JP3548314B2 - Steel sheet for cans with few defects and excellent aging and method for producing the same - Google Patents

Description

【００２４】
【表２】

【００２５】
【発明の効果】
本発明によって、製缶時の欠陥発生の少ない時効性に優れた缶用鋼板の製造が可能となった。[0001]
TECHNICAL FIELD OF THE INVENTION
TECHNICAL FIELD The present invention relates to a steel sheet for a can which has a small number of defects during can manufacturing and has excellent aging, and a method for producing the same.
[0002]
[Prior art]
Normally, a two-piece steel plate for cans is made of Al-killed steel that deoxidizes undeoxidized molten steel produced in a converter with Al. In such Al-deoxidized steel, Al added at the time of deoxidation reacts with oxygen in the molten steel, or Al remaining in the steel after deoxidation is oxidized by oxygen in slag, air or the like to produce alumina. Since this alumina is hard, it remains in a lump in the steel sheet without being crushed by rolling or processing, and causes defects such as cracks and flaws during can making. Therefore, by controlling the oxygen in the slag and atmosphere in these aluminas, it is possible to prevent the generation of alumina by oxidizing Al in the molten steel, and to reduce the amount of alumina by promoting the floating of alumina in the molten steel by blowing gas and flux into the molten steel. In addition, detoxification has been performed by controlling the form of calcium aluminate which is easily crushed during rolling and working by adding Ca to molten steel.
[0003]
However, as long as deoxidation is performed with Al, generation of alumina cannot be eliminated at all, and the removal is insufficient. The Ca addition method is also expensive, and the yield is extremely poor, so that the alloy cost is high. Further, since the inclusions contain alumina, hard alumina partially crystallizes in the inclusions during cooling, and remains without being crushed even by rolling or the like, and defects occur. Furthermore, calcium aluminate generated by adding Ca tends to be enlarged, and if such inclusions are not completely lifted and remain, they become defects. In order to solve these problems, it is conceivable to deoxidize with an element other than Al. As shown in JP-B-48-29005, a method of deoxidizing with only Ti without adding any Al or Si. However, in this case, the oxygen in the molten steel before the addition of Ti has a very high value due to deoxidation by only Mn, and when Ti is added to such molten steel, a large amount of titanium oxide having a large particle size is generated. It remains in the molten steel and becomes a defect because it is hard and not easily crushed like alumina.
For this reason, as disclosed in Japanese Patent Publication No. 2-9646, there is a method in which Al is added before Ti is added to perform preliminary deoxidation to reduce molten steel oxygen, and then Ti is added.
[0004]
In the method as described above, since Al is added, a large amount of alumina is generated and remains as it is, or a composite inclusion containing alumina is generated and alumina crystallizes in a part of the inclusion at the time of cooling. The part remains without being crushed even by rolling or the like, and a defect occurs. In addition, since Al has a strong deoxidizing power, control of oxygen is unstable. Further, when Ti is added, part of the titanium oxide generated by the reaction between Ti and oxygen in the molten steel becomes a composite inclusion, but since this composite oxide contains alumina, it is contained in the inclusion during cooling. The crystallized alumina remains without being crushed, causing defects. On the other hand, most of the generated titanium oxide has a large particle size and is hard to be crushed and exists in molten steel as titanium oxide, and some of the titanium oxide remains without floating and remains as a defect. is there.
[0005]
Further, in general low-carbon Al-killed steel, when annealing is performed by continuous annealing, most of C and N exist in a solid solution state. In order to prevent aging due to solid solution C and solid solution N, high temperature winding by hot rolling and rapid cooling and overaging in continuous annealing promote precipitation and fixation of solid solution C and solid solution N to prevent aging. However, since the precipitation fixation was not sufficient, the actual condition was that aging due to solid solution C and solid solution N could not be suppressed.
[0006]
[Problems to be solved by the invention]
The present invention has been made in order to solve such a problem, and includes inclusions having a composition in which inclusions in steel are fine, and there is no partially hard crystallization phase, and the entire inclusion is easily deformed and fractured. To reduce the number of inclusion defects at low cost, and to precipitate and fix the solute N and solute C in the steel as a carbonitride of Ti and Nb by Ti and Nb. An object of the present invention is to provide a steel sheet for cans excellent in aging property such as not causing a stretcher strain due to aging in order to reduce the solid solution C content, and a method for producing the same.
That is, in the present invention, the inclusions in the steel are controlled to be fine and inclusions having a composition in which the entire inclusions are easily deformed and crushed without a partially hard crystallization phase, and there are few inclusion defects at low cost. An object of the present invention is to provide a steel sheet for cans excellent in aging and a method for producing the same.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the present invention
(1) in mass%,
C: 0.0002-0.0080%,
Si: 0.001 to 0.10%,
Mn: 0.05-1.0%,
P: 0.001 to 0.050%,
S: 0.001 to 0.030%,
N: 0.0005 to 0.0080%,
Ti: 0.002 to 0.030%,
Nb: 0.003 to 0.070 %,
And Ti (%) + (48/93) × Nb (%)
≧ (48/12) × C (%) + (48/14) × N (%) (A)
Aging with less defects characterized by having oxide-based inclusions consisting of titanium-based oxides, manganese-based oxides, and silicon-based oxides in the steel consisting of iron and unavoidable impurities Steel plate for cans,
(2) mass%,
C: 0.0002-0.0080%,
Si: 0.001 to 0.10%,
Mn: 0.05-1.0%,
P: 0.001 to 0.050%,
S: 0.001 to 0.030%,
N: 0.0005 to 0.0080%,
Ti: 0.002 to 0.030%,
Nb: 0.003 to 0.070 %
And Ti (%) + (48/93) × Nb (%)
≧ (48/12) × C (%) + (48/14) × N (%) (A)
Is satisfied,
B: 0.0002 to 0.0050%
Containing iron and the balance of iron and unavoidable impurities, the steel has oxide-based inclusions consisting of titanium-based oxides, manganese-based oxides, and silicon-based oxides. Steel plate for cans,
(3) The oxygen content in the steel of the molten steel after refining is deoxidized to 300 ppm or less, and then Ti is added to obtain a steel having the composition described in (1) or (2) above, and the steel is continuously cast and hot rolled. After that, it is wound up at 600 ° C to 750 ° C, then is descaled, cold rolled, and then continuously annealed at 650 ° C to 900 ° C. Manufacturing method of steel sheet for cans,
(4) The molten steel after refining is subjected to vacuum degassing treatment and / or one or two types of Si and Mn are added to deoxidize the oxygen content in the steel to 300 ppm or less, and then Ti is added. (3) The method for producing a steel sheet for cans having a small number of defects and excellent aging according to (3),
(5) After deoxidation of the oxygen content in the molten steel after the refining to 300 ppm or less, the chemical composition is composed of 10 to 75% by mass of Ti, and one to three of Fe, Mn, and Si and inevitable impurities. (3) The method for producing a steel sheet for cans according to the above (3), which has a small number of defects and excellent aging characteristics, characterized by adding an alloy.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
The present inventors artificially synthesized inclusions having various compositions, embedded them in steel, and performed a rolling experiment in a laboratory. As a result, if the inclusions are composed mainly of titanium oxide, manganese oxide, and silicon oxide that do not contain alumina, the melting point is low, and a high-melting solid phase is formed during cooling. Instead, they were found to be finely crushed by rolling or the like.
A steel in which such inclusions are dispersed is smelted and cast in a laboratory, and hot rolled, pickled, cold rolled, annealed, temper rolled, and plated in a usual manner to obtain a steel sheet. Defects such as cracks occurred in some steel plates when the can was performed. As a result of investigating the portion of this defect, an elongated inclusion was detected in the defective portion, and the size of the inclusion was measured. As a result, the size was larger than 50 μm when converted to the size of the slab. It turns out. When the portion where no defect occurred was cut and the size of the inclusions in the steel was measured, inclusions of 50 μm or less were detected. In the case of inclusions larger than 50 μm, even if they are stretched or deformed under the pressure of rolling or the like, they remain unfractured and continuous, or even if they are crushed, their grains are largely continuous, causing defects during can making. Conceivable.
[0009]
From the above, it was presumed that inclusions of 50 μm or less did not become defects, so only inclusions of a composition mainly containing titanium oxide, manganese oxide, and silicon oxide not containing alumina of 50 μm or less were used. In a laboratory, a steel having dispersed therein is melted and cast, and hot-rolled, pickled, cold-rolled, annealed, temper-rolled, and plated by ordinary methods to obtain solid solution C and solid solution in steel. When a steel plate was formed into a steel plate on which dissolved N was deposited and fixed, and canning was performed, it was confirmed that aging was good and no defects were generated.
[0010]
As a result of an experiment conducted by changing the concentration of Ti to be added, it was found that in order to obtain an inclusion having a composition mainly containing titanium oxide, manganese oxide, and silicon oxide containing no alumina, the Ti concentration was set to 0.030. % Or less. This is because if Ti is too high, the deoxidizing power of Ti is higher than that of Mn or Si, so that it does not combine with these oxides, and an inclusion having a high melting point and a high content of titanium oxide similar to alumina is generated. It is. On the other hand, the lower limit of Ti is set to 0.002% in order to prevent bubbles from being generated due to insufficient deoxidation during continuous casting. The remaining Ti used for deoxidation is used together with Nb added after deoxidation to precipitate and fix the solid solution C and solid solution N in the steel. And the amount calculated by adding 0.002% required for deoxidation to the amount calculated from the above. By satisfying the formula (A), the amount of solid solution C and solid solution N in the steel after plating becomes 4 ppm or less, and the aging property is improved.
[0011]
Further, in order to obtain inclusions containing almost no alumina, it is preferable that Al is inevitably mixed without being added at all. When Al is added, the deoxidizing power of Al is higher than that of Ti, so that manganese oxide and silicon oxide are reduced, and the composite inclusion of the present invention cannot be stably formed. In addition, alumina is generated in the steel, and alumina is contained in the inclusions, and the inclusions have a high melting point and are hard to be crushed.
[0012]
Next, the production method of the present invention will be described in detail.
First, a target molten steel containing 0.0002 to 0.0080% of C is smelted in a converter. At this time, if the C in the molten steel is higher than the target C concentration, the steel is subjected to decarburization treatment using a vacuum degassing device or the like after tapping to reduce the C concentration to a predetermined C concentration, and if the C concentration is lower than the target C concentration. After tapping, C is added to a predetermined C concentration. If the C content is reduced to less than 0.0002%, the cost increases and the economic efficiency is greatly impaired. Therefore, the lower limit is 0.0002%, and if it exceeds 0.0080%, the amount of solid solution C in the steel is fixed. Since the addition amount of Ti or Nb increases and hardening due to precipitation of carbonitride becomes remarkable, it becomes impossible to work as a can. Therefore, the upper limit is 0.0080%.
[0013]
Next, the molten steel that has been tapped is preliminarily deoxidized by Mn, Si and / or vacuum degassing to reduce the oxygen in the molten steel to 300 ppm or less. In order not to include alumina in the inclusions, it is necessary not to add Al, and Fe-Mn or Fe-Si is added and deoxidation is performed by Mn and Si. The addition amount of Mn and Si is added in consideration of the increase amount due to Si and Mn contained in the Ti alloy added at the time of deoxidation. In addition, since Mn and Si have weak deoxidizing power, it may be difficult to reduce oxygen in molten steel to 300 ppm or less within a target range depending on a product. In this case, vacuum degassing is performed by vacuum degassing. And lower the oxygen. At this time, if necessary, a C source may be added to the molten steel. When oxygen in molten steel is higher than 300 ppm, it is necessary to add a large amount of Ti alloy, and as described later, the degree of supersaturation at the time of deoxidation increases, and titanium oxide having a high melting point similar to alumina at the time of adding Ti is added. Are generated in large numbers, and composite inclusions are not generated stably. In addition, these aggregate to form large inclusions.
[0014]
In this way, the oxygen in the molten steel in the molten steel was adjusted to 300ppm or less, the chemical composition Ti: 10 to 75 mass% of component and the balance being Fe, Mn, and three and unavoidable impurities from one kind of Si Is added to make 0.002 to 0.030% of Ti as a molten steel component.
By setting the Ti concentration in the molten steel to 0.030% or less, a composite inclusion having a composition mainly composed of titanium oxide, manganese oxide, and silica can be obtained. If the Ti concentration in the molten steel is too high, the deoxidizing power of Ti is higher than that of Mn or Si, so that it does not composite with these oxides, and a high-melting-point titanium oxide similar to alumina becomes the main component inclusion. .
[0015]
Furthermore, if the degree of supersaturation at the time of deoxidation is reduced, the nucleation rate is reduced, and the number of inclusions and the diameter of the inclusions are reduced. Since the degree of supersaturation is determined by the product of Ti and oxygen, it is effective to reduce the degree of supersaturation by lowering the Ti content in the deoxidized alloy and lowering the oxygen in the molten steel during deoxidation. If the Ti content in the deoxidized alloy is high, a portion with a high Ti concentration is formed around the deoxidized alloy added to the molten steel and the degree of supersaturation increases, so use a deoxidized alloy with a low Ti content. I do. Inclusion diameter decreases as the oxygen concentration and the Ti content in the alloy decrease, and oxygen is reduced to 300 ppm or less and deoxidation is performed using an alloy having a Ti content of 75% or less, so that an inclusion having a maximum of 50 μm or less is obtained. Things. Increasing the Ti content increases the size of the inclusions, and at the time of deoxidation, inclusions having a high proportion of titanium oxide are generated, which remain and are mixed in the molten steel. If the Ti concentration is too low, the input amount of the deoxidized alloy becomes too large, and the temperature of the molten steel decreases, which makes it difficult to solidify or cast the molten steel, and it takes a long time to add the molten steel, thereby impairing productivity. In addition, when the Ti content is high, it is effective to add a small amount at a time, since a portion having a high degree of supersaturation partially decreases.
In addition, by using Ti as an alloy with Fe, Si, and Mn, the activity of Ti is reduced and a region with a high concentration is partially reduced, so that the degree of supersaturation is further reduced, and titanium oxide and manganese oxide are reduced. Promotes the formation of composite inclusions of silicon oxide and silicon oxide.
[0016]
Finally, if the content of Mn contained in the steel is reduced to less than 0.05%, refining time becomes longer and economic efficiency is greatly impaired. Therefore, the lower limit is 0.05% and the content exceeds 1.0%. In addition, the workability of the steel sheet is greatly deteriorated, and it becomes impossible to work as a can. Therefore, the upper limit is 1.0%.
If the amount of Si is reduced to less than 0.001%, sufficient pretreatment is required, so that refining costs a great deal of cost and impairs economic efficiency. Therefore, the lower limit is 0.001%, and when it exceeds 0.1%, plating is performed. In this case, plating failure occurs, impairing surface properties and corrosion resistance, so the upper limit is 0.1%.
[0017]
When P is reduced to less than 0.001%, it takes time and cost for hot metal pretreatment, and the economic efficiency is greatly impaired. Therefore, the lower limit is 0.001%, and if it exceeds 0.050%, the workability deteriorates, 0.050% is made the upper limit because it interferes with processing as a can.
Lowering S to less than 0.001% requires time and cost for hot metal pretreatment and greatly impairs economic efficiency. Therefore, the lower limit of S is 0.001%, and if it exceeds 0.030%, workability and corrosion resistance deteriorate. However, 0.030% is set as the upper limit because it interferes with processing and performance as a can.
[0018]
When N is reduced to less than 0.0005%, the cost is significantly increased in the refining stage and the economic efficiency is greatly impaired. Since a large amount of Ti must be added to eliminate the elimination, and the form control of inclusions, which is the object of the present application, becomes impossible, the upper limit is 0.0080%.
If the amount of Nb exceeds 0.07%, the recrystallization temperature during continuous annealing will increase, so the upper limit is made 0.070%. If it is less than 0.003 %, the crystal grains become coarse and the moldability of the can deteriorates . Therefore , the lower limit is made 0.003 %.
B is a nitride-forming element, and when Ti is added, N binds preferentially to Ti, so that B precipitates at the grain boundaries and prevents grain boundary cracking. The effect appears at 0.0002% or more, and when it exceeds 0.0050%, the aging property is deteriorated. Therefore, the range is set to 0.0002% to 0.0050%.
[0019]
The molten steel thus produced is passed through a tundish in a conventional manner and cast by a continuous casting machine. Further, heating is appropriately performed prior to hot rolling, and the slab is hot-rolled by a conventional method, and thereafter, is wound up in a temperature range of 600 ° C to 750 ° C. If the temperature is lower than 600 ° C, precipitation of solid solution N and solid solution C by Ti and Nb is insufficient, and the aging property of the product is deteriorated. Therefore, the lower limit is 600 ° C. 750 ° C. is set as the upper limit because the skin becomes rough and the appearance is impaired. Next, descaling is performed. Generally, pickling is performed, but scale removal may be performed mechanically. Thereafter, cold rolling is performed and continuous annealing is performed. The temperature of the continuous annealing is 650 ° C to 900 ° C. If the temperature is lower than 650 ° C., recrystallization does not occur and the workability is deteriorated. Therefore, the lower limit is 650 ° C., and if it exceeds 900 ° C., the high-temperature strength of the steel sheet is weakened, causing a phenomenon called drawing in a continuous annealing furnace and causing problems such as breakage. Therefore, the upper limit is set at 900 ° C. Thereafter, skin pass rolling or double reduction rolling of about 5 to 40% is performed, and a surface treatment such as chrome plating or tin plating is performed to obtain a steel plate for a can. It is also possible to use a steel plate having a resin film adhered to the surface. These steel sheets are particularly suitable as steel sheets for two-piece cans.
[0020]
【Example】
Using a deoxidizing alloy having an alloy composition shown in Table 2 in a 270 ton converter, steel of each component was melted and continuously cast. Table 1 shows the components of the manufactured steel and the composition of the inclusions in the steel. Then, heating-hot rolling was performed. At that time, finish rolling and winding were performed at the temperatures shown in Table 2. Next, after pickling and cold rolling, annealing was performed at the temperatures shown in Table 2. After annealing, some of them were subjected to DR rolling (double reduce rolling). Subsequently, chrome plating or tin plating was applied, and a polyethylene terephthalate resin film was adhered to the front and back surfaces of some steel sheets to form steel sheets for cans.
[0021]
A part of the slab and a part of the cold-rolled steel sheet were sampled, the cross section was investigated, and the composition, size and shape of the inclusions were investigated. Table 1 shows the results. According to the method of the present invention, substantially spherical inclusions having a composition mainly composed of titanium oxide, manganese oxide, and silicon oxide are detected in the slab, and the concentration of inclusions including alumina and the concentration of titanium oxide are detected. High inclusions were not detected. In the cold-rolled steel sheet, these inclusions were crushed and finely dispersed.
[0022]
Further, using the obtained steel sheet for cans, a drawn can formed by three-step drawing and a DI can obtained by drawing and ironing were manufactured, and the defect rate at which cracks occurred at this time was investigated. Table 2 shows the results. It can be seen that the steel of the present invention has a lower defect rate than the comparative steel. In addition, the presence or absence of a stretcher strain generated at the bottom of the can was examined. As a result, it was confirmed that the steel of the present invention did not generate a stretcher strain and exhibited excellent aging performance.
[0023]
[Table 1]

[0024]
[Table 2]

[0025]
【The invention's effect】
ADVANTAGE OF THE INVENTION By this invention, the manufacture of the steel plate for cans which has few defects at the time of can manufacture and was excellent in aging property became possible.

Claims (5)

In mass%,
C: 0.0002-0.0080%,
Si: 0.001 to 0.10%,
Mn: 0.05-1.0%,
P: 0.001 to 0.050%,
S: 0.001 to 0.030%,
N: 0.0005 to 0.0080%,
Ti: 0.002 to 0.030%,
Nb: 0.003 to 0.070%
And Ti (%) + (48/93) × Nb (%)
≧ (48/12) × C (%) + (48/14) × N (%) (A)
Satisfies the following conditions, the balance of iron and unavoidable impurities in the steel, a titanium-based oxide, manganese-based oxide, a defect characterized by having an oxide-based inclusions composed of silicon-based oxides Small steel plate for cans with excellent aging. In mass%,
C: 0.0002-0.0080%,
Si: 0.001 to 0.10%,
Mn: 0.05-1.0%,
P: 0.001 to 0.050%,
S: 0.001 to 0.030%,
N: 0.0005 to 0.0080%,
Ti: 0.002 to 0.030%,
Nb: 0.003 to 0.070%,
And Ti (%) + (48/93) × Nb (%)
≧ (48/12) × C (%) + (48/14) × N (%) (A)
Satisfies the following conditions,
B: 0.0002 to 0.0050%
Containing steel and the balance of iron and unavoidable impurities, the steel has oxide inclusions consisting of titanium oxide, manganese oxide, and silicon oxide. Steel sheet for cans with excellent properties. The oxygen content in the steel of the molten steel after refining is deoxidized to 300 ppm or less, and then Ti is added to obtain a steel having the composition according to claim 1 or 2, and after continuous casting and hot rolling, the steel is heated to 600 ° C. Winding at 750 ° C., then descaling, cold rolling, continuous annealing at 650 ° C. to 900 ° C., and a steel plate for cans through a plating process. Manufacturing method for steel sheet. The molten steel after refining, was deoxidized vacuum degassing and Si, one or steel oxygen amount by performing either one or both of the two addition of Mn to 300ppm or less, characterized in that the addition of Ti The method for producing a steel sheet for cans according to claim 3, which has few defects and excellent aging. After deoxidation of the oxygen content of the molten steel to 300 ppm or less in the molten steel after the refining, an alloy having a chemical composition of Ti: 10 to 75% by mass and the remaining Fe, Mn, and Si and one or three kinds of unavoidable impurities is added. 4. The method for producing a steel sheet for cans according to claim 3, which has few defects and excellent aging.