conditions shown in Table 2 using the obtained cold-rolled annealed sheet as a clad laminated material (austenitic stainless steel) and a base material (ordinary steel).

  That is, the laminated material shown in Table 1 (austenitic stainless steel, plate thickness 20 mm) and the base material (regular steel: equivalent to SS400, plate thickness 73 mm) are assembled into slab dimensions with a width of 1890 mm and a length of 2060 mm, and the slab heating temperature ( ° C): 1250 ° C, rolling end temperature (° C): 1000 ° C, water cooling start temperature (° C): 950 ° C, water cooling end temperature (° C): 650 ° C, cooling rate (° C / s): 3.0 ° C / s Thus, stainless clad steel (laminated material: plate thickness 3 mm, base material: plate thickness 11 mm, width 2500 mm, length 8000 mm) was produced. Further, as shown in Table 3, normalizing heat treatment was performed on a part of the stainless clad steel at 950 ° C. for 10 minutes or 2 hours.

The stainless clad steel obtained as described above was subjected to belt polishing so that the surface of the stainless steel had the roughness shown in Table 4. Specifically, after performing multi-pass belt polishing in the longitudinal direction, multi-pass belt polishing was performed in the longitudinal and vertical direction. In the case of the longitudinal direction polishing, the polishing belts P60 to P400 as defined in JIS R6256: 2006 were used, and in the case of the longitudinal vertical direction polishing, the polishing belts P120 to P800 were used.
Next, an aqueous nitric acid solution was sprayed on the surface of the stainless steel clad steel at a rate of 1 L / min for a predetermined time, then washed with water and subjected to a passivation treatment. At this time, samples were prepared by adjusting the spraying time in the range of 5 seconds to 10 minutes and the nitric acid aqueous solution concentration in the range of 5 to 35% by mass so as to obtain a passive film as shown in Table 4.

The average roughness Rz _JIS , the number of sulfide inclusions, Cr / Fe concentration ratio, CPT (critical pitting corrosion temperature), and CCT (critical crevice corrosion temperature) are measured for the stainless clad steel obtained above. The seawater pitting resistance was evaluated. The results obtained from the above are shown in Table 4. The average roughness Rz _JIS , the number of sulfide inclusions, Cr / Fe concentration ratio, CPT (critical pitting corrosion temperature), and CCT (critical crevice corrosion temperature) are measured as follows.

Average roughness Rz _JIS
In accordance with JIS B 601-2001, the surface roughness Rz _JIS was measured at a measurement length of 10 mm in two directions of the rolling direction (L) and the direction perpendicular to the rolling direction (C) at the same position. This is done at five locations, the average of each of the rolling direction (L) and the vertical direction (C) is obtained, the average roughness Rz in the rolling direction (L) _JIS (L) and the average roughness Rz in the vertical direction (C) _JIS (C) was determined. In addition, the ratio (L / C) of the average roughness Rz _JIS between the rolling direction (L) and the vertical direction (C) at each measurement point was calculated, and the arithmetic average (average L / C) of L / C at 5 points Asked.

Number of sulfide inclusions
EPMA is used to analyze the surface of stainless clad steel 100μm × 100μm, and by processing the image obtained by mapping S amount, calculate the equivalent circle diameter and measure the number of sulfides of 1.0μmΦ or more. did. In addition, 20 fields of view each having a measurement area of 100 μm × 100 μm were measured and obtained as an average value. As described above, sulfides with a size of less than 1.0 μmΦ tend to stop the progress of pitting corrosion even if inclusions dissolve (so-called repassivation pits), so sulfides with a size of 1.0 μmΦ or more were counted. .

Cr / Fe concentration ratio
Each element (Fe, Cr) measured by sputtering in the depth direction using AES (PHI MODEL 660 manufactured by PHISICAL ELECTONICS, acceleration voltage: 5 kV, sample current: 0.2 μA, measurement area: 5 μm × 5 μm) ) The atomic ratio was obtained from the profile. In addition, as shown in FIG. 1, the area | region where the value of Cr and Fe became the substantially constant value was made into the parent phase, and the area | region where sputtering time was shorter than that was defined as the passive film part. In the passive film part, the value at the highest Cr / Fe value was taken as the Cr / Fe concentration and compared with the Cr / Fe concentration of the matrix.

CPT (critical pitting corrosion temperature), CCT (critical crevice corrosion temperature)
As an index of seawater pitting corrosion resistance, the critical pitting corrosion temperature and critical crevice corrosion temperature are determined by the CPT test (critical pitting corrosion temperature measurement test) and CCT test (critical crevice corrosion temperature measurement test) specified by ASTM. Asked.
The CPT test (critical pitting corrosion temperature measurement test), which is an index of seawater pitting corrosion resistance, is based on ASTMG48 (method C) and is immersed in a 6% FeCl ₃ + 1% HCl solution at 5 ° C intervals. went. The test size is 20 mm wide x 50 mm long x 2.0 mm thick. The immersion test was performed three times, and when the maximum pitting depth of the generated pitting corrosion reached 0.025 mm, it was determined to be rejected. When pitting corrosion did not occur in all three times, it was accepted, and the maximum temperature in that case was defined as CPT (° C.). The target value of CPT is 40 ° C. or higher, preferably 50 ° C. or higher.
The CCT test (critical crevice corrosion occurrence temperature measurement test) was also performed in the same manner as the CPT test (critical pitting corrosion occurrence temperature measurement test). When the maximum pitting depth of the generated pitting corrosion reached 0.025 mm, it was determined as rejected. When pitting corrosion did not occur in all three times, it was accepted, and the maximum temperature in that case was defined as CCT (° C.). The target value of CCT is 20 ° C. or higher, preferably 30 ° C. or higher.

From Table 4, it can be seen that in the present invention example, both CPT and CCT are the target of 40 ° C. or higher and 20 ° C. or higher, and a stainless clad steel excellent in seawater pitting corrosion resistance is obtained.
No.7 is, 950 ℃ after the hot rolling, is an example of the present invention that was baked a better heat treatment for 10 minutes. It can be seen that by controlling the surface roughness, the same characteristics as No. 4 are obtained.
Nos. 8 and 9 are examples of the present invention in which the number of sulfide inclusions is further reduced as compared to No. 7, and CPT is higher than No. 7, with No. 9 being 60 It has reached ℃. No. 10 is an example of the present invention in which the number of sulfide inclusions is further reduced and the Cr / Fe concentration ratio is improved compared to No. 7. CPT is 65 ℃ and CCT is very high at 50 ℃. No. 11 is an example of the present invention in which the Cr / Fe concentration ratio is further increased to 2 or more with respect to No. 10. CPT has reached 70 ℃.
No. 13 has a CPT of 65 ° C and a CCT of 45 ° C by reducing the number of sulfide inclusions and setting the Cr / Fe concentration ratio to 1.2 or higher.
These test results show that seawater pitting resistance is further improved by controlling the number of sulfide inclusions and the Cr / Fe concentration ratio in addition to the surface roughness.

On the other hand, the comparative example is inferior in seawater pitting resistance.
No. 1 is a comparative example in which the average roughness Rz _JIS (L) and Rz _JIS (C) exceed 1.0. Both CPT and CCT have not reached the target of 40 ° C and 20 ° C, and they have poor seawater pitting resistance.
No. 2 is a comparative example in which the average roughness Rz _JIS (L) exceeds 1.0 μm and the average ratio (average L / C) of the average roughness Rz _JIS in two directions exceeds 2.0 . Both CPT and CCT have not reached the target of 40 ° C and 20 ° C, and they have poor seawater pitting resistance.
No. 3 is a comparative example in which the ratio of the average roughness Rz _JIS in two directions (average L / C) exceeds 2.0. Both CPT and CCT have not reached the target of 40 ° C and 20 ° C, and they have poor seawater pitting resistance.

Claims (2)

Rolled (longitudinal) direction (measured in accordance with JIS B 0601-2001) on a stainless clad steel surface comprising stainless steel having a pitting corrosion index PI of 35.0 or more as a combination material ( L) average roughness Rz _JIS (L) is 1.0 μm or less, average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) is 1.0 μm or less, and the rolling at each measurement point ( Longitudinal) direction (L) average roughness Rz _JIS (L) and average ratio R / L of the average roughness Rz _JIS (C) in the direction perpendicular to the rolling direction (C) (L / C) resistance C is a range der of 0.5 to 2.0 is, the number of sulfide inclusions of the stainless clad steel surface, characterized in der Rukoto 2.5 × 10 ⁵ cells / mm ² or less Stainless clad steel with excellent seawater pitting resistance.
The pitting index PI is an index represented by Cr (mass%) + 3Mo (mass%) + 16N (mass%). Cr concentration (at%) / Fe concentration (at%) in the passive film portion formed on the surface of the stainless clad steel and Cr concentration (at%) / Fe concentration (at%) of the stainless steel as the parent phase The stainless clad steel excellent in seawater pitting corrosion resistance according to claim 1, wherein the ratio is 1.2 or more.