This is the U.S. National Phase application of PCT/JP2013/006952, filed Nov. 27, 2013, which claims priority to Japanese Patent Application No. 2012-280418, filed Dec. 25, 2012, the disclosures of these applications being incorporated herein by reference in their entireties for all purposes.
The present invention relates to a cooling method and a cooling apparatus that make it possible to, when a hot-rolled steel strip is cooled by controlled cooling in a hot-rolled steel strip manufacturing line, regulate the rate at which the hot-rolled steel strip is cooled, in a multistage manner.
A hot-rolled steel strip (hereinafter also simply referred to as a steel strip) is manufactured by rolling a heated slab such that the slab has a desired size. In this case, the hot-rolled steel strip is cooled using cooling water (water cooling) by a cooling apparatus during hot rolling (rough rolling, finish rolling) or after finish rolling. The purpose of this water cooling is to mainly control deposit or transformation structure of the steel strip and to regulate the quality of material so that intended strength, ductility, and the like can be obtained. In particular, accurately controlling at a predetermined temperature in the cooling after finish rolling is important in manufacturing hot-rolled steel strips having intended material properties without variation.
In recent years, as a result of soaring rare metal costs, methods have been developed that improve mechanical properties by transformation structure control based on cooling instead of alloy composition regulation. In the above-described water cooling, there is a great need for wide range control of cooling rate in response to requirements for material quality. In a typical run out table in the manufacturing of a hot-rolled steel strip, arrangement of pipe laminar nozzles for the upper surface and spray nozzles for the lower surface is often used as a cooling apparatus. The amount of cooling water is about 0.4 to 1.0 m3/min·m2 per one surface. For a steel strip having a thickness of 3 mm, a cooling rate of about 50 to 70° C./s is provided.
Recently, as regards hot-rolled high tensile strength steel, there has been a great need for further increasing cooling rate and aggressively performing transformation structure control. On the other hand, steel strips used, for example, for automotive bodies are sometimes soft steel strips and are formed into complicated shapes from the viewpoint of design or the like. Such steel strips are often required to have workability such as ductility rather than strength. If the cooling rate is too high, this workability may be impaired. So, such a cooling technique that cooling rate can be largely changed using the same cooling apparatus is required.
As regards hot-rolled steel strips, the passing performance of steel strips varies depending on, in particular, thickness. Unfortunately, difficulties occur. As regards high tensile steel for automobiles, most of steel strips have thicknesses from about 1.2 to 3.0 mm. In particular, a thin steel strip having a thickness of about 1.2 mm has poor stiffness and provides high passing speed. Accordingly, if the steel strip is passed while a large amount of cooling water is poured, the steel strip tends to bound or loop due to fluid resistance. So, a technique for reducing the amount of cooling water only when the thickness is small is also needed.
As described above, there is a great need for a technique for controlling cooling rate/amount of cooling water in order to control the size and target material of a steel strip. In response to this, there is, for example, a cooling technique described in Patent Literature 1.
Patent Literature 1: Japanese Unexamined Patent Application Publication No. 59-47010
Patent Literature 1 describes, as an example of a typical cooling apparatus, a technique to change the flow rate density using spray pressure. According to this technique, the flow rate of cooling water is proportional to the spray pressure raised to the power of 0.5. Therefore, if the spray pressure is decreased, the change in flow rate is small. Therefore, it is very difficult to largely change the cooling rate. In general, it is said that the cooling rate is proportional to the amount of cooling water raised to the power of about 0.7. Therefore, the change in cooling rate is proportional to the spray pressure raised to the power of about 0.35. Therefore, for example, when reducing the cooling rate by about half, it is beneficial to reduce the spray pressure by about 1/7. However, it is difficult to cause a typical flow control valve to carry out such an operation.
Patent Literature 1 discloses a technique concerning such an apparatus that spray nozzles are arranged in a water tank in a lower surface cooling apparatus, the spray nozzles are submerged by filling the water tank with cooling water, and cooling is performed by swirling up the cooling water in the water tank using the momentum of sprayed water. This technique changes the distance between the liquid level of the water tank and the tips of the spray nozzles in order to regulate the amount of swirled-up water.
A problem of this technique is that, particularly in the case of the lower surface of a steel strip, sprayed cooling water falls into the water tank after colliding with the steel strip, therefore the water tank is always supplied with a very large amount of water, and the regulation of liquid level is difficult. In the water tank into which a large amount of water falls from above, due to the fallen water, waves are formed locally on the liquid surface, and the liquid level fluctuates. Therefore, the amount of water swirled up by each nozzle changes, and the flow rate of spray to the steel strip varies.
There also is a publicly known technique to make the cooling rate variable by changing the cooling water amount density by changing the distance between spray nozzles and a slab in continuous casting equipment. Cooling water sprayed from spray nozzles is sprayed so as to spread at an angle. Therefore, the larger the distance between a steel strip and nozzles, the smaller the amount of cooling water per unit area (water amount density), and the cooling rate can be regulated.
The above-described technique changes the flow rate density by changing the distance between a steel strip and nozzles. Therefore, in principle, regulation of cooling rate is easy. However, on the steel strip lower surface side of the run out table, where space is narrow, changing the height regulating function of nozzles is difficult. As regards the lower surface of the steel strip, cooling water colliding with the steel strip falls. Therefore, cooling headers are always exposed to cooling water. Therefore, a nozzle elevating mechanism for changing the distance from the steel strip may fail to operate due to corrosion or the like. Since the height of spray nozzles is regulated, the area of cooling water colliding with the steel strip changes. If the distance between the steel strip and spray nozzles is extremely increased, the cooling area becomes excessively large, cooling water may collide with and be blocked by table rollers or the like, the flow rate density is difficult to control, effective cooling of the steel strip is not performed, and this is not economical.
The present invention has been made in consideration of the above-described circumstances and provides a cooling method and a cooling apparatus effective in cooling the lower surface of a hot-rolled steel strip, particularly in cooling the lower surface of a steel strip, where space is narrow.
To solve the above-described problems, the present invention includes the following aspects.
[1] A method for cooling a hot-rolled steel strip, comprising: preparing a cooling apparatus including a plurality of cooling headers having a plurality of spray nozzles arranged in a width direction, the cooling headers being arranged in a steel strip conveying direction, supply of cooling water being performed using two systems as one set in the cooling headers, valves being attached to the two systems of supply pipes of cooling water so that spraying or stop of spraying of cooling water can be independently performed; spray nozzles adjacent in the width direction being connected to supply pipes of different systems of the two systems of supply pipes,
wherein when increasing cooling rate, cooling water is supplied to one set of cooling headers from two systems of supply pipes and cooling water is sprayed from all of the spray nozzles of the one set of cooling headers, and wherein when decreasing cooling rate, cooling water is supplied to one set of cooling headers from one system of supply pipe and cooling water is sprayed from every other spray nozzle attached to the one set of cooling headers in the width direction.
[2] The method for cooling a hot-rolled steel strip according to the above-described [1], wherein two sets of the cooling headers in the steel strip conveying direction are referred to as a pair, spray nozzles attached to the pair of cooling headers are placed at the same position in the steel strip conveying direction, and when spraying cooling water from one system of the two systems of supply pipes in each pair, the spray nozzles of the pair of two sets spray cooling water from alternate positions in the width direction.
[3] The method for cooling a hot-rolled steel strip according to the above-described [1] or [2], wherein the spray nozzles have a rectangular or elliptic spray pattern, and are arranged in such a manner that, when performing supply of cooling water from two systems and when cooling water collides with the steel strip, the position of the end of the spray colliding part collides with a position located on the opposite side of the central axis of the adjacent nozzle from the nozzle spraying cooling water and located 0 to 30 mm from the central axis of the adjacent nozzle.
[4] The method for cooling a hot-rolled steel strip according to any one of the above-described [1] to [3], wherein two sets of the cooling headers in the steel strip conveying direction are referred to as a pair, and in the pair, spray nozzles attached in the width direction are placed at the same position in the steel strip conveying direction, and the nozzle attachment positions in the width direction of cooling headers of adjacent pairs are displaced by ½ of nozzle attachment pitch.
[5] The method for cooling a hot-rolled steel strip according to any one of the above-described [1] to [4], wherein the upper surface and lower surface of the steel strip differ in cooling water amount density, and, in each cooling headers for the upper surface and lower surface of the steel strip, the number of supply pipes for cooling water is changed individually.
[6] The method for cooling a hot-rolled steel strip according to any one of the above-described [1] to [5], wherein the method is applied to cooling of the lower surface of the steel strip.
[7] A cooling apparatus including a plurality of cooling headers having a plurality of spray nozzles arranged in a width direction, the cooling headers being arranged in a steel strip conveying direction,
wherein supply of cooling water is performed using two systems as one set in the cooling headers, spray valves are attached to the two systems of supply pipes of cooling water so that spraying or stop of spraying of cooling water can be independently performed, and spray nozzles adjacent in the width direction have pipe systems connected to supply pipes of different systems of the two systems of supply pipes, and
wherein the apparatus includes a control mechanism that makes it possible to, when increasing cooling rate, supply cooling water to one set of cooling headers from two systems of supply pipes and spray cooling water from all of the spray nozzles of the one set of cooling headers, and to, when decreasing cooling rate, supply cooling water to one set of cooling headers from one system of supply pipe and spray cooling water from every other spray nozzle attached to the one set of cooling headers in the width direction.
[8] The apparatus for cooling a hot-rolled steel strip according to the above-described [7], wherein two sets of the cooling headers in the steel strip conveying direction are referred to as a pair, and spray nozzles attached to the pair of cooling headers are placed at the same position in the steel strip conveying direction, and wherein the apparatus has a control function capable of opening and closing the spray valves in such a manner that, when spraying cooling water from one system of the two systems of supply pipes in each pair, the spray nozzles of the pair of two sets spray cooling water from alternate positions in the width direction.
[9] The apparatus for cooling a hot-rolled steel strip according to the above-described [7] or [8], wherein the spray nozzles have a rectangular or elliptic spray pattern, and are arranged in such a manner that, when cooling water collides with the steel strip, the position of the end of the spray colliding part is located on the opposite side of the central axis of the adjacent nozzle from the nozzle spraying cooling water and is located 0 to 30 mm from the central axis of the adjacent nozzle.
[10] The apparatus for cooling a hot-rolled steel strip according to any one of the above-described [7] to [9], wherein two sets of the cooling headers in the steel strip conveying direction are referred to as a pair, and in the pair, spray nozzles attached in the width direction are placed at the same position in the steel strip conveying direction, and the nozzle attachment positions in the width direction of cooling headers of adjacent pairs are displaced by ½ of nozzle attachment pitch.
[11] The apparatus for cooling a hot-rolled steel strip according to any one of the above-described [7] to [10], wherein the apparatus has a control function that, when two-system cooling water is supplied, is capable of spraying in such a manner that the upper surface and lower surface of the steel strip differ in cooling water amount density, and is capable of opening and closing the spray valves in order to change the number of supply systems for cooling water individually, in each cooling headers for the upper surface and lower surface of the steel strip.
[12] The apparatus for cooling a hot-rolled steel strip according to any one of the above-described [7] to [11], wherein the apparatus is applied to cooling of the lower surface of the steel strip.
The present invention can provide a cooling technique that, in the cooling of a hot-rolled steel strip, regulates the amount of cooling water in a two-stage manner for each set of headers in the width direction and changes the rate at which the steel strip is cooled, in a multistage manner by a simple method, and that is effective particularly in cooling the lower surface of the steel strip, where space is narrow.
By applying the present invention to the cooling after finish rolling in the hot-rolled steel strip manufacturing line, the cooling rate can be easily regulated. Therefore, various hot-rolled steel strips can be made. In addition, it is made possible to manufacture hot-rolled steel strips having the same strength, toughness, and the like as those of conventional ones without adding a special element.
Embodiments of the present invention will be described with reference to the drawings.
As regards the hot-rolled steel strip, a slab (having a thickness of, for example, 250 mm), which is a raw material, is heated (up to, for example, 1200° C.) by a heating furnace 30 and is subsequently rolled at a predetermined thickness through a rough rolling mill group 31 and a finish rolling mill group 32 and is then cooled by a cooling apparatus 33 and is coiled by a coiler 34.
Thus, in a set of lower surface cooling apparatuses arranged between table rollers, the spray amount of cooling water can be regulated by alternately performing spray in the width direction from adjacent spray pipes as two-system cooling water shown in
Suppose that the spray rate in the case where the pipe laminar nozzles 3 for the upper surface discharge sprays is 50%, the spray rate in the case where spray cooling apparatuses 4 for the lower surface discharge sprays in a one-set two-system manner is 50%, and the total spray rate of the upper and lower surfaces in the case where all discharge sprays to the upper surface/lower surface is 100%. In a state where the pipe laminar nozzles 3 for the upper surface discharge sprays as shown in
This method is characterized in that the amount of cooling water can be set only by spraying/stop of spraying of cooling water using the spray valves 7 and the control mechanism 8. Therefore, spraying/stop of spraying of cooling water can be switched using typical valves, and therefore the amount of cooling water can be set extremely easily. By increasing the opening and closing speed of the spray valves 7, the cooling water amount density can be set extremely rapidly. For example, when high-speed on-off valves called cylinder valves are used, switching is completed in an operating time of one second or less. Compared to this, when typical flow rate density control is carried out, flow control valves need to be attached. The valve opening is fine-tuned while measuring with a flow meter. Therefore, when typical flow control valves are used, a time of about 5 to 10 seconds is required depending on the diameter of pipes. When the distance between the nozzles and the steel strip is changed as in Patent Literature 1, the height needs to be regulated using a servomotor or the like, and rapid switching is difficult.
The position in the width direction of the end when cooling water sprayed from a spray nozzle collides with the steel strip is preferably located at the position of the central axis of the adjacent nozzle, but may be arranged so as to spread slightly to the opposite side of the central axis of the adjacent nozzle from the nozzle spraying cooling water. When spray is performed in a one-system manner, spray is performed alternately in one system as shown in
In addition, it is more preferable that two sets of lower surface cooling apparatuses placed between table rollers in the conveying direction be referred to as a pair, and the nozzle placement positions in the width direction be displaced by ½ of the nozzle attachment pitch in adjacent pairs as shown in
As shown in the figure, a plurality of pipe laminar nozzles 3 are arranged such that cooling water falls onto the upper surfaces of table rollers and into inter-table-roller spaces, and cooling apparatuses are arranged as spray nozzles 4 for the lower surface. The upper-surface pipe laminar nozzles 3 are each provided with a spray valve 7 (not shown) and are capable of independently performing spraying/stop of spraying of cooling water.
In the case of such arrangement, when the spray rate of cooling water is 100%, the upper surface 50% and the lower surface 50%, and therefore regulation can be performed in a four-stage manner only by spraying/stop of spraying of each header: spray rate 25% [
Although somewhat complicated, if four inter-table-roller spaces are combined doubly, eight-step regulation is possible.
The hatching in the figure shows the supply of cooling water.
An embodiment of the present invention in which the flow rate density balance between the upper and lower surfaces is changed will be described below.
Suppose that, in the cooling apparatus shown in
A case of application to cooling of the lower surface of a hot-rolled steel strip has been described. However, from the principle thereof, application to cooling of the upper surface of a hot-rolled steel strip is also possible. Of course, the cooling method of the present invention can also be applied to both the upper surface and lower surface.
Although flat spray nozzles have been described as the spray nozzles 5, elliptic or rectangular sprays may be used. On the other hand, considering overlapping of spray patterns in the case of one-system spray, the ratio of thickness to spread width of sprayed water (
Examples of the present invention will be described.
In the examples, in the hot-rolled steel strip manufacturing line of
As shown in
The detailed arrangement of lower surface nozzles will be described with reference to
The distance between the nozzles and the steel strip was 140 mm, the diameter of table rollers was 350 mm, and the spread angle of spray was 90°.
Table 2 shows the results of cooling in examples of the present invention and a comparative example.
One system of the upper surface pipe laminar 3 (one group in the width direction) and one system of the lower surface spray nozzles 5 (one group in the width direction) in
In examples 1 to 3 of the present invention, the spray system of cooling water for the upper surface was changed, and the change in cooling rate was examined.
First, in example 1 of the present invention, as shown in
Next, in example 2 of the present invention, as shown in
In example 3 of the present invention, spray for cooling the lower surface was not performed, and 164 cooling headers sprayed only to the upper surface. The cooling rate at this time was 40° C./s.
Thus, in examples 1 to 3 of the present invention, the cooling rate was able to be regulated from 40° C./s to 70° C./s. The temperature deviation in the width direction after cooling was good, about 30° C.
This confirms that, in the present invention, in the cooling after finish rolling in the hot-rolled steel strip manufacturing line, the cooling rate can be easily regulated. As a result, by using the present invention, various hot-rolled steel strips can be made. In addition, it is made possible to manufacture hot-rolled steel strips having the same strength, toughness, and the like as those of conventional ones without adding a special element.
Examples 4 and 5 of the present invention are the results of the pipe configuration of
In example 4 of the present invention, as shown in
In example 5 of the present invention, as shown in
In contrast, in the comparative example, although one system sprayed in the cooling of the lower surface as shown in
Number | Date | Country | Kind |
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2012-280418 | Dec 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/006952 | 11/27/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/103164 | 7/3/2014 | WO | A |
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Number | Date | Country | |
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20150321234 A1 | Nov 2015 | US |