JP3358871B2 - Manufacturing method of stainless steel strip - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a stainless steel strip having good productivity.

[0002]

2. Description of the Related Art Stainless steel strips have various surface finishes, for example, BA finishes, Nos. 1 to 3 as specified in JIS G4305, in order to meet various applications. 2B finish, No. A 2D finish and a polished finish are applied to the surface to produce a product.

FIG. 6 is an explanatory view showing a manufacturing process of a BA-finished stainless steel strip according to the prior art. The BA finish is obtained by performing a bright heat treatment after cold rolling. When an austenitic hot-rolled stainless steel strip represented by, for example, SUS304 is used as a starting material, the hot-rolled stainless steel strip is passed through an annealing descaling step 41 to be subjected to an annealing descaling treatment. Annealing descaling is performed by a series of annealing descaling equipment including an annealing device and a descaling device as disclosed in, for example, JP-A-59-41482. The descaling device is usually configured by combining mechanical treatment and chemical treatment in order to increase the descaling effect and to perform the descaling efficiently. The stainless steel strip is subjected to an annealing descaling process 41.
Then, the sheet is passed through the flaw removing step 42. In the flaw removal step 42, a continuous polishing apparatus is provided. In the flaw removal step 42, flaws and defective layers on the surface of the stainless steel strip are removed. The flaw removal is performed using an endless rotating belt coated with an abrasive having a relatively large particle size.

[0004] The stainless steel strip is passed through a reversing rolling step 43 following the flaw removing step 42. In the reversing rolling process 43, a cluster type rolling mill, for example, a 12-stage cold mill or a 20-stage Sendzimir mill is provided. The 20-stage Sendzimir mill includes a rolling mill main body and front and rear winding reels for alternately rewinding or winding the stainless steel strip coil. The work roll of the 20-stage Sendzimir mill has a small diameter of about 40 to 120 mm, and a mineral oil is generally used as a rolling agent. This mineral oil is a low-viscosity mineral oil straight oil, and the rolled stainless steel strip has excellent surface gloss.
In the reversing rolling step 43, the stainless steel strip is repeatedly and reciprocally rolled by the rolling mill body and the front and rear winding reels until the sheet thickness reaches a predetermined value. The number of reversal rolling passes is about 6 to 10 passes. In general, the stainless steel strip has a large deformation resistance and is easy to work harden compared to ordinary steel, so the target stainless steel strip thickness is very thin. When the number of reversal rolling passes is extremely large, the stainless steel strip is repeatedly passed through an annealing descaling process 41 and a reversal rolling process 43. The next step of the reversal rolling step 43 is a bright annealing step 44. In the bright annealing step 44, a bright annealing furnace is provided. Bright annealing is performed to soften or anneal a stainless steel strip work-hardened by cold rolling without reducing the surface gloss. The stainless steel strip is passed through a bright temper rolling step 45 following the bright annealing step 44 to perform a bright temper rolling. In the bright temper rolling step 45, a temper rolling mill is provided. Bright temper rolling is performed at a low draft using a bright roll. The surface gloss of the stainless steel strip is further improved by bright temper rolling. The stainless steel strip is passed through a temper rolling step 45 and subsequently to a refining step 46 to perform a refining process. In the refining process 46, degreasing, cleaning, shape correction, shearing,
Edge trimming, slitting, packing, and the like are performed, and the BA finished product 47 is commercialized.

On the other hand, when a ferritic hot-rolled stainless steel strip represented by SUS430 is used as a starting material, the flaw removing step 42 is omitted. When the ferritic hot-rolled stainless steel strip is polished using a belt coated with an abrasive having a relatively large particle size in the flaw removing step 42, a deep polished surface is formed. The deep polished surface does not disappear even if cold rolling is performed in the subsequent reversal rolling step 43, and remains on the surface, so that the surface properties deteriorate. Therefore, for the ferritic stainless steel strip, the flaw removing step 4
2 is not performed. Other steps and equipment installed in each step are almost the same as those of the austenitic hot-rolled stainless steel strip.

[0006] FIG. 2B and No. It is explanatory drawing which shows the manufacturing process of a 2D finish stainless steel strip. No. 2B finishing, after cold rolling, heat treatment,
After pickling or a treatment similar thereto, it is finished by cold rolling so as to obtain an appropriate gloss. No. 2
The D finish is obtained by performing cold treatment, heat treatment, pickling or a treatment similar thereto, and then lightly cold rolling with a matte roll. No. 2B and No.
The manufacturing process for 2D finished stainless steel strip is the same for all starting materials. The hot-rolled stainless steel strip, which is a starting material, is subjected to annealing descaling in the annealing descaling step 41 and then cold rolled in the reversal rolling step 43. When the thickness of the target stainless steel strip is very thin, the stainless steel strip is repeatedly passed through the annealing descaling step 41 and the reversal rolling step 43, as in the case of the BA finished stainless steel strip. . After the final cold rolling is performed in the reversal rolling step 43, the stainless steel strip is subjected to the annealing descaling step 4
In 1, a final annealing descaling treatment (finishing annealing descaling treatment) is performed.

[0007] No. In case of 2B finish stainless steel strip,
The next step after the final annealing descaling step 41 is the bright temper rolling step 45. Bright temper rolling is
It is carried out with a light rolling reduction using a bright roll. An appropriate surface gloss is imparted to the surface of the stainless steel strip by bright temper rolling. The stainless steel strip passed through the bright temper rolling step 45 and the refinement step 46, and 2
It is commercialized as a B-finished product 49. No. In the case of a 2D finished stainless steel strip, the next step after the final annealing descaling step 41 is a dull temper rolling step 48. Dull temper rolling is performed at a light draft using a matte roll. Dull temper rolling imparts a silvery dull luster to the surface of the stainless steel strip. Stainless steel strip
Through the dull temper rolling step 48 and the refinement step 46,
No. It is commercialized as a 2D finished product 50.

FIG. 8 is an explanatory view showing the steps of manufacturing a polished stainless steel strip and a buff polished stainless steel strip according to the prior art. The types of the abrasive finishing materials are finely divided according to the abrasive particle size and are defined in JIS G4305. The manufacturing process for the polished and buff polished stainless steel strips is the same for all starting materials. The hot-rolled stainless steel strip as a starting material is subjected to the above No. until the final annealing descaling step 41. 2
B and No. It is manufactured in almost the same manufacturing process as a 2D finished stainless steel strip. Final annealing descaling step 41
The next step is a temper rolling step 51. Temper rolling 5
In 1, bright pass rolling or dull pass rolling is performed. The main purpose of this temper rolling is to produce a high-quality polished product or HL (hairline) finished polished product of a good quality in the subsequent polishing process, thereby producing a fine surface texture. This is performed to keep the steel strip and to correct (correct) the shape of the steel strip. In the case of a polished stainless steel strip, the next step of the temper rolling step 51 is a polishing step 52. In the polishing step 52, the stainless steel strip is made of an endless rotating belt coated with abrasives having various grain sizes for each grain size in order to produce abrasive products of various polishing counts and abrasive products with a specific HL finish. It is polished by a belt coated with a material. The particle size of the abrasive is specified in JIS G4305, and the particle size range of the abrasive is 100 to 400. After each of the stainless steel strips is polished and finished, the stainless steel strip goes through a refining process 46 to be produced as a polished finished product 54. In the case of a buff-polished stainless steel strip, buff polishing is performed in a buff polishing step 53 instead of the polishing step 52. The other steps are exactly the same as for the polished stainless steel strip. After the stainless steel strip is buff-polished, it is made into a buff-polished product 55 through a refining process 46.

[0009]

According to the prior art, a stainless steel strip is cold-rolled by a revers-type cluster rolling mill, for example, a 20-stage Sendzimir mill, for each surface finishing material. The 20-stage Sendzimir mill is provided with a work roll having a small diameter as described above, and uses mineral oil as a rolling agent. This mineral oil is a low viscosity mineral oil straight oil. For cold rolling agents, lubrication, roll cooling,
Cleanability and surface glossiness are required. Generally, lubricity improves as the oil film thickness increases. Since the oil film thickness increases as the viscosity of the rolling oil increases, the lubricity improves as the viscosity of the rolling oil increases. The surface gloss is obtained by rubbing the product surface with a work roll surface of a cold rolling mill through a thin film of rolling oil. Since the oil film thickness becomes thinner as the viscosity of the rolling oil is lower, the surface glossiness is improved as the viscosity of the rolling oil is lower. Also, when the oil film thickness is large, many oil pits are formed on the surface of the steel strip to be rolled, and the surface gloss is impaired. Therefore, the lower the viscosity of the rolling oil, the higher the surface gloss. Also, the smaller the diameter of the work roll,
Since the rolling oil hardly slips on the contact surface between the work roll and the stainless steel strip, the surface glossiness is improved. Therefore, when cold rolling is performed with a 20-stage Sendzimir mill using mineral oil as a rolling agent, the stainless steel strip exhibits extremely excellent surface gloss. However, the mineral oil has extremely poor roll cooling properties as compared with other rolling agents, for example, a solid oil obtained by dispersing a rolling oil in water to form an emulsion. When cold rolling is performed using a rolling agent having poor roll cooling properties, a rise in the temperature of the rolling rolls cannot be suppressed, so that lubricity is reduced and surface defects such as seizure, so-called heat scratches, are likely to occur. Therefore, when cold rolling is performed using mineral oil as a rolling agent, it is difficult to perform high-speed rolling under high pressure. When it is difficult to perform high-pressure high-speed rolling as described above, when rolling is performed with a reversible rolling mill, the number of rolling passes increases and the number of rolling passes increases.
Since the rolling time per pass becomes longer, efficiency and productivity are greatly reduced.

An object of the present invention is to provide a manufacturing method capable of stably manufacturing a stainless steel strip having good surface quality and productivity.

[0011]

SUMMARY OF THE INVENTION According to the present invention, a hot-rolled stainless steel strip is continuously passed through a series of equipment comprising a plurality of multiple rolling mills arranged subsequently to an annealing device and a descaling device. Annealing performed by plate, descaling and rolling steps, and a stainless steel strip comprising a stainless steel strip rolled by the series of equipment, a final rolling step of cold rolling by a reversible cluster type rolling mill. This is a method for manufacturing a steel strip.

Further, the present invention is characterized in that high-speed high-pressure rolling is performed in a plurality of multiple rolling mills in the annealing, descaling and rolling steps.

Further, the present invention is characterized in that between the annealing, descaling and rolling steps and the final rolling step, a flaw removing step for removing flaws and the like on the surface of the stainless steel strip is performed.

Further, the present invention provides annealing, descaling and rolling of a stainless steel strip by continuously passing the stainless steel strip through a series of equipment comprising a plurality of multiple rolling mills subsequently arranged in an annealing apparatus and a descaling apparatus. A method for producing a stainless steel strip, wherein the step is repeated a plurality of times using the same series of equipment.

[0015]

According to the present invention, in the manufacturing process of the stainless steel strip, the hot-rolled stainless steel strip is converted into a series of equipment configured by arranging a plurality of multiple rolling mills after the annealing equipment and the descaling equipment. The process includes an annealing, descaling, and rolling process performed by continuous passing, and a final rolling process of cold rolling the stainless steel strip rolled by the above-described series of facilities using a reversible cluster rolling mill. The combined use of tandem rolling and reversing rolling reduces the load on the reversing-type cluster rolling mill, so that the number of reversing rolling passes is greatly reduced, and efficiency and productivity are improved. Conventionally, the annealing descaling process and the rolling process are separate processes, and the time required to transport and store the stainless steel strip coil each time during this process is greatly reduced. Significant improvements are also made in terms of transport to equipment and facilities, transportation and storage, and transfer equipment and facilities, as well as the logistics required for these personnel.

Further, according to the present invention, high-speed high-speed rolling is performed in a plurality of multiple rolling mills, so that the performance and productivity of the entire manufacturing process are improved.

Further, according to the present invention, a flaw removing step for removing flaws on the surface of the stainless steel strip can be performed between the annealing, descaling and rolling steps and the final rolling step. Surface quality is improved.

Further, according to the present invention, the annealing, descaling and rolling steps are repeatedly performed using the same series of equipment, so that a stainless steel strip having a large deformation resistance and easily work hardening can be efficiently rolled. Can be. It is only necessary to transport the stainless steel strip coil from the exit side to the entrance side of the same equipment,
Even if it is stored on the way, it can be stored in the same building. If separate equipment is used as in the past, at least temporary storage is required near the entrance and exit sides of each equipment, but significant improvements in logistics can be achieved. it can. Further, welding is not required between each step in a series of facilities, and the possibility of scratching the stainless steel strip due to gripping during welding is reduced.

[0019]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory view schematically showing the entire configuration of an example of a series of continuous annealing descaling rolling equipment according to the present invention. The stainless steel strip 1 is mounted on the pay-off reels 2a and 2b for each coil, and the preceding coil is unwound from, for example, one pay-off reel 2a and fed out. When the passing of the leading coil is completed, the trailing coil is fed from the other payoff reel 2b, and the welding device 3 welds the tail end of the leading coil and the tip of the trailing coil. The stainless steel strip 1 may be a hot-rolled stainless steel strip or a cold-rolled stainless steel strip. Downstream of the welding device 3, an entrance looper device 4 is provided.
Since the entrance-side looper device 4 stores the steel strip length necessary for continuously passing the stainless steel strip 1 on the downstream side, welding must be stopped and performed. Can be done without stopping. An annealing device 5 and a descaling device 6 are disposed downstream of the entrance looper device 4.

The stainless steel strip 1 is heated in the annealing furnace 5a of the annealing apparatus 5 and cooled by the cooling apparatus 5b to complete the annealing process. Subsequently, the mechanical processing 6a and the chemical processing 6b are combined by the descaling apparatus 6. And descaled. After the descaling process, the stainless steel strip 1 is continuously passed through a bridle device 8 via a delivery looper device 7. A first mill 9 is provided downstream of the bridle device 8. The first mill 9 is a cold rolling mill whose roll arrangement can be changed to a double rolling mill or a quadruple rolling mill. When the stainless steel strip 1 is cold-rolled following the annealing process and the descaling process, the first mill 9 is configured as a quadruple rolling mill. FIG. 1 shows a state where the first mill 9 is configured as a quadruple rolling mill. When the stainless steel strip 1 is not cold-rolled after the annealing and descaling, the first mill 9 is configured as a double rolling mill and used as a temper rolling mill. On the downstream side of the first mill 9, a shearing machine 16 for shearing the welded portion is provided, and a front take-up reel 18 for winding the stainless steel strip 1 through a deflector roll 17 is provided. Front take-up reel 1
8 and shears 16 are used when the stainless steel strip 1 is not cold rolled.

On the downstream side of the front take-up reel 18, two six-rolling mills are arranged in tandem with a second mill 10 and a third mill 11 from the upstream side via a centering device 19. The second mill 10 and the third mill 11 have exactly the same configuration. The intermediate roll of the six-high rolling mill can reciprocate in the axial direction to perform a roll shift for shape correction. The centering device 19 is used when the stainless steel strip 1 is cold-rolled. The stainless steel strip 1 is cold-rolled by the first mill 9 and then passed through the second mill 10 and the third mill 11 while being centered by the centering device 19. The diameter of the work rolls of the second mill 10 and the third mill 11 is 230 to 250 mm. As the diameter of the work roll becomes smaller, the contact area with the stainless steel strip 1 becomes smaller, so that the rolling load decreases. Therefore, while the diameter of a pair of upper and lower work rolls in a tandem cold rolling mill for cold rolling a steel strip such as ordinary steel is in the range of 400 to 600 mm, the second mill 10 and the third mill 11 The diameter of the work roll is very small. On the downstream side of the third mill 11,
A tension applying device 12 constituted by a pair of upper and lower rolls is provided. The tension applying device 12 applies a tension to the stainless steel strip 1 and also has a function of cleaning dirt on the stainless steel strip 1. On the downstream side of the tension applying device 12, a shearing machine 13 for shearing the welded portion of the stainless steel strip 1 is provided, and a rear take-up reel 15 for winding the stainless steel strip 1 via a deflector roll 14 is provided. Has been established. The tension applied to the rear take-up reel 15 is reduced due to the interposition of the tension applying device 12. Also,
Even if the shearing machine 13 shears the welded portion, the tension necessary for rolling is ensured by the tension applying device 12.

First mill 9, second mill 10, third mill 11
For the tension applying device 12, a rolling agent is used for cooling, lubrication and cleaning. When cold rolling is performed in the first mill 9, a water-soluble rolling oil containing an organic acid as a main component is used as a rolling agent. The water-soluble rolling oil contains almost no organic amine. The concentration of the water-soluble rolling oil is 10%. When temper rolling is performed in the first mill 9, a water-soluble temper rolling oil mainly containing an organic acid and an organic amine is used as the temper rolling oil. The component of the water-soluble temper rolling oil is adjusted so that the friction coefficient does not change depending on the temper rolling speed. The concentration of the water-soluble temper rolling oil is 3%. As the rolling agent for the second mill 10 and the third mill 11, a solvable oil obtained by dispersing a rolling oil having a synthetic ester as a base oil in water to form an emulsion is used. The concentration of the rolling oil is 6% and the viscosity at 50 ° C. is 80 cSt. The viscosity of the rolling oil is higher than that of a normal rolling oil in the range of 10 to 20 cSt. Tension applying device 12
As the rolling agent, straight mineral oil is used.
The mineral oil contains an alcohol-based additive to improve detergency. The viscosity of the mineral oil is 6.0 cSt at 40 ° C.

FIG. 2 is an explanatory view showing a manufacturing process of a BA-finished stainless steel strip according to one embodiment of the present invention. When an austenitic hot-rolled stainless steel strip represented by SUS304 is used as a starting material, the hot-rolled stainless steel strip is subjected to annealing and descaling in which a series of continuous annealing and descaling rolling equipment shown in FIG. Then, the sheet is continuously passed through a rolling step 21 to perform annealing, descaling, and tandem cold rolling. Annealing is performed to eliminate the hot-rolled structure and soften the stainless steel strip work-hardened by the hot rolling. The descaling is performed in order to remove the thick and dense scale generated by the hot rolling and the annealing. As described above, as the rolling agent for the second mill 10 and the third mill 11, a solvable oil obtained by dispersing a high-viscosity rolling oil in water to form an emulsion is used. High-viscosity rolling oil increases the oil film thickness, so that lubricity is improved and rolling load is reduced. Solible oil has good roll cooling properties, is unlikely to generate heat scratches, and has a low risk of fire. Further, since the diameter of the work rolls of the second mill 10 and the third mill 11 is relatively small, the rolling load can be reduced. Therefore, in the second mill 10 and the third mill 11, high-speed cold rolling under high pressure is possible. Since the solvable oil used in this way can have a relatively thin oil film thickness, almost no oil pits are formed on the surface of the rolled steel strip,
Surface gloss is improved. On the other hand, since the soluble oil has a strong affinity with the scum containing iron powder, the iron powder captured in the scum is easily pushed into the surface of the stainless steel strip by the work roll, and pit-like defects are easily generated. However, this scum tends to adhere to and remain on the stainless steel strip, and a scum pattern is likely to occur when annealed in the next step. Therefore, the scum remaining on the stainless steel strip is washed with mineral oil in the tension applying device 12 disposed downstream of the third mill 11. The stainless steel strip is passed through an annealing, descaling and rolling step 21 and then through a flaw removing step 22. In the flaw removal step 22, a continuous polishing device is provided. In the flaw removal step 22, surface flaws of the stainless steel strip are removed on both the front and back surfaces, including the pit-like defects and oil pits. The flaw removal is performed using an endless rotating belt coated with an abrasive determined for each particle size.

The stainless steel strip is passed through a final rolling step 23 following the flaw removing step 22 and cold rolled while leveraging. In the final rolling step 23, a cluster type rolling mill, for example, a levers type 20-stage Sendzimir mill is provided. The diameter of the work roll of the 20-stage Sendzimir mill is 40 to 120 mm, which is extremely small as compared with other rolling mills. As a rolling agent for a 20-stage Sendzimir mill,
Mineral oil is used. This mineral oil is a straight oil of low viscosity mineral oil, and has excellent surface gloss as described above. The surface glossiness of the rolled stainless steel strip is affected by the rolling agent, the diameter of the work roll, the surface roughness of the work roll, the number of rolling passes, the total draft, and the like. As described above, as the rolling agent, straight oil of low-viscosity mineral oil such as mineral oil is preferable, and as the work roll, a small-diameter work roll such as a 20-stage Sendzimir mill is preferable. Since the surface glossiness is obtained by rubbing the stainless steel strip surface with a work roll surface via a thin film of rolling oil, the roll surface roughness is preferably as small as possible. As the number of rolling passes increases, the number of contacts between the stainless steel strip and the work roll increases, so that the frequency and degree of rubbing the stainless steel strip surface with the work roll surface increase. Therefore, as the number of rolling passes increases, the surface gloss improves. Since the stainless steel strip is tandem cold-rolled in the annealing, descaling and rolling step 21,
The rolling load in the final rolling step 23 is greatly reduced. Therefore, although the number of rolling passes in the final rolling step 23 can be reduced, it is preferable to provide at least two to three passes in order to improve the surface gloss. In the final rolling step 23, the number of rolling passes provided is about three. The total rolling reduction is the total rolling reduction of the annealing, descaling and rolling process 21 and the final rolling process 23. Generally, the higher the total reduction ratio, the more the number of times of contact with the work rolls and the smoother the surface of the stainless steel strip, thereby improving the surface gloss. The total reduction is preferably in the range of 60 to 87%. Further, the rolling reduction in the final rolling step 23 must be equal to or higher than the rolling reduction required to eliminate the polished lines generated in the flaw removing step 22. The rolling reduction in the final rolling step 23 is preferably in the range of 40 to 80%. The surface gloss of the austenitic stainless steel strip is improved by performing cold rolling under the above-mentioned cold rolling conditions, and the surface gloss required as a BA finish is obtained.

The step following the final rolling step 23 is a bright annealing step 24. In the bright annealing step 24, a bright annealing furnace is provided. Bright annealing is usually performed in a reducing H ₂ -N ₂ gas atmosphere in a bright annealing furnace. In bright annealing, since almost no oxide film is formed on the stainless steel strip, the stainless steel strip is softened or annealed while maintaining the excellent surface gloss obtained in the final rolling step 23. The stainless steel strip is passed through a bright temper rolling step 25 following the bright annealing step 24 to perform a bright temper rolling.
In the bright temper rolling step 25, a temper rolling mill is provided. Bright temper rolling is performed at a low draft using a bright roll. The surface gloss of the stainless steel strip is further improved by bright temper rolling. The stainless steel strip is processed into a refinement step 26 following the bright temper rolling step 25.
, And a refining process is performed. In the refining process 26, degreasing, cleaning, shape correction, shearing, edge trimming,
Slitting and packing are performed, and the stainless steel strip is commercialized as a BA finished product 27.

On the other hand, when a ferritic hot-rolled stainless steel strip represented by SUS430 is used as a starting material, the flaw removing step 22 is omitted. The reason why the flaw removal step 22 is omitted is the same as in the case of FIG. The other steps and the equipment provided in each step are almost the same as those of the austenitic hot-rolled stainless steel strip. The ferritic stainless steel strip is used in the final rolling step 23.
Is cold-rolled by a 20-stage Sendzimir mill. Cold rolling conditions use mineral oil as a rolling agent. Use small diameter work rolls. Work roll surface roughness is reduced. The number of rolling passes is at least two to three. The total reduction is preferably set to 50 to 90%. Ferritic stainless steel strip
By performing cold rolling under the above-mentioned cold rolling conditions, the surface gloss is improved, and the surface gloss required for a BA finish is obtained.

FIG. 3 shows another embodiment of the present invention.
2B and No. It is explanatory drawing which shows the manufacturing process of a 2D finish stainless steel strip. Parts corresponding to those in FIG. 2 are denoted by the same reference numerals. No. 2B and No. The manufacturing process for 2D finished stainless steel strip is the same for all starting materials. The starting material, hot rolled stainless steel strip,
The sheet is continuously passed through the annealing, descaling and rolling process 21 provided in a series of continuous annealing descaling and rolling facilities shown in FIG. 1 to perform annealing, descaling and tandem cold rolling. The rolling agent used in the tandem cold rolling is exactly the same as in FIG. Following the annealing, descaling and rolling step 21, the final rolling step 2
In 3, cold rolling is performed. The rolling device and rolling conditions in the final rolling step 23 are exactly the same as those in FIG. Since the stainless steel strip is tandem cold-rolled in the annealing, descaling and rolling steps 21, the load in the final rolling step 23 is reduced.
After the final cold rolling is performed in the final rolling step 23, the stainless steel strip is subjected to final annealing descaling in the annealing descaling step 28. The annealing descaling apparatus provided in the annealing descaling step 28 is exactly the same as the annealing and descaling apparatus provided in the annealing descaling step 41. No. In the case of a 2B-finished stainless steel strip, bright temper rolling is performed in the bright temper rolling step 25 following the final annealing descaling step 28. Bright temper rolling is performed at a low draft using a bright roll. An appropriate surface gloss is imparted to the stainless steel strip by bright temper rolling. After the stainless steel strip is bright temper rolled,
After the refining process 26, It is commercialized as a 2B finished product 30. No. For 2D finished stainless steel strip,
Subsequent to the final annealing descaling step 28, dull temper rolling is performed in a dull temper rolling step 29. Dull temper rolling is performed at a light draft using a matte roll.
Dull temper rolling imparts a silver-white dull luster to the stainless steel strip. After the dull temper rolling of the stainless steel strip, the stainless steel strip passed through the refining process 26, 2D finishing product 31
Be commercialized as.

FIG. 4 is an explanatory view showing a manufacturing process of a polished stainless steel strip and a buff polished stainless steel strip according to still another embodiment of the present invention. The manufacturing process for the polished and buff polished stainless steel strips is the same for all starting materials. The hot-rolled stainless steel strip as a starting material is subjected to the above No. until the final annealing descaling step 28. 2B and No. 2D
It is passed through the same process as the finished stainless steel strip. The stainless steel strip is passed through a temper rolling step 32 subsequent to the final annealing descaling step 28 and temper rolling is performed. In the temper rolling, bright temper rolling or dull temper rolling is performed. In the case of a polished stainless steel strip, the plate is passed through a polishing step 33 subsequent to the temper rolling step 32 to perform polishing. In the polishing step 33, a continuous finishing polishing apparatus is provided. The stainless steel strip is continuously finished and polished by an endless rotary belt coated with an abrasive determined for each grain size or a belt coated with an abrasive. The particle size of the abrasive is specified in JIS G4305, and the particle size range of the abrasive is 100 to 400. The stainless steel strip passes through the polishing step 33 and the refining step 26 to be commercialized as a polished product 35. In the case of a buff-polished stainless steel strip, buff polishing is performed in a buff polishing step 34 instead of the polishing step 33. The other steps are exactly the same as for the polished stainless steel strip. After the stainless steel strip is buff-polished, it is manufactured as a buff-polished product 36 through the refining process 26.

FIG. 5 is an explanatory view showing a process of manufacturing a stainless steel strip according to still another embodiment of the present invention. In this embodiment, the annealing, descaling and rolling steps 21 similar to those of the embodiment of FIGS. 2 to 4 are repeated, and the stainless steel strip is passed through the same series of equipment twice or three times a plurality of times. In the same building, it is sufficient to transport the stainless steel strip coil from the exit side to the entrance side of the equipment, and even if it is temporarily stored on the way, it can be managed in common for the exit side and the entrance side, Is greatly improved. Further, in order to obtain a large overall rolling reduction in a stainless steel strip having a large deformation resistance and easy to work harden, it is necessary to perform multiple annealings, but in the present embodiment, it is possible to efficiently increase the overall rolling reduction. . Further, the number of times of welding and shearing between the respective steps is reduced, and at this time, generation of unavoidable flaws for gripping the stainless steel strip can be suppressed, and the surface quality can be improved. After a plurality of repetitions, the final product may be directly produced, or the process may be shifted to the various steps described above.

[0030]

As described above, according to the present invention, in the manufacturing process of the stainless steel strip, a plurality of multiple rolling mills are arranged after the hot-rolled stainless steel strip in the annealing device and the descaling device. Annealing, descaling and rolling steps performed by continuously passing through a series of facilities to be performed, and a stainless steel strip rolled in the series of facilities, a final rolling step of cold rolling by a reversible cluster rolling mill. It is included. By using tandem rolling and reversing rolling together,
Since the rolling load of the reversing type cluster type rolling mill is reduced, the number of final rolling passes is reduced. Therefore, the rolling time of the final rolling step is shortened, and the efficiency and productivity of the reversible cluster type rolling mill are improved. In addition, the logistics related to the transportation of the stainless steel strip coil and the like are greatly improved.

According to the present invention, high-speed high-speed rolling is performed in a plurality of multiple rolling mills, so that the performance and productivity of the entire manufacturing process are improved. Therefore, it is possible to reduce the amount of work in progress of the stainless steel strip coil between each process and to shorten the required number of days for manufacturing the stainless steel strip.

According to the present invention, a flaw removing step for removing flaws and the like on the surface of the stainless steel strip can be performed between the annealing, descaling and rolling steps and the final rolling step. Surface quality is improved. Overall, significant improvements in quality and cost can be achieved.

Further, according to the present invention, by using the same equipment, the possibility that the surface of the stainless steel strip is flawed is reduced, the surface quality is improved, and the production efficiency and the distribution are improved. It becomes possible.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a simplified entire configuration of an example of a series of continuous annealing descaling rolling equipment according to the present invention.

FIG. 2 is an explanatory view showing a manufacturing process of a BA-finished stainless steel strip which is one embodiment of the present invention.

FIG. 3 shows another embodiment of the present invention. 2B and N
o. It is explanatory drawing which shows the manufacturing process of a 2D finish stainless steel strip.

FIG. 4 is an explanatory view showing a manufacturing process of a polished stainless steel strip and a buff polished stainless steel strip according to still another embodiment of the present invention.

FIG. 5 is an explanatory view showing a manufacturing process of a stainless steel strip according to still another embodiment of the present invention.

FIG. 6 is an explanatory view showing a manufacturing process of a BA-finished stainless steel strip according to a conventional technique.

FIG. 2B and No. It is explanatory drawing which shows the manufacturing process of a 2D finish stainless steel strip.

FIG. 8 is an explanatory view showing a manufacturing process of a polished stainless steel strip and a buff polished stainless steel strip according to the prior art.

[Explanation of symbols]

 Reference Signs List 1 stainless steel strip 5 annealing device 6 descaling device 9 first mill 10 second mill 11 third mill 12 tension applying device 21 annealing, descaling and rolling process 22 flaw removing process 23 final rolling process 24 bright annealing process 25 bright tone Temper rolling process 28 Annealing and descaling process 29 Dull temper rolling process 33 Polishing process 34 Buff polishing process

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-6-15308 (JP, A) JP-A-3-23001 (JP, A) JP-A-5-212410 (JP, A) JP-A Sho 53- 56143 (JP, A) JP-A-6-79303 (JP, A) JP-A-4-71702 (JP, A) JP-A-54-128463 (JP, A) (58) Fields investigated (Int. ⁷ , DB name) B21B 1/00-3/02 B21B 45/06 C21D 8/02

Claims (4)

(57) [Claims] 1. An annealing and descaling process in which a stainless steel strip after hot rolling is continuously passed through a series of equipment comprising a plurality of multiple rolling mills subsequently arranged in an annealing device and a descaling device. And a rolling step; and a final rolling step of cold rolling the stainless steel strip rolled by the series of facilities by a reversible cluster rolling mill. 2. The method for producing a stainless steel strip according to claim 1, wherein high-speed high-speed rolling is performed in a plurality of multiple rolling mills in the annealing, descaling, and rolling processes. 3. A flaw removing step for removing flaws on the surface of the stainless steel strip between the annealing, descaling and rolling steps and the final rolling step.
Or the method for producing a stainless steel strip according to 2. 4. An annealing, descaling, and rolling process in which a stainless steel strip is continuously passed through a series of equipments constituted by a plurality of multiple rolling mills subsequently arranged in an annealing device and a descaling device, A method for producing a stainless steel strip, wherein the method is repeated a plurality of times using the same series of equipment.