JP5394706B2 - How to clean hot slab cutting surface layer - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a hot slab cutting surface layer cleaning method, and in particular, to achieve hot slab cleaning without causing deterioration of the quality of the surface of the hot slab and the surface layer, while reducing wear of the cutting blade. It is what.

  The continuous casting equipment continuously manufactures slabs with a length of around 10m from molten steel and sends them to the next hot rolling line as rolling material. In this hot rolling line, the slab is usually heated in a heating furnace and then subjected to hot rolling. In this case, if the slab produced by continuous casting is charged as high as possible, preferably at a temperature of 800 ° C. or higher, into the heating furnace of the hot rolling line, the burden on the heating furnace is reduced, and the fuel is reduced. The basic unit can be reduced. Such an operation method is called direct feed rolling or direct hot charge roll (DHCR), and has been widely attempted recently.

  However, slabs have inclusion defects that occur in the casting stage. In particular, inclusion defects existing up to several millimeters below the surface of the slab are lined up on the surface of the steel sheet in the subsequent rolling or plating processes. Generate a state defect. Such inclusion defects originate from deoxidation products such as mold powder and alumina used during continuous casting, and inclusions having a size of about several hundred microns are said to cause defects.

  For this reason, slabs produced by casting equipment are conventionally either hot or cold after being cooled, and the entire surface of the slab surface is subjected to hot-cut or scarfing (scarfing). It has been common practice to perform surface grinding with a grinder.

  However, the hot scurfer is a method in which the slab surface layer is melted with high heat and scraped off while the melt is blown away, so that the slab surface layer is locally heated. As a result, the concentration of specific elements such as phosphorus (P) and nickel (Ni) in the slab surface layer portion or the decarburization of the surface layer portion is caused, which causes a problem that the surface layer quality of the slab deteriorates.

  In addition, cold scurfers that target slabs that have been sharded do not change the depth of the slab because the slab temperature does not change, and the degree of heating of the slab surface layer is small, so the concentration of the specific elements described above is unlikely to occur. However, there was a problem that energy loss due to slab cooling was severe.

  Regardless of whether the hot scurfer or cold scurfer is used, the surface of the slab surface may be roughened with a slab having a swell of about 2 mm if the entire surface of the slab is cleaned by scurfer Many. This is due to the fact that the flammable gas outlet from the nozzle of the skater is divided. Scarfers for eliminating such undulations have been developed, but it is not sufficient in terms of smoothing the surface to be welded after cleaning. This undulation is said to cause new surface defects of the hot-rolled steel sheet in the hot rolling process.

On the other hand, the maintenance by the grinder has a disadvantage that the cutting efficiency is remarkably small as compared with the scarf because the grinder's surface layer removing ability (care ability) is low. In addition, since there are missing and attached grindstones that cause surface flaws in steel products, it was only used to remove gas cutting paste at the end of the slab for hot slabs.
As described above, in the conventional general care method, there is a possibility that a defect causing a new surface flaw may occur in the skin or surface layer portion of the slab after care.

As a solution to the above problem, a slab care method for grinding the surface of a steel sheet with a cutting blade has been proposed.
As surface cutting methods of hot steel materials using a cutting blade, two methods, a shaper method (shaving) and a cutting method using a milling machine, have been proposed.
The steel material in the hot state has a lower specific cutting resistance, which is the resistance at the time of cutting, than the steel material in the cold state, and particularly at 500 ° C. or higher, it is reduced to 2/3 to 1/2 in the cold state. Thus, the hot cutting can be easily performed, and the machinability (free-cutting property) is good, so that the surface roughness of the cutting surface is also good.

The characteristics when cutting steel in a high temperature state are as follows.
(1) The cutting power decreases as the specific cutting resistance decreases.
(2) Since the cutting is performed at a high temperature, wear of the blade edge proceeds.
(3) Even if the cutting edge wear progresses, the increase of cutting power and the deterioration of cutting surface roughness are small.
(4) Regardless of the progress of cutting edge wear, chips during cutting are discharged in a red hot state, or sparks are generated during cutting.
(5) Adherents are easily attached to the cutting edge.

The features (1) to (5) described above are phenomena that are not observed in the cutting of cold material, and are inherent to the cutting of hot material. The boundary temperature at which such a phenomenon appears is not clear, but the experimental results show that the above-mentioned characteristics start to be observed when the steel surface temperature is about 400 ° C., and is particularly noticeable at 500 ° C. or higher.
Thus, in the surface cutting of the hot steel material by the cutting blade, since the high-temperature material is cut, the thermal load on the cutting edge is large, and the wear of the cutting edge is promoted compared to the cold cutting. Further, the chipping (chip) of the blade is likely to occur due to thermal shock, and the blade life becomes a problem.

Patent documents 1 and 2 are mentioned as conventional technology about cutting of such hot steel materials of high temperature.
JP 2004-181561 A Japanese Patent Laid-Open No. 9-47913

The care method described in Patent Document 1 is a method of cutting a plane with a single-blade cutting device called a shaper. In order to extend the life of the cutting blade, it has a free rotating circular cutting blade that rotates by the cutting reaction force.When the cutting blade is sent, the cutting blade rotates by the cutting reaction force, the cutting blade surface is constantly updated, and it is in one place. The heat load is not applied and the blade tip is devised to avoid wear.
Here, the rotary circular cutting blade satisfies the function only by having a rotatable structure, but a mechanism for feeding the rotary circular cutting blade along the cutting surface of the slab is separately required. In patent document 1, it is supposed that the slab drive force by the pinch roll of a continuous casting machine or the slab transfer force of the roller table for slab transfer is applied to the drive force of the cutting feed of a rotary circular cutting blade.

The removal amount of the defective portion in the slab surface layer immediately after casting is empirically about 2 to 4 mm from the skin. If the cutting reaction force when cutting the entire width of the surface on one side of the slab under a temperature condition of 4 mm thickness and 800 ° C. is estimated, it is necessary to receive a cutting reaction force of 120 to 250 tons when the slab width is 1500 mm. However, as proposed in Patent Document 1, it is difficult to obtain a driving force corresponding to such a cutting reaction force from a slab driving force by a pinch roll or a slab conveying force of a slab conveying roller table.
For example, instead of the full width of the slab, a cutting method of reciprocating multiple times with a cutting amount per blade as 100 mm is conceivable. Considering the overlap of the cutting pitch, a large number of reciprocating motions of the circular cutting blade are necessary, and the cutting time is prolonged and not realistic.

  Further, Patent Document 2 cuts hot steel with a cylindrical milling machine, and it is said that it can be dealt with by devising the peripheral speed and the hydraulic pressure sprayed onto the cutting blade, but it is very much in the cylindrical circumferential direction Since the blade is installed to cut the surface of the steel material, the cost of the blade cannot be increased.

  The present invention has been developed in view of the above circumstances, and the object thereof is not only to obtain a smooth care surface, but also to cause deterioration of the quality of the skin and surface portion of the hot slab. In addition, it provides a highly efficient cutting method for hot slabs that can remove skin and surface layer defects in hot slabs and extend the life of the blades, thereby reducing the running costs. That is.

That is, the gist configuration of the present invention is as follows.
1. After the continuous casting, the hot slab cut to a predetermined length has a surface temperature of 400 ° C. or higher, and one of the front, back and side surfaces of the slab, or one surface layer portion of two or more surfaces. When performing surface care with a milling surface cutting machine having a rotary cutting tool having a large number of cutting blades, part or all,
As the milling surface cutting device, a cutting device in which a number of driven round piece cutting tips that rotate by a cutting reaction force are arranged around a rotary cutting tool, and the circumferential shape of the cutting blade of the round piece cutting tip is used . A hot slab cutting type surface layer cleaning method, characterized in that a scraper comprising a rectangular parallelepiped fixed blade for stripping off chips adhering to the cutting edge is provided at one place .

2 . Cutting thickness, hot cutting type surface portion Caring for slabs according to claim 1, characterized in that the slab skin is 1mm or more.

3 . 2. The hot slab cutting type surface layer cleaning method according to claim 1, wherein the surface layer portion maintenance is performed after surface layer maintenance by a hot scarf or a hot grinder.

According to the present invention, the surface layer part of the hot slab is cleaned using the surface layer cutting device constituted by the rotary cutting tool, so that the surface and the surface layer and the surface layer part of all the surfaces of the hot slab, the back surface and the side surface. Slabs can be reliably removed in the hot state and can be charged into the heating furnace in the hot state without cooling the slab to a cold piece. Heat can be used effectively.
In addition, the care method according to the present invention significantly improves the smoothness of the skin surface of the slab after the care compared with the conventional care method. The resulting wrinkles on the steel sheet surface can be reliably reduced, and energy saving and quality improvement of the steel sheet can be achieved.

  In addition, with conventional slab surface cleaning, which is used to clean the entire surface of the slab surface, the layer scraped off by the slab becomes complete iron oxide and can be reused as an iron source. However, in the maintenance method of the present invention, the chips generated by the cutting of the surface layer have the iron oxide content. Since it is recovered as a small amount of metal, no reductant or thermal energy associated with the reduction is required when it is reused as an iron source, and the manufacturing cost can be reduced compared to the conventional case.

  Furthermore, when hot charge rolling is performed on a slab that has been subjected to surface layer care by the care method according to the present invention, there is no unevenness of the care surface and the surface roughness is good, so that it is hot in the heating furnace as a hot charge. Since the scale of the surface scale produced when charged is uniform and the peelability is good, the descaling effect in the hot rolling line is further improved, and a hot rolled steel material with extremely few surface defects is obtained. be able to.

Furthermore, since it is based on a general-purpose large portal machine tool, not only is the equipment cost low, but it can also be combined with existing equipment lines, for example, hot scarf (welding) care. By further caring for the subsequent surface according to the present invention, the quality of the surface of the conventional scarf can be further improved.
In addition, the cutting blade life when cutting high-temperature materials can be extended, so the number of cutting tip replacements can be reduced, running costs can be reduced, and high-temperature (hot) slab surfaces can be milled. It is an industrially available technique to be performed by cutting and cleaning.

Hereinafter, the present invention will be specifically described with reference to the drawings.
FIG. 1 shows the flow of the slab from the continuous casting line to the heating furnace of the hot rolling line in the present invention.
FIG. 2 shows the flow of a conventional slab. As shown in FIG. 2, conventionally, when the slab surface is maintained in a hot state, it has been performed by hot scarfer or grinder grinding. However, it is difficult to obtain good slab surface properties by such a method. Is as described above. Therefore, in order to obtain a good slab surface, after cooling to cold, care was taken and sent to the next hot rolling line.

On the other hand, in this invention, as shown in FIG. 1, after cutting out the slab manufactured by the continuous casting line to predetermined length, it is a heating furnace of the hot rolling line of the next process with a hot state. Transport to. If it is determined that the slab needs to be cleaned during the transfer process, the surface of the slab in the hot state at an appropriate place such as on the transfer roller table or a dedicated surface layer maintenance area, At least a defective portion on the back surface and the side surface is cut in an as-cast state using a surface layer cutting device composed of a rotary cutting tool having a large number of cutting blades that are rotated by the driving force of an electric motor.
In the present invention, as in the prior art, surface care according to the present invention may be performed after cleaning by hot scurfer or grinder grinding.

Next, FIG. 3 shows an overall view of the rotary cutting tool of the milling surface cutting apparatus according to the present invention, and FIG. In the figure, reference numeral 1 denotes the entire rotary cutting tool, and 2 is a circular piece cutting tip attached on the circumference of the rotary cutting tool 1.
As shown in FIG. 4, all the cutting blades attached around the rotary cutting tool (cutter body) 1 are all round cutting tips 2, and the cylindrical edge of each cutting tip is an all-round cutting blade. . This round piece cutting piece chip 2 is attached to a rotating shaft incorporated on the circumference of the cutter body 1, and this rotating shaft is not provided with a drive system. The round piece tip 2 and the round piece tip rotating shaft are attached to the cutter body 1 at an angle such that the round piece tip rolls by the cutting reaction force with respect to the cutting surface as shown in FIG. . Therefore, although the cutter body 1 is forcibly rotated by the drive system of the machine tool spindle, the round chip 2 attached on the circumference of the cutter body 1 is rotated according to the rotation of the cutter body 1 by the cutting reaction force. That is, driven rotation (hereinafter referred to as free rotation) is performed. Thus, by attaching the round piece tip 2 to the cutter body 1 so as to be driven to rotate by the cutting reaction force, the blade of the round piece tip 2 has a negative rake angle with respect to the cutting surface. In order to rotate the cutting tip more smoothly, it is preferable that the spindle has sufficient rotational slidability.

  In the present invention, the cutter body is rotated at a high speed, generally at a peripheral speed of 200 m / min or more, and the cutting tip is in contact with the hot work material or close to it. Since the time is short, the problem of heat transfer and radiant heat from the high-temperature work material to the chip is not large.

  As described above, in the present invention, unlike the case of the fixed blade, the cutting blade tip can be constantly updated by freely rotating the circular piece tip, so that the thermal load from the hot hot work material is reduced. As a result, it is possible to greatly reduce cutting edge wear, which is likely to be accelerated at high temperatures.

  Here, from the viewpoint of heat resistance and wear resistance, it is preferable to use a round piece chip having a hardness of HRA of 50 or more, preferably 90 or more. Such materials include CBN, super steel. Chips made of an alloy, super heat-resistant alloy and ceramic, and those having a special coating on the chip surface can be mentioned.

In the following, preferred conditions for smoothly rotating the round piece insert in accordance with the present invention by the cutting reaction force will be described.
-Peripheral speed of rotary cutting tool: 200-3000 mpm (preferably 1000-3000 mpm)
・ Rotational cutting tool forward speed: ~ 10 mpm
・ Circle piece diameter: 15 to 25 mm
・ Circle piece feed: 0.2 to 1.0 mm
・ Number of round chip inserts: 8-14 / (periphery of rotary cutting tool: per 250-300mm)

In addition, when the work material is cut at a high temperature according to the present invention, a part of the cutting waste may adhere to the vicinity of the cutting edge of the round piece cutting tip, and this countermeasure needs to be sufficient.
To solve this problem, as shown in FIG. 5, mount the scraper 3 to remove deposits of debris cut circumferentially one place of the cutting edges of the circular piece cutting tip 2. As such a scraper 3, a rectangular parallelepiped fixed blade made of a heat-resistant alloy having high hardness is useful. By installing such a scraper 3, it is possible to prevent chip 4 from adhering to the cutting edge, which is a concern during hot cutting. It can be effectively peeled off by the rotation of the round piece cutting tip 2.

  Further, in addition to the free-rotating round piece chip mounted on the circumference of the cutter body in the present invention, it is possible to combine a wiper fixed chip for the purpose of improving the surface roughness.

It is the flowchart which showed the flow of the slab from the continuous casting line to the heating furnace of a hot rolling line in this invention. It is the figure which showed the flow of the slab from the conventional continuous casting line to the heating furnace of a hot rolling line. 1 is an overall view of a rotary cutting tool of a milling surface layer cutting device according to the present invention. It is a principal part detail drawing of FIG. It is the figure which showed the peeling condition of the scraps by a scraper.

Explanation of symbols

1 Rotary cutting tool (cutter body)
2 Round piece cutting tip 3 Scraper 4 Chip

Claims (3)

After the continuous casting, the hot slab cut to a predetermined length has a surface temperature of 400 ° C. or higher, and one of the front, back and side surfaces of the slab, or one surface layer portion of two or more surfaces. When performing surface care with a milling surface cutting machine having a rotary cutting tool having a large number of cutting blades, part or all,
As the milling surface cutting device, a cutting device in which a number of driven round piece cutting tips that rotate by a cutting reaction force are arranged around a rotary cutting tool, and the circumferential shape of the cutting blade of the round piece cutting tip is used . A hot slab cutting type surface layer cleaning method, characterized in that a scraper comprising a rectangular parallelepiped fixed blade for stripping off chips adhering to the cutting edge is provided at one place . The cutting thickness of the hot slab according to claim 1, wherein the cutting thickness is 1 mm or more from the slab skin. The method for cleaning a hot slab according to claim 1, wherein the surface layer is cleaned after the surface layer is cleaned with a hot scarf or a hot grinder.

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