JP2012035310A - Method and equipment for manufacturing hot rolled steel plates - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and equipment for manufacturing hot rolled steel plates which can acquire a material quality with high strength and high ductility by achieving highly accurate and stable cooling during a run-out cooling, even when the coiling temperature is designated at a comparatively low temperature range such as 450-550°C for the hot rolled plate of product thickness of 12 mm or more.SOLUTION: The run-out cooling equipment 5 is a laminar type cooling device which applies a top surface cooling on a steel plate 10, while in the descaling device 3 the collision pressure of descaling water onto the steel plate 10 is 2.0 MPa or more. The cooling equipment is divided into an upstream side cooling equipment 6 and a downstream side cooling equipment 7, and the water amount density of cooling water for the top surface of steel plate 10 is 1.0-2.4 m/mmin in the upstream side cooling equipment 6, while 0.5-1.0 m/mmin in the downstream side cooling equipment 7.

Description

  The present invention relates to a manufacturing method and manufacturing equipment for a hot-rolled steel sheet.

  In the process of manufacturing a steel plate (steel strip) by hot rolling, the slab is heated in the heating furnace 1 and then rough rolled in the roughing mill 2 in a manufacturing facility as shown in FIG. During the rough rolling and after the end of the rough rolling, the scale is removed by the descaling device 3 and the finish rolling is performed by the finishing mill 4. Thereafter, the cooling equipment (run-out cooling equipment) 5 installed on the run-out table performs water cooling or air cooling to control the structure of the steel plate 10.

  Among these, there are some thick materials having a product thickness of 12 mm or more, which are used as materials for electric-welded pipes and spiral steel pipes. However, a relatively low temperature as a hot-rolled steel sheet due to water cooling in the run-out cooling equipment 5, for example 450 When rapidly cooled to ˜550 ° C., a fine ferrite structure and a bainite structure are obtained, and a high-strength and high-toughness material is obtained.

  However, there is a problem that the cooling becomes unstable when cooling in the run-out cooling facility 5 in a relatively low temperature range where the coiling temperature in the coiler 8 is 550 ° C. or lower.

  In general, in cooling of a steel plate on a run-out table (run-out cooling), when the steel plate surface temperature is high (for example, when it exceeds 550 ° C.), film boiling occurs and stable cooling is performed. In contrast, when cooling progresses and the steel sheet surface temperature decreases (for example, 550 ° C. or less), transition boiling in which film boiling and nucleate boiling coexist occurs. In the state of transition boiling, the cooling capacity increases as the surface temperature decreases, so that the cooling becomes unstable, the temperature variation increases, and the material variation also increases. Further, if the steel plate is cooled too much, it becomes extremely hard, the spring back of the steel plate tail end (steel strip tail end) becomes large, and the steel plate (steel strip) 10 cannot be removed from the coiler 8, or the tip of the steel plate The (steel strip front end) cannot be bent, and problems such as being unable to wind with the coiler 8 occur.

  Therefore, the technique of Patent Document 1 has been proposed as a technique for performing stable cooling in the runout table. This is because the run-out cooling zone is divided into the first half zone and the second half zone, slit laminar type high cooling capacity equipment is arranged in the first half zone, and spray type low cooling capacity equipment is arranged in the second half zone. In addition, a pipe laminar type medium cooling capacity facility is arranged over the entire length of the runout cooling zone. With this technology, the first half zone secures the material by increasing the water amount density and cooling, and the second half zone realizes stable cooling by reducing the water amount density and performing highly accurate temperature control.

In addition, in the descaling apparatus 3 installed in the middle of rough rolling and after completion | finish of rough rolling, conventionally, it was common to carry out with the spraying pressure of descaling water being 150 kgf / cm < ² > (14.7 MPa). On the other hand, high-pressure descaling in which the spray pressure of descaling water is 250 kgf / cm ² (24.5 MPa) or more has been used for products that require a particularly aesthetic surface. For thick materials, descaling at a normal injection pressure of 150 kgf / cm ² (14.7 MPa) was used, but there was no problem of surface appearance.

JP 2003-025009 A

  However, in the conventional technology, there is a problem that cooling of a thick material such as a product thickness of 12 to 26 mm becomes unstable in a low temperature region of 550 ° C. or lower.

  The temperature at which transition boiling begins (referred to as transition boiling start temperature) is higher as the scale generated on the steel sheet surface is thicker. When a steel plate with incomplete descaling is cooled to 550 ° C. or less, the scale thickness varies within the steel plate, so that transition boiling also varies and temperature unevenness occurs. The lower the coiling temperature, the longer the time for cooling at the transition boiling temperature and the greater the temperature unevenness. Therefore, there is a problem that the material is dispersed or the steel plate is cooled too much and the operation becomes unstable.

  Further, as shown in FIG. 2, in the upper surface cooling by the laminar type cooling facility, the cooling capacity at the laminar collision portion 24 where the laminar water 23 from the upper nozzle 22 attached to the upper header 21 collides with the upper surface of the steel plate 10. Is very high, and the temperature drop when passing through the laminar collision part 24 is very large. On the other hand, since the cooling capacity is not so high in the water riding section 26 where the accumulated water 25 is on the upper surface of the steel plate 10, the surface temperature is somewhat increased by recuperation. Here, if the surface temperature of the steel sheet 10 is lower than the transition boiling start temperature during cooling, transition boiling occurs and cooling becomes unstable. If the descaling is incomplete, the transition boiling start temperature is relatively high in the portion where the scale remains, so that the surface temperature of the steel sheet 10 enters the transition boiling temperature region during cooling in the run-out cooling facility 5, and temperature unevenness occurs. appear.

Regarding this point, in the technique of Patent Document 1, when the scale thickness of the steel sheet is not uniform, it is difficult to uniformly cool the steel sheet to a relatively low temperature range where the coiling temperature is 450 to 550 ° C. It caused temperature unevenness, which was a problem. In addition, this technology is to arrange spray cooling equipment in the latter half of the run-out cooling zone and cool the water volume density to 0.3 m ³ / m ² min or less. However, since the water volume is small, the cooling zone is limited. A thick material cannot be cooled to a winding temperature of 450 to 550 ° C. with a run-out cooling facility having a length (for example, 120 m). In addition to pipe laminar medium cooling capacity equipment (ordinary cooling equipment) over the entire length of the run-out cooling zone, this technology also installs slit laminar cooling equipment in the first half zone and spray cooling equipment in the second half zone. Therefore, there is a problem that the equipment cost becomes enormous.

  The present invention has been made in view of the circumstances as described above, and when producing a hot-rolled steel sheet having a product thickness of 12 mm or more, even if the winding temperature is 450 to 550 ° C. and a relatively low temperature range, An object of the present invention is to provide a method and equipment for manufacturing a hot-rolled steel sheet capable of realizing highly accurate and stable cooling in run-out cooling and ensuring a high-strength and high-toughness material.

  In order to solve the above problems, the present invention has the following features.

[1] When producing a hot-rolled steel sheet having a product thickness of 12 mm or more, after performing descaling such that the impact pressure of descaling water against the steel sheet is 2.0 MPa or more, finish rolling is performed, and then in runout cooling, The upper surface is cooled by a laminar system, and at that time, the water is divided into an upstream side and a downstream side, and the cooling water is supplied at a water density of 1.0 to 2.4 m ³ / m ² min on the upstream side, A method for producing a hot-rolled steel sheet, wherein cooling water is supplied at a water density of 0.5 to 1.0 m ³ / m ² min and winding is performed at a winding temperature of 450 ° C. to 550 ° C.

[2] The method for producing a hot-rolled steel sheet according to [1], wherein an injection pressure of the descaling water is 250 kgf / cm ² or more.

[3] In a hot-rolled steel plate manufacturing facility, a descaling device in which the impact pressure of descaling water against the steel plate is 2.0 MPa or more, a finish rolling mill, and a run-out cooling facility for performing top surface cooling of the steel plate by a laminar system The run-out cooling equipment is sequentially arranged, and is divided into an upstream cooling zone and a downstream cooling zone, and the water density of cooling water for cooling the upper surface of the steel sheet is 1.0 in the upstream cooling zone. ~2.4m ³ / ^m 2 min, manufacturing facility hot-rolled steel sheet, which is a 0.5~1.0m ³ / ^m 2 min at the downstream cooling zone.

[4] The hot-rolled steel sheet manufacturing facility according to [3], wherein the descaling apparatus has an injection pressure of descaling water of 250 kgf / cm ² or more.

  In the present invention, descaling with a collision pressure on the steel plate of 2.0 MPa or more is performed, and in the runout table, strong cooling is performed upstream and normal cooling is performed downstream, so that transition boiling can be avoided. It is possible to produce a steel plate with stable material cooling and small material variation.

  That is, in the present invention, when manufacturing a hot rolled steel sheet having a product thickness of 12 mm or more, high precision and stable cooling is realized in the run-out cooling even in a relatively low temperature range of 450 to 550 ° C. In addition, a high-strength and high-toughness material can be ensured.

It is a figure which shows the manufacturing equipment of the hot-rolled steel plate in one Embodiment of this invention. It is a figure which shows the cooling state in the cooling facility of a laminar system. It is a figure which shows the relationship between descaling and runout cooling. It is a figure which shows the relationship between descaling and the temperature nonuniformity of a steel plate.

  An embodiment of the present invention will be described with reference to the drawings.

  The manufacturing equipment for hot-rolled steel sheets in one embodiment of the present invention is shown in FIG. As shown in FIG. 1, the hot-rolled steel sheet manufacturing equipment in this embodiment includes a heating furnace 1 that heats a slab, a rough rolling machine 2 that performs rough rolling of the heated slab, a middle of rough rolling, and rough rolling. The descaling device 3 for removing the scale after completion, the finish rolling machine 4 for finishing rolling of the roughly rolled steel plate (rough bar), and the run-out cooling facility 5 for cooling the finish-rolled steel plate (run-out cooling). And a coiler 8 for winding the run-out cooled steel plate.

And in this embodiment, while the collision pressure to the steel plate 10 of the descaling water in the descaling apparatus 3 is 2.0 MPa or more, the run-out cooling equipment 5 performs the cooling which performs the upper surface cooling of the steel plate 10 by a laminar system. A cooling water (laminar cooling water) that is divided into an upstream cooling zone (upstream cooling equipment) 6 and a downstream cooling zone (downstream cooling equipment) 7 for cooling the upper surface of the steel plate 10. Of the upstream cooling facility 6 (upper header 11, upper nozzle 12) is 1.0 to 2.4 m ³ / m ² min, and the downstream cooling facility 7 (upper header 15, upper nozzle 16) is 0. It is 5 to 1.0 m ³ / m ² min.

  The division ratio between the upstream cooling zone 6 and the downstream cooling zone 7 is set in accordance with the finishing dimensions (particularly the plate thickness), the steel type, the coiling temperature, etc., and the upstream cooling zone 6 is the entire run-out cooling facility 5. It is appropriate that it is 30 to 60%. Specifically, the number of the upper nozzles 16 in the upstream cooling zone 6 is equal to the number of upper nozzles in the entire runout cooling facility 5 (the total of the upper nozzles 12 in the upstream cooling zone 6 and the upper nozzles 16 in the downstream cooling zone 7). It is appropriate that it is 30 to 60% of the (number).

  However, it is not limited to the above range. For example, as the plate thickness increases, the retained heat near the center of the steel plate increases, and even if the amount of cooling water is increased, the retained heat near the center of the steel plate increases. Since the surface temperature recuperates greatly, the ratio of the upstream cooling zone 6 may be made more than 60% within the range where the surface temperature does not enter the transition boiling temperature range.

  In the run-out cooling facility 5, the lower surface cooling of the steel plate 10 is performed by spraying both the upstream cooling facility 6 (lower header 13 and lower nozzle 14) and the downstream cooling facility 7 (lower header 17 and lower nozzle 18). It is like that.

  Then, using this hot-rolled steel sheet manufacturing equipment, a hot-rolled steel sheet having a product thickness of 12 mm or more is manufactured. At that time, the coiling temperature at the coiler 8 is set to 450 ° C. to 550 ° C. Yes. Note that the upper limit of the product thickness is the maximum plate thickness that can be wound by the coiler 8 (specific upper limit value of the coiler: 26 mm, for example).

In this way, in the run-out cooling facility 5, on the upstream side (upstream cooling facility 6), the cooling water is supplied to the upper surface of the steel plate at a water density of 1.0 to 2.4 m ³ / m ² min by a laminar method. A high cooling rate can be obtained even for a thick steel plate, and a high-strength and high-toughness material can be secured. Once transition boiling occurs, the subsequent water cooling is likely to be performed in the transition boiling region, making temperature control difficult, but in the first half of the laminar cooling (cooling in the upstream cooling facility 6), the steel sheet surface temperature Is relatively high, it is difficult to enter the transition boiling temperature range even if the amount of water is increased to some extent.

Incidentally, if the water density of the cooling water (laminar cooling water) on the upper surface of the steel sheet in the upstream side cooling facility 6 is less than 1.0 m ³ / m ² min, a sufficient cooling rate can be obtained when the steel sheet is thick. It is not possible to secure a material with high strength and toughness. In addition, when the water density of the cooling water (laminar cooling water) on the upper surface of the steel plate in the upstream side cooling facility 6 exceeds 2.4 m ³ / m ² min, the equipment cost increases and transition boiling easily occurs. Becomes unstable.

Further, in the run-out cooling facility 5, on the downstream side (downstream cooling facility 7), the cooling water is supplied to the upper surface of the steel sheet by a laminar method at a water density of 0.5 to 1.0 m ³ / m ² min. The amount of supplied water can be increased as compared with the cooling facility, and the thick material can be accurately cooled to a relatively low target temperature of 450 ° C. to 550 ° C. Moreover, since the water density is moderately small, transition boiling is unlikely to occur, and large temperature unevenness does not occur.

Incidentally, if the water density of the cooling water (laminar cooling water) on the upper surface of the steel sheet in the downstream side cooling facility 7 is less than 0.5 m ³ / m ² min, the cooling capacity is insufficient when the steel sheet is thick, It cannot cool to 450 degreeC-550 degreeC which is the target of coiling temperature. In addition, when the water density of the cooling water (laminar cooling water) on the upper surface of the steel sheet in the downstream side cooling facility 7 exceeds 1.0 m ³ / m ² min, transition boiling is likely to occur. Control becomes difficult.

  Then, by performing descaling such that the collision pressure to the steel plate 10 becomes 2.0 MPa or more before finish rolling, the scale thickness can be made uniform and stable cooling can be realized.

  When the normal descaling in which the impact pressure is about 1.4 MPa is used, scale removal is incomplete, and the transition boiling start temperature is relatively high in the portion where the scale remains, so FIG. Thus, the transition boiling temperature range is entered during the run-out cooling, and the cooling becomes unstable.

  On the other hand, when high pressure descaling with a collision pressure of 2.0 MPa or more can be used, the scale can be removed better than when normal descaling is used, and the transition boiling start temperature becomes lower. ) As shown, it becomes easier to avoid transition boiling and stable cooling can be realized.

Further, on the downstream side of the run-out cooling facility 5 (downstream-side cooling facility 7), the cooling water is supplied to the upper surface of the steel plate at a water density of 0.5 to 1.0 m ³ / m ² min, and the upstream side of the run-out cooling facility 5 If the cooling capacity is moderately reduced as compared with (upstream cooling facility 6), as shown in FIG. 3 (c), the temperature drop when passing the laminar collision part becomes small, so that transition boiling can be more easily avoided. More stable cooling can be realized.

  When the normal descaling is used, the temperature distribution in the width direction before the winding is as shown in FIG. On the other hand, when high pressure descaling is used, the scale can be completely removed in the entire surface of the steel sheet, so that transition boiling is less likely to occur, and the temperature variation becomes small as shown in FIG.

  Thus, if high pressure descaling is performed so that the collision pressure is 2.0 MPa or more, the scale of the coarse bar before finish rolling can be completely removed, and the thickness of the scale generated after descaling can be reduced. It can be made uniform.

In the descaling apparatus 3 installed on the entry side of the finishing mill 4, in order to obtain a collision pressure of 2.0 MPa or more, the spray pressure of descaling water is 250 kgf / cm ² (24.5 MPa) or more. Good. If the injection pressure is less than 250 kgf / cm ² (24.5 MPa), it is difficult to obtain a collision pressure of 2.0 MPa, the scale remains partially, and cooling becomes unstable, which is not good.

  Thus, in this embodiment, since a hot-rolled steel sheet having a product thickness of 12 mm or more can be stably cooled at a high cooling rate, it is possible to produce a high-quality steel sheet with high strength, high toughness and small material variation. it can. Further, since the coiling temperature does not become abnormally low, the springback of the steel plate tail end (steel strip tail end) becomes large, and the steel strip 10 cannot be removed from the coiler 8 or the steel plate tip ( It is possible to avoid operational troubles such as the fact that the steel strip tip portion cannot be bent and cannot be wound by the coiler 8, and the operational stability can be ensured.

  Moreover, in this embodiment, in the laminar type cooling equipment, transition boiling is avoided, and unlike the technique of Patent Document 1, a new cooling equipment is not installed, so that equipment costs are required. No problem.

  Examples of the present invention will be described.

  In the hot-rolled steel sheet manufacturing equipment shown in FIG. 1, the slab is heated in the heating furnace 1, and then rough rolled by the rough rolling machine 2, and the scale is scaled by the descaling device 3 during the rough rolling and after completion of the rough rolling. It removed and finish-rolled with the finishing mill 4. The steel plate temperature on the exit side of the finishing mill 4 was 780 ° C. Thereafter, while conveying the steel plate 10 on the run-out table, in the run-out cooling facility 5 (upstream cooling facility 6, downstream cooling facility 7), laminar cooling water is supplied to the upper surface of the steel plate and spray cooling water is applied to the lower surface of the steel plate. Was cooled to 500 ° C. In order to secure a target material and produce a steel sheet with small variations, it was necessary to suppress the temperature-direction temperature unevenness within 50 ° C.

  Manufacturing conditions of the present invention and comparative examples (rough bar thickness, product thickness, descaling injection pressure, descaling collision pressure, upstream cooling facility water density, downstream cooling facility water density, steel sheet transport speed) Table 1 summarizes the manufacturing results (temperature unevenness in the width direction).

First, in Comparative Example 1, the coarse bar thickness is 60 mm, the product thickness is 22.2 mm, the descaling pressure before finishing rolling is 150 kgf / cm ² (14.7 MPa), the conveyance speed is 180 mpm, and the first half of the run-out cooling (upstream cooling equipment). A hot-rolled steel sheet was manufactured with a water density of 1.6 m ³ / m ² min and a water density of the latter half of the run-out cooling (downstream cooling equipment) of 0.8 m ³ / m ² min. As a result, since the impact pressure of descaling before finish rolling was 1.4 MPa, scale unevenness remained on the surface of the steel sheet, and the temperature unevenness in the width direction was as large as 100 ° C., which caused problems in material variations and operational stability. It was.

In contrast, in Example 1 of the present invention, the coarse bar thickness is 60 mm, the product thickness is 22.2 mm, the descaling pressure before finishing rolling is 300 kgf / cm ² (29.4 MPa), the conveyance speed is 180 mpm, the run-out cooling first half (upstream side) A hot-rolled steel sheet was manufactured with a water density of 1.6 m ³ / m ² min in the cooling facility and a water density of 0.8 m ³ / m ² min in the latter half of the run-out cooling (downstream cooling facility). As a result, since the impact pressure of descaling before finish rolling was 2.8 MPa, the unevenness of the scale on the steel sheet surface was eliminated. By avoiding the transition boiling region by high-speed conveyance, the temperature unevenness in the width direction was reduced to 40 ° C. As a result, a high-quality steel sheet with high strength and toughness and little material variation was obtained. In addition, the temperature control accuracy was improved and the steel sheet was not abnormally cooled excessively, and the operation stability was ensured.

Next, in Comparative Example 2, the coarse bar thickness is 40 mm, the product thickness is 12 mm, the descaling pressure before finishing rolling is 150 kgf / cm ² (14.7 MPa), the conveyance speed is 220 mpm, and the first half of the run-out cooling (upstream cooling equipment) A hot-rolled steel sheet was manufactured with a density of 1.6 m ³ / m ² min and a water density in the second half of the run-out cooling (downstream cooling facility) at 0.8 m ³ / m ² min. As a result, since the impact pressure of descaling before finish rolling was 1.4 MPa, scale unevenness remained on the surface of the steel sheet, and the temperature unevenness in the width direction became 80 ° C., resulting in a problem of material variation.

In Comparative Example 3, the coarse bar thickness is 40 mm, the product thickness is 12 mm, the descaling pressure before finishing rolling is 300 kgf / cm ² (29.4 MPa), the conveyance speed is 220 mpm, and the water density of the first half of the run-out cooling (upstream cooling equipment). Was 1.6 m ³ / m ² min, and the water density in the second half of the run-out cooling (downstream cooling equipment) was 1.4 m ³ / m ² min, to produce a hot-rolled steel sheet. As a result, since the impact pressure of descaling before finish rolling was 2.8 MPa, the unevenness of the scale on the steel sheet surface was eliminated. However, transition boiling occurred in the latter half of the run-out cooling, and the temperature unevenness in the width direction became 55 ° C., and there was a problem of material variation.

On the other hand, in Example 2 of the present invention, the coarse bar thickness is 40 mm, the product thickness is 12 mm, the descaling pressure before finishing rolling is 300 kgf / cm ² (29.4 MPa), the conveyance speed is 220 mpm, the run-out cooling first half (upstream cooling equipment) ) Was 1.6 m ³ / m ² min, and the water density in the latter half of the run-out cooling (downstream side cooling facility) was 0.8 m ³ / m ² min. As a result, since the impact pressure of descaling before finish rolling was 2.8 MPa, the unevenness of the scale on the steel sheet surface was eliminated. Then, the temperature unevenness in the width direction was reduced to 25 ° C., and a high-quality steel sheet with high strength and high toughness and little material variation was obtained. In addition, the temperature control accuracy was improved and the steel sheet was not abnormally cooled excessively, and the operation stability was ensured.

DESCRIPTION OF SYMBOLS 1 Heating furnace 2 Rough rolling mill 3 Descaling device 4 Finishing mill 5 Run-out cooling equipment 6 Upstream cooling equipment (upstream cooling zone)
7 Downstream cooling equipment (downstream cooling zone)
8 Coiler 10 Steel sheet (steel strip)
11 Upper header of upstream cooling facility 12 Upper nozzle of upstream cooling facility 13 Lower header of upstream cooling facility 14 Lower nozzle of upstream cooling facility 15 Upper header of downstream cooling facility 16 Upper nozzle of downstream cooling facility 17 Downstream Lower header of the side cooling equipment 18 Lower nozzle of the downstream side cooling equipment 21 Upper header 22 Upper nozzle 23 Laminar water (laminar cooling water)
24 Laminar collision part 25 Stagnant water 26 Water ride part

Claims (4)

When producing a hot rolled steel sheet having a product thickness of 12 mm or more, after descaling is performed such that the impact pressure of the descaling water against the steel sheet is 2.0 MPa or more, finish rolling is performed, and then the top surface of the steel sheet is cooled in run-out cooling. In this case, the water is divided into an upstream side and a downstream side, and cooling water is supplied at a water density of 1.0 to 2.4 m ³ / m ² min on the upstream side, and cooling water is supplied on the downstream side. A method for producing a hot-rolled steel sheet, which is supplied at a water density of 0.5 to 1.0 m ³ / m ² min and is wound at a winding temperature of 450 ° C. to 550 ° C. The method for producing a hot-rolled steel sheet according to claim 1, wherein an injection pressure of the descaling water is 250 kgf / cm ² or more. In a hot-rolled steel plate manufacturing facility, a descaling device in which the impact pressure of descaling water against the steel plate is 2.0 MPa or more, a finish rolling mill, and a run-out cooling facility for laminating the top surface of the steel plate are sequentially arranged. The run-out cooling facility is divided into an upstream cooling zone and a downstream cooling zone, and the water density of the cooling water for cooling the upper surface of the steel sheet is 1.0 to 2 in the upstream cooling zone. 4m ³ / ^m 2 min, manufacturing facility hot-rolled steel sheet, which is a 0.5~1.0m ³ / ^m 2 min at the downstream cooling zone. The hot-rolled steel sheet manufacturing equipment according to claim 3, wherein the descaling device has an injection pressure of descaling water of 250 kgf / cm ² or more.

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