JP6082625B2 - Stainless steel strip manufacturing method - Google Patents

Description

  The present invention relates to a technique for removing oxide scale formed on the surface of stainless steel by hot rolling and subsequent bell annealing or continuous annealing.

  For descaling of a stainless steel hot-rolled annealed steel strip, descaling equipment generally composed of a scale breaker (repetitive bending), shot blasting, and a pickling tank is used. As the pickling solution, hydrofluoric acid is often used, but hydrochloric acid is sometimes used. In some cases, a pretreatment such as a sulfuric acid tank is used in combination.

  In order to improve the descaling ability, it is effective to increase the concentration and temperature of the pickling solution. However, both the concentration and temperature are already high at present, and further improvement is difficult considering the load on the equipment and work environment.

  Therefore, methods for improving the descaling ability by strengthening methods other than pickling are also being studied. Patent Document 1 discloses a method in which a brush roll is disposed and descaling by surface grinding is used in combination. The brush roll is effective in descaling, but the amount of wear of the brush is large, which increases the manufacturing cost. A ground defect may be caused by rolling and may be pushed into the substrate to cause surface defects.

  Patent Documents 2 and 3 disclose techniques for improving descaling ability by actively utilizing shot blasting equipment in particular. Patent Document 2 is a technique for increasing the projection energy of shot blast to increase the descaling ability and suppressing the deterioration of the surface quality accompanying the increase in the projection energy by adding a pickling accelerator to the pickling solution. Patent Document 3 is a technique for performing descaling only by shot blasting and surface grinding without performing pickling treatment by specifying in detail the shot blasting projection conditions.

JP 7-51729 A JP 9-143768 A JP 2008-207203 A

  Considering the cost, it is preferable to perform descaling only by a scale breaker, shot blasting, and pickling without using a pickling accelerator or excessive surface grinding. Therefore, the inventors examined a descaling technique using a scale breaker, shot blasting, and pickling treatment using the technique of Patent Document 3. However, since Patent Document 3 is premised on surface grinding, the expected effect cannot be obtained for descaling by the combined use of shot blasting and pickling.

  This invention makes it a subject to provide the descaling technique of a stainless steel annealed steel strip by a scale breaker, shot blasting, and a pickling process.

In the present invention, in order to achieve the above object, when the shot blast treatment is performed on the surface of the stainless hot-rolled annealed steel strip, the average particle diameter of the projection material is 0.25 to 0.30 mm, and the projection speed is 40 to 100 m / s. The projection energy is in the range of the following formula according to the annealing method and the Cr content of the steel material, followed by pickling.
Bell annealed stainless steel strip: 5 / 3Cr ² + 200 / 3Cr + 760 (kJ / m ² ) or more Continuous annealed stainless steel strip: 50 (kJ / m ² ) or more Projection energy is 0.5 × projection density × projection speed ² .
Here, Cr in the formula is the Cr content (% by mass) of the steel material.

  The bell-annealed stainless steel strip is a steel containing Cr: 11.0 to 19.0 mass%, and is a stainless steel strip that has been subjected to heat treatment at 700 to 900 ° C. for 3 to 30 hours after hot rolling. Say.

  Continuously annealed stainless steel strip is a steel containing Cr: 11.0 to 35.0 mass%, and is a stainless steel strip that has been subjected to heat treatment at 700 ° C. or higher for 1 hour or less after hot rolling. That means.

The pickling treatment is performed by dipping in an aqueous hydrofluoric acid solution having an HF concentration of 1 to 50 g / l, an HNO ₃ concentration of 20 to 150 g / l, a metal content of 60 g / l or less, and a liquid temperature of 30 to 60 ° C.

Further, it may be combined with a known pickling method such as electrolysis in an aqueous solution of Na ₂ SO ₄ , immersion in an aqueous solution of H ₂ SO ₄ , immersion in an aqueous solution of FeCl ₃ .

  According to the present invention, according to the present invention, the stainless steel hot-rolled annealed steel strip can be descaled by scale breaker, shot blasting, and pickling without using excessive surface grinding with a pickling accelerator or brush roll. It can be carried out.

The cross-sectional form of the oxide scale of the hot rolled material and the Cr concentration immediately below the oxide scale are shown. The surface appearance and descaling judgment value of SUS after immersion in hydrofluoric acid are shown. The relationship between the descaling judgment value after immersion in hydrofluoric acid and the projection energy is shown. Relationship between Cr amount and projection energy required for descaling The difference in surface appearance between the inventive example and the comparative example is shown.

  For the actual line hot-rolled / annealed material of SUS410, SUS430, SUS430LX, and SUS304 having the composition shown in Table 1, investigation of the oxide scale and investigation of descalability by shot blasting and pickling were performed.

In FIG. 1, the SUS410 hot-rolled / bell-annealed steel strip, SUS430 hot-rolled / bell-annealed steel strip, SUS430LX hot-rolled / continuous-annealed steel strip, SUS304 hot-rolled / continuous-annealed steel strip and the underlying substrate were investigated. Results are shown.
SUS410 has a thick oxide scale, and no decrease in Cr concentration was observed in the substrate immediately below the oxide scale. Although SUS430 has a thinner oxide scale than SUS410, a decrease in Cr concentration was not observed in the substrate directly under the oxide scale, as in SUS410. On the other hand, SUS430LX and SUS304 had a thinner oxide scale than SUS430, and a region in which the Cr concentration decreased immediately below the oxide scale was observed.

  It is considered that the thinner the oxide scale, the easier the oxide scale peeling or crack formation occurs by shot blasting. In addition, when the Cr concentration directly under the oxide scale is low, even if the oxide scale is peeled off or cracks are not sufficiently formed, the region where the Cr concentration is low is dissolved by the subsequent pickling treatment, and the possibility of descaling is high. it is conceivable that. Therefore, the shot blasting conditions and pickling conditions affecting the descalability of each steel type were examined in detail.

Each stainless steel annealed steel strip was subjected to bending and bending back processing with a scale breaker on a real line, then cut into a size of 100 mm × 100 mm, and subjected to shot blasting with a laboratory machine. The projectile was an iron ball having an average particle size of 0.45 mm, and the projection speed was changed in the range of 40 to 100 m / s and the projection density in the range of 15 to 90 kg / m ² . The steel plate after shot blasting was immersed for 40 s in an aqueous hydrofluoric acid solution having an HF concentration of 15 g / l, an HNO ₃ concentration of 90 g / l, a metal content of 26 g / l, and a liquid temperature of 50 ° C.

  FIG. 2 shows an example of the surface appearance of SUS410 after being immersed in a hydrofluoric acid aqueous solution. As shown in FIG. 2, the state where the oxide scale remained almost entirely was set to 0, and the state where the oxide scale was completely removed was set to 3, and the degree of descaling was determined.

FIG. 3 shows the relationship between the descaling judgment value of each stainless steel and the shot blast projection energy. The projection energy is the total kinetic energy of the projection material projected per unit area, and was calculated as 0.5 × projection density × projection speed ² . As can be seen from FIG. 3, SUS410 was able to be completely descaled when the projection energy was 200 kJ / m ² or more. SUS430 could be completely descaled when the projection energy was 120 kJ / m ² or more. SUS430LX and SUS304 could be completely descaled at a projection energy of 50 kJ / m ² or more.

  The reason why the required projection energy differs depending on the steel type is that, as already described, the thickness of the oxide scale and the situation of Cr deficiency directly under the oxide scale are different. Then, the relationship between the amount of Cr and the projection energy required for descaling was investigated using various stainless steel strips with different Cr. FIG. 4 shows the evaluation results.

In the bell-annealed stainless steel strip, the larger the Cr content, the thinner the oxide scale and the smaller the required projection energy. From FIG. 4, the required projection energy was determined to be 5 / 3Cr ² + 200 / 3Cr + 760 (kJ / m ² ).

In the continuously annealed stainless steel strip, the required projection energy was 50 kJ / m ² regardless of the Cr content. This is presumably because a Cr-deficient region exists directly under the oxide scale.

By performing the shot blast treatment specified in the present invention, and then performing the pickling treatment, the descaling of the stainless steel hot-rolled annealed steel strip can be performed without using excessive surface grinding with a pickling accelerator or a brush roll. It can be carried out.
Hereinafter, matters for specifying the present invention will be described.

  When the average particle diameter of the projection material is less than 0.25 mm, the speed is lowered due to friction with air or the like, and a sufficient effect cannot be obtained. On the other hand, if the average particle size exceeds 0.80 mm, the contact area with the steel strip per projection material decreases, and the area where the projection material is not applied increases instead of the projection density, so the expected effect is obtained. It becomes impossible. Therefore, the average particle diameter of the projection material is set to 0.25 to 0.80 mm.

  When the projection speed is slow, it is necessary to increase the projection amount in order to obtain the necessary projection energy. On the other hand, if the projection speed is too high, the load on the equipment increases. Therefore, in this invention, a projection speed shall be 40-100 m / s.

In the pickling treatment, if the HF is less than 2 g / l and the HNO ₃ concentration is less than 20 g / l, the pickling ability is lowered, and the productivity is lowered. On the other hand, when the HF concentration and the HNO ₃ concentration are increased, the load on the facility and the work environment is increased. Accordingly, in the present invention, the HF concentration is 2 to 50 g / l and the HNO ₃ concentration is 20 to 150 g / l.

  As the stainless annealed steel strip is descaled, the metal is eluted in the pickling solution. As the metal concentration increases, descalability decreases, so it is preferable to keep the metal concentration low. However, in order to reduce the metal concentration, renewal of the liquid or ion exchange treatment is required, which causes an increase in cost. Therefore, in the present invention, a metal content of 60 g / l is allowed.

  When the temperature of the pickling solution is low, the pickling ability is lowered, and when the temperature is high, the load on the facility and the working environment is increased.

  Scaled to SUS410 hot-rolled / bell-annealed steel strip, SUS430 hot-rolled / bell-annealed steel strip, SUS430LX hot-rolled / continuously-annealed steel strip, SUS304 hot-rolled / continuously-annealed steel strip having a thickness of 4.5 mm with the composition shown in Table 1. After being bent and bent back by a breaker, shot blasting was performed. In the shot blast treatment, a projection material having an average particle diameter of 0.5 mm was used and the projection was performed at a projection speed of 75 m / s.

In the example of the invention, the projecting amount is 80 kg / m ^{2 for} the SUS410 hot rolled / bell annealed steel strip, 50 kg / m ^{2 for} the SUS430 hot rolled / bell annealed steel strip, SUS430LX hot rolled / continuously annealed steel strip. SUS304 hot-rolled / continuously annealed steel strip was set at 30 kg / m ² .

In the comparative example, the projection amount is 60 kg / m ^{2 for} the SUS410 hot rolled / bell annealed steel strip, 30 kg / m ^{2 for} the SUS430 hot rolled / bell annealed steel strip, SUS430LX hot rolled / continuously annealed steel strip. SUS304 hot-rolled / continuously annealed steel strip was set to 10 kg / m ² .

The shot stainless steel strip after shot blasting was dipped in an aqueous hydrofluoric acid solution having an HF concentration of 15 g / l, an HNO ₃ concentration of 90 g / l, a metal content of 26 g / l, and a liquid temperature of 50 ° C. for 40 s to perform pickling.

  FIG. 5 shows the appearance of the surface after descaling. No scale residue was observed in the inventive examples. On the other hand, in the comparative example, a scale residue was observed in any steel type, and descaling was insufficient.

  As described above, according to the present invention, descaling of a stainless steel hot-rolled annealed steel strip can be performed by scale breaker, shot blasting, and pickling without using excessive surface grinding with a pickling accelerator or a brush roll. It can be carried out.

Claims (2)

A stainless steel strip manufactured by performing descaling by pickling treatment after performing shot blasting on the surface of the stainless hot-rolled annealed steel strip, the average particle size of the projection material being 0.25 to 0.80 mm, A method for producing a stainless steel strip in which the projection speed is 40 to 100 m / s, the projection energy is in the range of the following formula according to the annealing method and the Cr amount, and subsequently pickling.
Bell annealed stainless steel ^{strip: 5 / 3Cr 2 + 200 /} 3Cr + 760 (kJ / m 2) or more continuous annealing of stainless steel strip: 50 (kJ / ^{m 2)} or more projection energy is 0.5 × projection density × blasting speed ² .
Here, Cr in the formula is the Cr content (% by mass) of the steel material. 2. The technique according to claim 1, wherein the pickling treatment is immersed in an aqueous hydrofluoric acid solution having an HF concentration of 2 to 50 g / l, an HNO ₃ concentration of 20 to 150 g / l, a metal content of 60 g / l or less, and a liquid temperature of 30 to 60 ° C. To manufacture stainless steel strip.