WO2016031168A1 - 厚鋼板の製造設備および製造方法 - Google Patents
厚鋼板の製造設備および製造方法 Download PDFInfo
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- WO2016031168A1 WO2016031168A1 PCT/JP2015/004055 JP2015004055W WO2016031168A1 WO 2016031168 A1 WO2016031168 A1 WO 2016031168A1 JP 2015004055 W JP2015004055 W JP 2015004055W WO 2016031168 A1 WO2016031168 A1 WO 2016031168A1
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- steel plate
- thick steel
- descaling
- cooling
- water
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21B—ROLLING OF METAL
- B21B45/00—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
- B21B45/04—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for de-scaling, e.g. by brushing
- B21B45/08—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for de-scaling, e.g. by brushing hydraulically
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21B—ROLLING OF METAL
- B21B1/00—Metal-rolling methods or mills for making semi-finished products of solid or profiled cross-section; Sequence of operations in milling trains; Layout of rolling-mill plant, e.g. grouping of stands; Succession of passes or of sectional pass alternations
- B21B1/38—Metal-rolling methods or mills for making semi-finished products of solid or profiled cross-section; Sequence of operations in milling trains; Layout of rolling-mill plant, e.g. grouping of stands; Succession of passes or of sectional pass alternations for rolling sheets of limited length, e.g. folded sheets, superimposed sheets, pack rolling
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21B—ROLLING OF METAL
- B21B45/00—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
- B21B45/02—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for lubricating, cooling, or cleaning
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21B—ROLLING OF METAL
- B21B45/00—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
- B21B45/02—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for lubricating, cooling, or cleaning
- B21B45/0203—Cooling
- B21B45/0209—Cooling devices, e.g. using gaseous coolants
- B21B45/0215—Cooling devices, e.g. using gaseous coolants using liquid coolants, e.g. for sections, for tubes
- B21B45/0218—Cooling devices, e.g. using gaseous coolants using liquid coolants, e.g. for sections, for tubes for strips, sheets, or plates
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21B—ROLLING OF METAL
- B21B45/00—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
- B21B45/02—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for lubricating, cooling, or cleaning
- B21B45/0203—Cooling
- B21B45/0209—Cooling devices, e.g. using gaseous coolants
- B21B45/0215—Cooling devices, e.g. using gaseous coolants using liquid coolants, e.g. for sections, for tubes
- B21B45/0233—Spray nozzles, Nozzle headers; Spray systems
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21B—ROLLING OF METAL
- B21B45/00—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
- B21B45/04—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for de-scaling, e.g. by brushing
- B21B45/06—Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for de-scaling, e.g. by brushing of strip material
Definitions
- the present invention relates to a thick steel plate manufacturing facility and manufacturing method for performing hot rolling, shape correction and accelerated cooling of a thick steel plate.
- Patent Document 1 discloses a method in which descaling is performed at least immediately before and immediately after the final pass of finish rolling, followed by hot correction, and then descaling and forced cooling.
- Patent Document 2 discloses a method of performing control cooling after performing descaling after performing finish rolling and hot straightening.
- Patent Document 3 discloses a method of performing descaling while controlling the collision pressure of cooling water immediately before the controlled cooling.
- the present invention has been made paying attention to the unsolved problems of the above-described conventional example, and by uniformizing the scale generated on the surface of the thick steel plate in the descaling process, it is uniform in the cooling process. It aims at providing the manufacturing equipment and manufacturing method of a thick steel plate which cools and is excellent in the shape and mechanical characteristic of a thick steel plate.
- the present inventors diligently examined the force that causes scale peeling by descaling water.
- the spray nozzles of the descaling device are arranged in two or more rows in the longitudinal direction of the thick steel plate. If the energy density of the descaling water sprayed onto the thick steel plate from the two or more rows of spray nozzles is 0.08 J / mm 2 or more in total, the scale thickness generated on the surface after the product becomes uniform. I found out. As a result, it has been found that when passing through the accelerated cooling apparatus, the steel plate can be uniformly cooled with almost no variation in the surface temperature at the position in the width direction of the thick steel plate, resulting in a thick steel plate having an excellent thick steel plate shape.
- the gist of the present invention is as follows. [1] A hot rolling mill, a shape correcting device, a descaling device, and an accelerated cooling device are arranged in this order from the upstream side in the conveying direction, and the spray nozzles of the descaling device are arranged in two rows with respect to the longitudinal direction of the thick steel plate.
- the energy density E of the descaling water sprayed from the two rows of spray nozzles toward the surface of the thick steel plate is 0.08 J / mm 2 or more in total, .
- a hot rolling mill, a shape correction device, a descaling device, and an accelerated cooling device are arranged in this order from the upstream side in the conveying direction, and the spray nozzles of the descaling device are two or more rows in the longitudinal direction of the thick steel plate.
- the energy density E of the descaling water that is disposed and sprayed from the two or more rows of spray nozzles toward the surface of the thick steel plate is 0.08 J / mm 2 or more in total. production equipment.
- the distance from the descaling device to the accelerated cooling device when the transport speed from the descaling device to the accelerated cooling device is V [m / s] and the steel plate temperature before cooling is T [K].
- L [m] satisfies the formula L ⁇ V ⁇ 5 ⁇ 10 ⁇ 9 ⁇ exp (25000 / T), the thick steel plate manufacturing facility according to [1] or [2].
- [4] The thick steel plate manufacturing facility according to [3], wherein a distance L from the descaling device to the acceleration cooling device is 12 m or less.
- [5] The thickness according to any one of [1] to [4], wherein a distance H from the spray nozzle of the descaling device to the surface of the thick steel plate is 40 mm or more and 200 mm or less. Steel plate manufacturing equipment.
- the accelerated cooling device includes a header for supplying cooling water to the upper surface of the thick steel plate, a cooling water injection nozzle for injecting rod-shaped cooling water suspended from the header, and the thick steel plate and the header.
- a partition wall to be installed, and a water supply port for interpolating a lower end portion of the cooling water injection nozzle, and a drain port for draining the cooling water supplied to the upper surface of the thick steel plate to the partition wall. are provided, and the manufacturing equipment for thick steel plates according to any one of [1] to [5].
- the energy density E is added to the surface of the thick steel plate during the hot straightening step and the accelerated cooling step.
- the energy density E is added to the surface of the thick steel plate during the hot straightening step and the accelerated cooling step.
- a thick steel plate manufacturing method characterized by having a descaling step of performing descaling twice or more so as to be 0.08 J / mm 2 or more in [9] starting the accelerated cooling step after completion of the descaling step The time t [s] until the time satisfies the formula of t ⁇ 5 ⁇ 10 ⁇ 9 ⁇ exp (25000 / T).
- T Thick steel plate temperature (K) before cooling.
- the present invention by making the scale generated on the surface of the thick steel plate uniform in the descaling step, uniform cooling can be performed in the cooling step, and the thick steel plate having excellent thick steel plate shape and mechanical properties. Can be manufactured.
- FIG. 1 is a schematic view showing a thick steel plate manufacturing facility according to an embodiment of the present invention.
- FIG. 2 is a diagram for explaining a temperature distribution in the width direction of a thick steel plate of a conventional example.
- FIG. 3 is a graph showing the relationship between the energy density of the descaling water to be ejected and the scale thickness generated on the product surface of the thick steel plate in the descaling apparatus.
- FIG. 4 is a diagram illustrating the relationship between the spray distance of the spray nozzle and the fluid velocity in the descaling apparatus.
- FIG. 5 is a diagram showing the surface temperature distribution at the position in the width direction of the thick steel plate of the present invention.
- FIG. 6 is a schematic diagram showing the arrangement relationship of the spray nozzles of the descaling device, (a) is a schematic diagram showing the positional relationship of the spray nozzles, and (b) is a schematic diagram showing a spray pattern.
- FIG. 7 is a side view of the accelerated cooling apparatus according to the embodiment of the present invention.
- FIG. 8 is a side view of another accelerated cooling apparatus according to an embodiment of the present invention.
- FIG. 9 is a diagram for explaining an example of the nozzle arrangement of the partition wall according to the embodiment of the present invention.
- FIG. 10 is a diagram for explaining the flow of the cooling drainage on the partition wall.
- FIG. 11 is a diagram illustrating another flow of the cooling drainage on the partition wall.
- FIG. 12 is a view for explaining a temperature distribution in the width direction of a thick steel plate of a conventional example.
- FIG. 13 is a diagram illustrating the flow of cooling water in the acceleration cooling device.
- FIG. 14 is a diagram for explaining non-interference with cooling water on the partition wall in the accelerated cooling device.
- FIG. 1 is a schematic view showing a thick steel plate manufacturing facility according to an embodiment of the present invention.
- an arrow is a conveyance direction of a thick steel plate.
- the heating furnace 1, the descaling device 2, the rolling mill 3, the shape correcting device 4, the descaling device 6, the descaling device 7, and the accelerated cooling device 5 are arranged in this order.
- a slab (not shown), which is a rolling material, is reheated in a heating furnace 1, and then the slab is descaled in the descaling device 2 to remove the primary scale.
- the slab is subjected to rough rolling and finish rolling by a rolling mill 3 and rolled into a thick steel plate (not shown) having a predetermined plate thickness. Only one rolling mill 3 is illustrated. In addition, the rolling mill 3 may be comprised with the rough rolling mill and the finish rolling mill.
- the descaling device 6 and the descaling device 7 perform descaling to completely remove the scale.
- controlled cooling by water cooling or air cooling is performed in the acceleration cooling device 5.
- the shape correction device 4 corrects distortion generated in a thick steel plate during hot rolling.
- the shape correcting device is not limited to this, and a skin pass type or press type shape correcting device may be used. Further, when the rolling mill 3 is constituted by a rough rolling mill and a finishing rolling mill, skin pass correction may be performed by the finishing rolling mill.
- the thick steel plate is cooled to a predetermined temperature by the cooling water sprayed from the upper surface cooling facility and the lower surface cooling facility. Thereafter, if necessary, the shape of the thick steel plate is corrected by a shape correction device (not shown) provided further downstream or online.
- This shape correcting device corrects distortion generated in the thick steel plate during cooling by the accelerated cooling device 5.
- this shape correction device may not be used.
- this shape correction device may use a skin pass method or a press method shape correction device.
- two descaling devices that is, a descaling device 6 and a descaling device 7 are arranged between the shape correction device 4 and the acceleration cooling device 5.
- the energy density E of descaling water sprayed from the descaling device 6 and descaling device 7 onto the surface of the thick steel plate is 0.08 J / mm 2 or more in total of the two rows of spray nozzles.
- the scale generated on the surface of the thick steel plate is removed by the descaling device 6 and the descaling device 7, and then the thick steel plate is cooled by the accelerated cooling device 5, thereby improving the steel plate shape and mechanical characteristics of the thick steel plate. Can be made.
- the descaling device shown in FIG. 1 has only two columns.
- the descaling apparatus of 3 or more rows.
- the energy density E of descaling water sprayed on the surface of the thick steel plate is set to 0.08 J / mm 2 or more in total for the spray nozzles of the configured rows.
- the reason for this is as follows.
- the scale when scale removal is performed in a descaling apparatus after shape correction, the scale may be partially peeled off. Then, since the scale is not peeled off uniformly, the scale thickness varies about 10 to 50 ⁇ m. In this case, it is difficult to uniformly cool the thick steel plate in the subsequent accelerated cooling device. That is, if a thick steel plate having a variation in scale thickness distribution in a conventional rolling facility is accelerated and cooled, as shown in FIG. 2, the surface temperature varies widely in the width direction and cannot be uniformly cooled. As a result, the thick steel plate shape is affected.
- the present inventors have obtained the knowledge that the scale peeling is not sufficiently performed depending on the descaling condition, but rather the scale unevenness is promoted. And earnestly examined about the conditions by which scale peeling is fully performed.
- two or more rows of descaling devices are arranged in the longitudinal direction of the thick steel plate between the shape correction device and the acceleration cooling device, and two rows of the descaling device are arranged.
- the scale surface is cooled by the descaling water, so that a thermal stress is generated on the scale and an impact force by the descaling water acts.
- the scale is removed by peeling or breaking.
- the effect of thermal stress generated during descaling can be obtained twice or more by performing descaling twice or more after hot shape correction.
- FIG. 3 it turned out that the scale can be removed more efficiently when performed twice than when performed only once.
- the energy density E of the descaling water sprayed to the thick steel plate from the two rows of spray nozzles of the descaling device is 0.08 J / mm 2 or more in total, the product scale thickness can be reduced and uniformized.
- the number of injections shown in FIG. 3 is two. It has been confirmed by the present inventors that the same effect can be obtained even when the number of injections is three or more. This is because the scale is once completely peeled off uniformly by descaling, and then the scale is thinly and uniformly regenerated. Therefore, according to the present invention, the scale thickness of the thick steel plate before passing through the accelerated cooling device is thin and uniform, so there is almost no surface temperature variation in the width direction position of the thick steel plate when passing through the accelerated cooling device.
- the steel plate can be cooled uniformly and has a thick steel plate shape and excellent mechanical properties.
- the energy density E (J / mm 2 ) of descaling water sprayed on the thick steel plate is an index of the ability to remove the scale by descaling and is defined as the following equation (1).
- E Q ⁇ v 2 t ⁇ ( 2 dW) (1)
- Q Descaling water injection flow rate [m 3 / s]
- d Flat nozzle spray injection thickness [mm]
- W Flat nozzle spray injection width [mm]
- the present inventors adopted water density ⁇ injection pressure ⁇ collision time as a simple definition of the energy density E (J / mm 2 ) of descaling water injected into the thick steel plate. I found out that I should do.
- the water density (m 3 / (mm 2 ⁇ min)) is a value calculated by “descaled water injection flow rate ⁇ descaling water collision area”.
- the collision time (s) is a value calculated by “descaled water collision thickness ⁇ thick steel plate conveyance speed”.
- the discharge pressure of the pump becomes enormous, which is not preferable.
- the present inventors examined the fluid velocity v of the descaling water ejected from the spray nozzles of the descaling device 6 and the descaling device 7. As a result, it was found that the relationship between the fluid velocity v and the ejection distance is as shown in FIG.
- the fluid velocity on the vertical axis was obtained by solving an equation of motion considering buoyancy and air resistance. Until the descaling water reaches the thick steel plate, the fluid velocity v of the descaling water is reduced as compared with the time of jetting. For this reason, the smaller the injection distance, the larger the fluid velocity v at the time of the collision with the thick steel plate, and a larger energy density can be obtained. From FIG. 4, since the attenuation increases especially when the injection distance H exceeds 200 mm, the injection distance H is preferably 200 mm or less.
- the injection distance is shorter, the injection pressure and the injection flow rate for obtaining a predetermined energy density can be reduced, so that the pumping capacity of the descaling device 6 and the descaling device 7 can be reduced.
- the thick steel plate straightened by the shape straightening device 4 moves into the descaling device 6 and the descaling device 7.
- the spray nozzle of the scaling device 7 can be brought close to the surface of the thick steel plate.
- the spray distance is preferably 40 mm or more.
- the injection distance H is 40 mm or more and 200 mm or less.
- the injection pressure of the descaling water is preferably 14.7 MPa or more. There is no particular upper limit on the injection pressure. However, since the energy consumed by the pump that supplies the descaling water becomes enormous when the injection pressure is increased, the injection pressure is preferably 50 MPa or less.
- the descaling device 6 and the descaling device 7 in which the energy density E of descaling water ejected from two or more spray nozzles is set to 0.08 J / mm 2 or more are The scale generated on the surface of the steel plate is removed. As a result, there is no variation in the scale thickness distribution. Therefore, when the thick steel plate is cooled by the accelerated cooling device 5, as shown in FIG. It is possible to produce a thick steel plate having excellent shape and mechanical properties.
- the header headers 7-1 are arranged in two rows.
- the deske header shown in FIG. 6 (a) has two rows.
- the deske header may be composed of three or more rows.
- the upper limit is preferably 3 rows.
- the descaling water is sprayed from the spray nozzles 6-2 and 7-2 provided in the deske header to the thick steel plate to form a spray pattern 22 as shown in FIG.
- the arrangement relationship between the spray nozzles 6-2 and 7-2 of the descaling device 6 and the descaling device 7 is to prevent the splash water of the second row of descaling water from interfering with the descaling water of the first row. It is preferable that the distance is 500 mm or more in the longitudinal direction. Furthermore, it is preferable that the injection pattern in the width direction is staggered in the first and second rows as shown in FIG.
- the energy density of the descaling water sprayed from the two spray nozzles 6-2 and 7-2 is the same as the descaling of the second row after cracking the scale by the thermal stress effect of the descaling of the first row. If the scale is removed with a large energy density, the scale can be removed more efficiently.
- the energy density of the first row descaling water is preferably 0.01 J / mm 2 or more. It is preferable to make the energy density of water larger than the first row by 0.04 J / mm 2 or more.
- the nozzle rows are spaced apart by 500 mm or more in the longitudinal direction to form a staggered arrangement. Further, when the descaling device has three or more rows, the descaling water jetted from the jet nozzle of the descaling device in the row immediately before the final row is the same as the case of the descaling device having two rows.
- the energy density of the descaling water is 0.01 J / mm 2 or more, and the energy density of the descaling water ejected from the spray nozzle of the descaling device in the final row is 0.04 J / mm than the row immediately before the final row. It is preferable to increase it by 2 or more.
- the shape correction device 4 has corrected the shape of the thick steel plate, the spray nozzles of the descaling device 6 and the descaling device 7 can be brought close to the surface of the shape-corrected thick steel plate. As a result, the descaling capability is improved.
- the scale of the surface of a thick steel plate is generally expressed by the following formula (2), where the growth of the scale of the thick steel plate can be generally controlled by diffusion rate control.
- ⁇ 2 a ⁇ exp ( ⁇ Q / RT) ⁇ t (2)
- ⁇ scale thickness
- a constant
- Q activation energy
- R constant
- T thick steel plate temperature [K] before cooling
- t time.
- the following formula (3) can be derived based on the above formula (2). That is, the time t [s] from the end of descaling of the thick steel plate by the descaling device 7 on the downstream side of the descaling device 6 and the descaling device 7 until the accelerated cooling device 5 starts cooling the thick steel plate.
- the following equation (3) is satisfied, cooling by the acceleration cooling device 5 is stabilized.
- T Thick steel plate temperature [K] before cooling.
- the following formula (4) can be derived based on the above formula (2). That is, when the time t [s] from the end of removal of the scale of the thick steel plate by the descaling device 7 to the start of cooling of the thick steel plate by the acceleration cooling device 5 satisfies the following equation (4), acceleration is performed. Cooling by the cooling device 5 is more stable. t ⁇ 2.2 ⁇ 10 ⁇ 9 ⁇ exp (25000 / T) (4) Furthermore, when the scale thickness is 5 ⁇ m or less, the following formula (5) can be derived based on the above formula (2).
- the accelerated cooling is performed. Cooling by the device 5 is very stable. t ⁇ 5.6 ⁇ 10 ⁇ 10 ⁇ exp (25000 / T) (5)
- the distance L from the exit side of the descaling device 7 to the entrance side of the acceleration cooling device 5 is the transport speed V of the thick steel plate and time t (from the end of the descaling process by the descaling device 7 to the process of the acceleration cooling device 5 The time is set so as to satisfy the following expression (6).
- the cooling is very stable, which is preferable. More preferably, the distance L from the descaling device 7 to the acceleration cooling device 5 is 5 m or less.
- the distance L from the descaling device 7 to the accelerated cooling device 5 is preferably 12 m or less, more preferably 5 m or less, and even more preferably.
- the cooling can be stabilized by setting the length to 2.5 m or less.
- the upper surface cooling facility of the accelerated cooling device 5 of the present invention includes an upper header 11 that supplies cooling water to the upper surface of the thick steel plate 10, and cooling that jets rod-shaped cooling water suspended from the upper header 11.
- the water injection nozzle 13 and the partition 15 installed between the thick steel plate 10 and the upper header 11 are provided.
- the partition wall 15 is provided with a plurality of water supply ports 16 for inserting the lower end portion of the cooling water injection nozzle 13 and drain ports 17 for draining the cooling water supplied to the upper surface of the thick steel plate 10 onto the partition wall 15.
- it is.
- the upper surface cooling facility includes an upper header 11 for supplying cooling water to the upper surface of the thick steel plate 10, a cooling water injection nozzle 13 suspended from the upper header 11, and the upper header 11 and the thick steel plate 10. And a partition wall 15 having a large number of through-holes (water supply port 16 and drain port 17) installed horizontally in the width direction of the thick steel plate.
- the cooling water injection nozzle 13 is a circular pipe nozzle that injects rod-shaped cooling water, and its tip is inserted into a through-hole (water supply port 16) provided in the partition wall 15 and above the lower end portion of the partition wall 15. It is installed to become.
- the cooling water injection nozzle 13 may be inserted into the upper header 11 so that the upper end of the cooling water injection nozzle 13 protrudes into the upper header 11 in order to prevent the foreign matter at the bottom in the upper header 11 from being sucked and clogged. preferable.
- the rod-shaped cooling water in the present invention is cooling water injected in a state of being pressurized to some extent from a circular (including elliptical or polygonal) nozzle outlet, and is cooled from the nozzle outlet.
- the water injection speed is 6 m / s or more, preferably 8 m / s or more, and the water flow jetted from the nozzle outlet has a continuous circular shape, and the water flow has a continuous and straight flow.
- it is different from a free fall flow from a circular tube laminar nozzle or a liquid ejected in a droplet state such as a spray.
- the reason why the tip of the cooling water spray nozzle 13 is inserted into the through hole and is located above the lower end of the partition wall 15 is that the partition wall 15 is inserted even when a thick steel plate whose tip is warped upward enters. This is to prevent the cooling water injection nozzle 13 from being damaged. As a result, the cooling water injection nozzle 13 can be cooled for a long period of time in a good state, so that it is possible to prevent the occurrence of uneven temperature in the thick steel plate without repairing the equipment.
- the tip of the circular tube nozzle 13 is inserted into the through hole, as shown in FIG. 14, there is no interference with the flow in the width direction of the drained water indicated by the dotted arrow flowing through the upper surface of the partition wall 15. Therefore, the cooling water jetted from the cooling water jet nozzle 13 can reach the upper surface of the thick steel plate equally regardless of the position in the width direction, and uniform cooling in the width direction can be performed.
- a large number of through-holes having a diameter of 10 mm are formed in a grid pattern at a pitch of 80 mm in the thick steel plate width direction and 80 mm in the transport direction.
- a cooling water injection nozzle 13 having an outer diameter of 8 mm, an inner diameter of 3 mm, and a length of 140 mm is inserted into the water supply port 16.
- the cooling water injection nozzles 13 are arranged in a staggered pattern, and the through holes through which the cooling water injection nozzles 13 do not pass serve as cooling water drains 17.
- the large number of through holes provided in the partition wall 15 of the accelerated cooling device of the present invention are composed of the substantially same number of water supply ports 16 and drain ports 17, and each share a role and function.
- the total cross-sectional area of the drain port 17 is sufficiently larger than the total cross-sectional area of the inner diameter of the circular pipe nozzle 13 of the cooling water injection nozzle 13, and about 11 times the total cross-sectional area of the inner diameter of the circular pipe nozzle 13 is ensured.
- the cooling water supplied to the upper surface of the thick steel plate is filled between the thick steel plate surface and the partition wall 15, led to the upper side of the partition wall 15 through the drain port 17, and quickly discharged.
- the FIG. 10 is a front view for explaining the flow of cooling drainage in the vicinity of the end in the width direction of the thick steel plate on the partition wall.
- the drainage direction of the drainage port 17 is upward opposite to the cooling water injection direction, and the cooling drainage drained upward from the partition wall 15 changes the direction outward in the thick steel plate width direction, between the upper header 11 and the partition wall 15. It drains through the drainage channel.
- the drain port 17 is inclined in the thick steel plate width direction, and the slant direction is directed outward in the width direction so that the drain direction is directed outward in the thick steel plate width direction.
- the cooling water does not easily come out above the partition wall 15 after colliding with the steel plate, and the steel plate 10 And the partition wall 15 flow toward the end in the width direction of the thick steel plate. Then, since the flow rate of the cooling drainage between the thick steel plate 10 and the partition wall 15 increases as it approaches the end in the plate width direction, the force that the jet cooling water 18 penetrates the staying water film and reaches the thick steel plate is the plate width. The direction end portion is inhibited.
- the influence is limited because the plate width is about 2 m at most. However, the influence cannot be ignored especially in the case of a thick steel plate having a plate width of 3 m or more. Accordingly, the cooling at the end in the width direction of the thick steel plate is weakened, and the temperature distribution in the width direction of the thick steel plate in this case becomes a non-uniform temperature distribution.
- the water supply port 16 and the water discharge port 17 are provided separately and share the roles of water supply and water discharge. And smoothly flows above the partition wall 15. Accordingly, since the drainage after cooling is quickly removed from the upper surface of the thick steel plate, the cooling water supplied subsequently can easily penetrate the staying water film, and a sufficient cooling capacity can be obtained.
- the temperature distribution in the width direction of the thick steel plate is a uniform temperature distribution, and a uniform temperature distribution in the width direction can be obtained.
- the cooling water is discharged quickly. This can be realized, for example, by making holes larger than the outer diameter of the circular tube nozzle 13 in the partition wall 15 and making the number of drain ports equal to or greater than the number of water supply ports.
- the ratio of the total cross-sectional area of the drain outlet and the total cross-sectional area of the inner diameter of the circular tube nozzle 13 is preferably in the range of 1.5 to 20.
- the gap between the outer peripheral surface of the circular tube nozzle 13 inserted in the water supply port 16 of the partition wall 15 and the inner surface of the water supply port 16 be 3 mm or less. If this gap is large, the cooling drainage discharged to the upper surface of the partition wall 15 is drawn into the gap between the outer peripheral surface of the circular pipe nozzle 13 of the water supply port 16 due to the influence of the accompanying flow of the cooling water injected from the circular pipe nozzle 13. As a result, the steel sheet is again supplied onto the thick steel plate, resulting in poor cooling efficiency. In order to prevent this, it is more preferable that the outer diameter of the circular tube nozzle 13 is substantially the same as the size of the water supply port 16. However, in consideration of machining accuracy and mounting errors, a gap of up to 3 mm that has substantially little influence is allowed. More preferably, it is 2 mm or less.
- the nozzle inner diameter is preferably 3 to 8 mm. If it is smaller than 3 mm, the bundle of water sprayed from the nozzle becomes thin and the momentum becomes weak. On the other hand, when the nozzle diameter exceeds 8 mm, the flow rate becomes slow, and the force penetrating the staying water film becomes weak.
- the length of the circular tube nozzle 13 is preferably 120 to 240 mm.
- the length of the circular tube nozzle 13 here means the length from the inlet at the upper end of the nozzle that penetrates into the header to some extent to the lower end of the nozzle inserted into the water supply port of the partition wall.
- the distance between the lower surface of the header and the upper surface of the partition wall becomes too short (for example, the header thickness is 20 mm, the protrusion amount of the nozzle upper end into the header is 20 mm, and the insertion amount of the nozzle lower end into the partition wall is 10 mm. Therefore, the drainage space above the partition wall becomes small, and the cooling drainage cannot be discharged smoothly.
- the pressure loss of the circular tube nozzle 13 becomes large, and the force penetrating the staying water film becomes weak.
- the jet speed of cooling water from the nozzle is required to be 6 m / s or more, preferably 8 m / s or more. This is because if it is less than 6 m / s, the force of the cooling water penetrating through the staying water film becomes extremely weak. If it is 8 m / s or more, a larger cooling capacity can be secured, which is preferable.
- the distance from the lower end of the cooling water spray nozzle 13 for upper surface cooling to the surface of the thick steel plate 10 is preferably 30 to 120 mm. If it is less than 30 mm, the frequency with which the thick steel plate 10 collides with the partition wall 15 becomes extremely high, and equipment maintenance becomes difficult. If it exceeds 120 mm, the force through which the cooling water penetrates the staying water film becomes extremely weak.
- draining rolls 20 When cooling the upper surface of the thick steel plate, it is preferable to install draining rolls 20 before and after the upper header 11 so that the cooling water does not spread in the longitudinal direction of the thick steel plate. Thereby, the cooling zone length becomes constant and the temperature control becomes easy.
- the cooling drainage since the flow of the cooling water in the direction of transporting the thick steel plate is blocked by the draining roll 20, the cooling drainage flows outward in the width direction of the thick steel plate. However, the cooling water tends to stay in the vicinity of the draining roll 20.
- the cooling water jet nozzles in the uppermost stream side row in the thickness plate conveying direction are 15 to 15 upstream in the thickness plate conveying direction. It is preferable that the cooling water jet nozzles at the most downstream side in the thick steel plate conveyance direction are inclined 15 to 60 degrees in the downstream direction in the thick steel plate conveyance direction.
- the distance between the lower surface of the upper header 11 and the upper surface of the partition wall 15 is such that the cross-sectional area in the width direction of the thick steel plate in the space surrounded by the lower surface of the header and the upper surface of the partition wall is 1.5 times the total cross-sectional area of the cooling water spray nozzle inner diameter. For example, it is about 100 mm or more.
- the cross-sectional area of the thick steel plate in the width direction is not 1.5 times or more than the total cross-sectional area of the cooling water jet nozzle inner diameter, the cooling drainage discharged from the drain port 17 provided on the partition wall to the top surface of the partition wall 15 is smoothly thick. It cannot be discharged in the width direction of the steel sheet.
- the range of the water density that exhibits the most effect is 1.5 m 3 / (m 2 ⁇ min) or more.
- the staying water film does not become so thick, and even if a known technique for cooling the steel plate by free-falling the rod-shaped cooling water is applied, the temperature unevenness in the width direction does not become so large. In some cases.
- the water density is higher than 4.0 m 3 / (m 2 ⁇ min)
- 1.5 to 4.0 m 3 / (m 2 ⁇ min) is the most practical water density.
- the application of the cooling technique of the present invention is particularly effective when a draining roll is arranged before and after the cooling header.
- the header is relatively long in the longitudinal direction (when it is about 2 to 4 m), and it is applied to cooling equipment that sprays water spray for purging before and after the header to prevent water leakage to the non-water cooling zone. Is also possible.
- the cooling device on the lower surface side of the thick steel plate is not particularly limited.
- an example of the cooled header 12 including the circular tube nozzle 14 similar to the cooling device on the upper surface side is shown.
- the injected cooling water naturally falls after colliding with the thick steel plate. Therefore, there is no need for the partition wall 15 for discharging cooling drainage like the upper surface side cooling in the width direction of the thick steel plate.
- the thick steel plate manufacturing equipment of the present invention two or more rows of spray nozzles of descaling water are arranged as the descaling device 6 and the descaling device 7, and the steel plate 10 is formed from the two or more rows of spray nozzles.
- the energy density E injected toward the surface is set to a total of 0.08 J / mm 2 or more, the scale generated in the thick steel plate 10 is made uniform, and the accelerated cooling device 5 performs uniform cooling. Can be planned.
- the thick steel plate 10 excellent in the shape of the thick steel plate can be manufactured.
- the spray nozzles of the descaling device 6 and the descaling device 7 can be brought closer to the surface of the thick steel plate 10.
- the spray distance H (the distance between the spray nozzles of the descaling device 6 and the descaling device 7 and the surface of the thick steel plate 10) is set to 40 mm or more and 200 mm or less, the descaling capability is improved. Further, since the injection pressure and the injection flow rate for obtaining the predetermined energy density E may be small, the pumping capacity of the descaling device 6 and the descaling device 7 can be reduced.
- the distance L from the descaling device 7 on the downstream side of the descaling device 6 and the descaling device 7 to the acceleration cooling device 5 satisfies L ⁇ V ⁇ 5 ⁇ 10 ⁇ 9 ⁇ exp (25000 / T). Thereby, cooling of the thick steel plate 10 by the accelerated cooling device 5 can be stabilized.
- the cooling water supplied from the upper cooling water injection nozzle 13 through the water supply port 16 cools the upper surface of the thick steel plate 10 and has a high temperature. It becomes drainage and flows in the width direction of the thick steel plate 10 from above the partition wall 15 using the drainage port 17 through which the upper cooling water spray nozzle 13 is not inserted as a drainage channel. Since the drainage after cooling is quickly eliminated from the thick steel plate 10, the cooling water flowing from the upper cooling water jet nozzle 13 through the water supply port 16 sequentially contacts the thick steel plate 10, Sufficient and uniform cooling capacity in the width direction can be obtained.
- the temperature unevenness in the width direction of the thick steel plate subjected to accelerated cooling without performing descaling as in the present invention was about 40 ° C.
- the temperature unevenness in the width direction of the thick steel plate cooled by the accelerated cooling device 5 is reduced to about 10 ° C. I understood it.
- the descaling is performed by the descaling device 6 and the descaling device 7, the uneven temperature in the width direction of the thick steel plate subjected to the accelerated cooling using the accelerated cooling device 5 shown in FIG. It turned out to decrease.
- the temperature unevenness of the thick steel plate was measured by measuring the surface temperature distribution of the thick steel plate after accelerated cooling with a scanning thermometer, and the temperature unevenness in the width direction was calculated from the measurement result.
- the distortion generated during rolling is corrected by the shape correction device 4, and the descaling device 6 and the descaling device 7 are descaled to stabilize the cooling controllability. Therefore, the thick steel plate 10 that is straightened by the shape straightening device that is provided online or offline downstream of the thick steel plate manufacturing facility originally has a high flatness and a uniform temperature. Therefore, it is not necessary to increase the correction force of the shape correction device provided downstream. Moreover, the distance between the acceleration cooling device 5 and the shape correcting device provided downstream is preferably longer than the maximum length of the thick steel plate 10 manufactured by the rolling line. Thereby, since reverse correction etc.
- the shape straightening device provided downstream, the effect of preventing troubles such as the reversely fed thick steel plate 10 jumping on the transport roll and colliding with the acceleration cooling device 5 is achieved.
- a slight temperature deviation generated during cooling in the accelerating cooling device 5 can be made uniform, and an effect of avoiding warpage caused by the temperature deviation after correction can be expected.
- a thick steel plate having a thickness of 30 mm and a width of 3500 mm rolled by the rolling mill 3 was subjected to controlled cooling from 820 ° C. to 420 ° C. after passing through the shape correction device 4, the descaling device 6 and the descaling device 7.
- the conditions under which the cooling is stabilized are calculated from the above-described equations (3), (4), and (5).
- the accelerated cooling device 5 The time t until the start of cooling is preferably 42 s or less, more preferably 19 s or less, and even more preferably 5 s or less.
- the surface distance between the injection nozzle and the thick steel plate of the scaling device 6 and the descaling device 7 is 130 mm, the nozzle injection angle is 66 °, the angle of attack is 15 °, and the injection direction of the adjacent nozzles is wrapped to some extent.
- the spray spray thickness was 3 mm, and the spray spray width was 175 mm.
- the nozzle was a flat spray nozzle.
- the energy density of descaling water is a value defined by the above-mentioned water amount density ⁇ injection pressure ⁇ collision time.
- the collision time (s) is the time during which descaling water is sprayed on the surface of the thick steel plate, and is obtained by dividing the spray spray thickness by the transport speed.
- the accelerated cooling device 5 is provided with a flow path that allows the cooling water supplied to the upper surface of the thick steel plate to flow above the partition as shown in FIG. 7, and further drains from the side of the thick steel plate width direction as shown in FIG.
- the equipment In the partition, holes with a diameter of 12 mm are drilled like a grid, and as shown in FIG. 9, upper cooling water injection nozzles are inserted into the water supply ports arranged in a staggered pattern, and the remaining holes are used as drainage ports. Using.
- the distance between the lower surface of the upper header and the upper surface of the partition wall was 100 mm.
- the upper cooling water spray nozzle of the accelerated cooling device 5 had an inner diameter of 5 mm, an outer diameter of 9 mm, and a length of 170 mm, and its upper end protruded into the header. Moreover, the injection speed of the rod-shaped cooling water was 8.9 m / s.
- the nozzle pitch in the thick steel plate width direction was 50 mm, and 10 rows of nozzles were arranged in the longitudinal direction in a zone having a distance between table rollers of 1 m.
- the water density on the upper surface was 2.1 m 3 / (m 2 ⁇ min).
- the lower end of the nozzle for cooling the upper surface was set so as to be in the middle position between the upper and lower surfaces of the partition wall having a thickness of 25 mm, and the distance to the surface of the thick steel plate was 80 mm.
- the cooling equipment similar to the top surface cooling equipment is used except that no partition wall is provided as shown in FIG. did.
- T is the thick steel plate temperature (K) before cooling.
- Thick steel plate shape was evaluated by re-correction rate (%). Specifically, if the warpage of the total length of the thick steel plate and / or the warpage of the full width of the thick steel plate is within the standard value defined in the product standard corresponding to the thick steel plate, if it exceeds the standard value
- the re-correction rate was calculated as (number of re-correction execution materials) / (total number of target materials) ⁇ 100.
- Invention Examples 1 to 5 in Table 1 all had an energy density of 0.08 J / mm 2 or more, and therefore, the re-correction rate due to shape defects was low, and good results were obtained. This is because, when cooled by the acceleration cooling device 5, the surface temperature in the position in the width direction is almost uniform and is cooled uniformly, which is superior in mechanical properties and is considered to be caused by the temperature distribution of the thick steel plate. As a result, it is considered that the recorrection rate due to the shape defect is low. In each of Invention Examples 1 to 5, the scale was removed and the surface properties were good. The surface property was evaluated by determining the presence or absence of scale from image processing using the color tone difference between the remaining scale part and the peeled part using an image of the surface of the thick steel plate cooled to room temperature.
- the inventive examples 1 to 4 in which the distance from the descaling device 7 in the most downstream row to the acceleration cooling device 5 with respect to the transport direction is 5 m, after the removal of the scale of the thick steel plate by the descaling device 7,
- the time t until the accelerated cooling device 5 starts cooling the thick steel plate was 19 s or less, which is a condition that the cooling by the accelerated cooling device 5 becomes more stable, regardless of the conveying speed V of the thick steel plate. Therefore, the recorrection rate was as good as 5% or less.
- the recorrection rate was 12%, which was a pass, but was inferior to Inventive Examples 1 to 4. This is considered to be because the scale became thick and the cooling became unstable because the time from the end of scale removal to the start of cooling by the accelerated cooling device 5 was as long as 46 s.
- the scale generated on the surface of the thick steel plate can be made uniform. Cooling by the accelerated cooling device 5 was performed. For this reason, the re-correction rate became 40% due to the deterioration of flatness, which is considered to be caused by the temperature distribution of the thick steel plate, and the mechanical characteristics also varied.
- the energy density was 66 °
- the angle of attack was 15 °
- the energy density was 0.06 J / mm 2 in total of the three times of descaling
- the energy density of the descaling water was not sufficiently large.
- the scale partially peeled off, and the temperature distribution in the thick steel plate width direction deteriorated. For this reason, the re-correction rate was 69%, and the mechanical characteristics also varied.
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Abstract
Description
[1]熱間圧延機、形状矯正装置、デスケーリング装置及び加速冷却装置をこの順序で搬送方向上流側から配置し、前記デスケーリング装置の噴射ノズルは厚鋼板の長手方向に対して2列配置され、前記2列の噴射ノズルから厚鋼板の表面に向けて噴射されるデスケーリング水の持つエネルギー密度Eを、合計で0.08J/mm2以上とすることを特徴とする厚鋼板の製造設備。
[2]熱間圧延機、形状矯正装置、デスケーリング装置及び加速冷却装置をこの順序で搬送方向上流側から配置し、前記デスケーリング装置の噴射ノズルは厚鋼板の長手方向に対して2列以上配置され、前記2列以上の噴射ノズルから厚鋼板の表面に向けて噴射されるデスケーリング水の持つエネルギー密度Eを、合計で0.08J/mm2以上とすることを特徴とする厚鋼板の製造設備。
[3]前記デスケーリング装置から前記加速冷却装置までの搬送速度をV[m/s]、冷却前の厚鋼板温度をT[K]とすると、前記デスケーリング装置から前記加速冷却装置までの距離L[m]は、L≦V×5×10-9×exp(25000/T)の式を満たしていることを特徴とする[1]または[2]記載の厚鋼板の製造設備。
[4]前記デスケーリング装置から前記加速冷却装置までの距離Lが12m以下とすることを特徴とする[3]に記載の厚鋼板の製造設備。
[5]前記デスケーリング装置の噴射ノズルから前記厚鋼板の表面までの距離Hを、40mm以上で200mm以下とすることを特徴とする[1]乃至[4]の何れか1項に記載の厚鋼板の製造設備。
[6]前記加速冷却装置が、前記厚鋼板の上面に冷却水を供給するヘッダと、該ヘッダから懸垂した棒状冷却水を噴射する冷却水噴射ノズルと、前記厚鋼板と前記ヘッダとの間に設置される隔壁とを備えるとともに、前記隔壁には、前記冷却水噴射ノズルの下端部を内挿する給水口と、前記厚鋼板の上面に供給された冷却水を前記隔壁上へ排水する排水口とが、多数設けられていることを特徴とする[1]乃至[5]の何れか1項に記載の厚鋼板の製造設備。
[7]熱間圧延工程、熱間矯正工程及び加速冷却工程の順番で厚鋼板を製造する方法において、前記熱間矯正工程及び加速冷却工程の間に、厚鋼板の表面にエネルギー密度Eが合計で0.08J/mm2以上となるようにデスケーリングを2回行うデスケーリング工程を有することを特徴とする厚鋼板の製造方法。
[8]熱間圧延工程、熱間矯正工程及び加速冷却工程の順番で厚鋼板を製造する方法において、前記熱間矯正工程及び加速冷却工程の間に、厚鋼板の表面にエネルギー密度Eが合計で0.08J/mm2以上となるようにデスケーリングを2回以上行うデスケーリング工程を有することを特徴とする厚鋼板の製造方法
[9]前記デスケーリング工程の完了から前記加速冷却工程の開始までの時間t[s]は、t≦5×10-9×exp(25000/T)の式を満たしていることを特徴とする[7]または[8]に記載の厚鋼板の製造方法。ただし、T:冷却前の厚鋼板温度(K)である。
E=Qρv2t÷(2dW)…(1)
ただし、Q:デスケーリング水の噴射流量[m3/s]、d:フラットノズルのスプレー噴射厚み[mm]、W:フラットノズルのスプレー噴射幅[mm]、流体密度ρ[kg/m3]、厚鋼板衝突時の流体速度v[m/s]、衝突時間t[s](t=d/1000V、搬送速度V[m/s])である。
ξ2=a×exp(-Q/RT)×t…(2)
ただし、ξ:スケール厚み、a:定数、Q:活性化エネルギー、R:定数、T:冷却前の厚鋼板温度[K]、t:時間である。
t≦5×10-9×exp(25000/T)…(3)
ただし、T:冷却前の厚鋼板温度[K]である。
t≦2.2×10-9×exp(25000/T)…(4)
さらに、スケール厚みが5μm以下の場合、上記(2)式に基づき、下記式(5)を導出することができる。すなわち、デスケーリング装置7による厚鋼板のスケール除去終了後から、加速冷却装置5で厚鋼板の冷却を開始するまでの時間t[s]が、次の(5)式を満たす場合に、加速冷却装置5による冷却が非常に安定する。
t≦5.6×10-10×exp(25000/T)…(5)
一方、デスケーリング装置7の出側から加速冷却装置5の入り側までの距離Lは、厚鋼板の搬送速度Vと、時間t(デスケーリング装置7によるデスケーリング工程終了から加速冷却装置5の工程開始までの時間)とに対して次の(6)式を満たすように設定する。
L≦V×t…(6)
ただし、L:デスケーリング装置7から加速冷却装置5までの距離(m)、V:厚鋼板の搬送速度(m/s)、t:時間(s)
そして、上記(6)式と上記(3)式とから、次の(7)式を導出することができる。本発明において、(7)式を満足することがより好ましい。
L≦V×5×10-9×exp(25000/T)…(7)
また、上記(6)式と上記(4)式とから、次の(8)式を導出することができる。本発明において、(8)式を満足することがさらに好ましい。
L≦V×2.2×10-9×exp(25000/T)…(8)
さらに、上記(6)式と上記(5)式とから、次の(9)式を導出することができる。本発明において、(9)式を満足することが好ましい。
L≦V×5.6×10-10×exp(25000/T)…(9)
上記の(7)~(9)式から、例えば加速冷却装置5による冷却前の厚鋼板の温度を820℃とし、厚鋼板の搬送速度を0.28~2.50m/sとすると、デスケーリング装置7から加速冷却装置5までの距離Lは12m以上107m以下で冷却が安定し、5m以上47m以下で冷却がより安定し、1.3m以上12m以下で冷却が非常に安定する。
2 デスケーリング装置
3 圧延機
4 形状矯正装置
5 加速冷却装置
6 デスケーリング装置
6-1 デスケヘッダー
6-2 噴射ノズル
7 デスケーリング装置
7-1 デスケヘッダー
7-2 噴射ノズル
10 厚鋼板
11 上ヘッダ
12 下ヘッダ
13 上冷却水噴射ノズル(円管ノズル)
14 下冷却水噴射ノズル(円管ノズル)
15 隔壁
16 給水口
17 排水口
18 噴射冷却水
19 排出水
20 水切ロール
21 水切ロール
22 スプレーパターン
Claims (9)
- 熱間圧延機、形状矯正装置、デスケーリング装置及び加速冷却装置をこの順序で搬送方向上流側から配置し、前記デスケーリング装置の噴射ノズルは厚鋼板の長手方向に対して2列配置され、前記2列の噴射ノズルから厚鋼板の表面に向けて噴射されるデスケーリング水の持つエネルギー密度Eを、合計で0.08J/mm2以上とすることを特徴とする厚鋼板の製造設備。
- 熱間圧延機、形状矯正装置、デスケーリング装置及び加速冷却装置をこの順序で搬送方向上流側から配置し、前記デスケーリング装置の噴射ノズルは厚鋼板の長手方向に対して2列以上配置され、前記2列以上の噴射ノズルから厚鋼板の表面に向けて噴射されるデスケーリング水の持つエネルギー密度Eを、合計で0.08J/mm2以上とすることを特徴とする厚鋼板の製造設備。
- 前記デスケーリング装置から前記加速冷却装置までの搬送速度をV[m/s]、冷却前の厚鋼板温度をT[K]とすると、前記デスケーリング装置から前記加速冷却装置までの距離L[m]は、L≦V×5×10-9×exp(25000/T)の式を満たしていることを特徴とする請求項1または2記載の厚鋼板の製造設備。
- 前記デスケーリング装置から前記加速冷却装置までの距離Lが12m以下とすることを特徴とする請求項3に記載の厚鋼板の製造設備。
- 前記デスケーリング装置の噴射ノズルから前記厚鋼板の表面までの距離Hを、40mm以上で200mm以下とすることを特徴とする請求項1乃至4の何れか1項に記載の厚鋼板の製造設備。
- 前記加速冷却装置が、前記厚鋼板の上面に冷却水を供給するヘッダと、該ヘッダから懸垂した棒状冷却水を噴射する冷却水噴射ノズルと、前記厚鋼板と前記ヘッダとの間に設置される隔壁とを備えるとともに、前記隔壁には、前記冷却水噴射ノズルの下端部を内挿する給水口と、前記厚鋼板の上面に供給された冷却水を前記隔壁上へ排水する排水口とが、多数設けられていることを特徴とする請求項1乃至5の何れか1項に記載の厚鋼板の製造設備。
- 熱間圧延工程、熱間矯正工程及び加速冷却工程の順番で厚鋼板を製造する方法において、前記熱間矯正工程及び加速冷却工程の間に、厚鋼板の表面にエネルギー密度Eが合計で0.08J/mm2以上となるようにデスケーリングを2回行うデスケーリング工程を有することを特徴とする厚鋼板の製造方法。
- 熱間圧延工程、熱間矯正工程及び加速冷却工程の順番で厚鋼板を製造する方法において、前記熱間矯正工程及び加速冷却工程の間に、厚鋼板の表面にエネルギー密度Eが合計で0.08J/mm2以上となるようにデスケーリングを2回以上行うデスケーリング工程を有することを特徴とする厚鋼板の製造方法。
- 前記デスケーリング工程の完了から前記加速冷却工程の開始までの時間t[s]は、t≦5×10-9×exp(25000/T)の式を満たしていることを特徴とする請求項7または8に記載の厚鋼板の製造方法。ただし、T:冷却前の厚鋼板温度(K)である。
Priority Applications (5)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
KR1020177004919A KR101940428B1 (ko) | 2014-08-26 | 2015-08-14 | 후강판의 제조 설비 및 제조 방법 |
BR112017003566-9A BR112017003566B1 (pt) | 2014-08-26 | 2015-08-14 | Método de fabricação de uma placa de aço espessa |
EP15836765.6A EP3195946B1 (en) | 2014-08-26 | 2015-08-14 | Thick steel plate manufacturing method |
CN201580045928.4A CN106794500B (zh) | 2014-08-26 | 2015-08-14 | 厚钢板的制造设备及制造方法 |
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JP2012077325A (ja) * | 2010-09-30 | 2012-04-19 | Jfe Steel Corp | ラインパイプ用高強度鋼板及びその製造方法並びにラインパイプ用高強度鋼板を用いた高強度鋼管 |
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JPH0957327A (ja) | 1995-08-22 | 1997-03-04 | Sumitomo Metal Ind Ltd | 厚鋼板のスケール除去方法 |
JP3796133B2 (ja) | 2000-04-18 | 2006-07-12 | 新日本製鐵株式会社 | 厚鋼板冷却方法およびその装置 |
JP2003181522A (ja) * | 2001-12-14 | 2003-07-02 | Nippon Steel Corp | 表面性状の優れた鋼板の製造方法及びその装置 |
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JP2012077325A (ja) * | 2010-09-30 | 2012-04-19 | Jfe Steel Corp | ラインパイプ用高強度鋼板及びその製造方法並びにラインパイプ用高強度鋼板を用いた高強度鋼管 |
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JP6264464B2 (ja) | 2018-01-24 |
BR112017003566A2 (pt) | 2017-12-05 |
BR112017003566B1 (pt) | 2022-12-06 |
JPWO2016031168A1 (ja) | 2017-04-27 |
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