KR20170073988A - Method of detecting flaw of hot-rolled steel causing hot rolling roll flaw - Google Patents

Abstract

A method of detecting a hot rolling rolled defect is disclosed. According to an embodiment of the present invention, there is provided a method of detecting a hot rolling rolled defect, comprising the steps of: photographing a surface of a plate material; analyzing the photographed image to detect defects on a surface of the plate material; and if the shape of the detected defect is a linear defect or a hook- , And the detected defect is judged as a hot rolling rolled defect.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hot rolling rolled-

More particularly, the present invention relates to a hot rolling rolled defect detection method for detecting whether a defect occurring in a plate material in a hot rolling process is a defect caused by a rolled roll defect.

Generally, the hot rolling of a stainless steel sheet is carried out in a hot rolling mill having a layout in which a heating furnace, a roughing mill stand, a finishing mill stand, a cooling stand and a winding machine are arranged in a straight line. And then subjected to primary rolling at a bar thickness of about 30 mm in a rough rolling mill stand composed of a 2Hi or 4Hi mill, and then subjected to primary rolling in a finishing rolling mill stand made of a 4Hi mill 6 to 7 stands It is common to hot rolled continuously to thickness, and after winding on a cooling stand, it is wound in coil form.

The hot-rolled stainless steel sheet coil is subjected to a hot-rolled annealing and pickling process for removing the scale of the surface, cold-rolled to a predetermined thickness by a rolling mill, cold rolled annealed or pickled and annealed, and finally shipped to a cold rolled coil.

[0002] Recently, hot rolling rolls used as working rolls in hot-rolling mills are high-speed tool steel hot-rolling rolls (high-speed rolls) having excellent wear resistance with a diameter of 600 to 800 mm from the rough rolling mill to the finishing rolling mill.

However, even in such a high-speed tool steel hot-rolled roll, the surface of the rolled roll is damaged due to the fatigue caused by the accumulation of repeated stress, resulting in defects.

Conventionally, in order to detect surface defects caused by hot rolling of stainless steel sheets, a surface defect detector (SDD) is installed at the end of the finishing mill, at the end of the hot rolling annealing process and at the end of the cold annealing pickling process or the bright annealing process .

However, it is very difficult to detect surface defects in the upper process prior to the cold rolling process for very fine surface defects of 1 to 3 mm in size, which is a problem in the final cold rolled product.

It is not easy to make a visual judgment and an SDD judgment on defects having a size of about 1 to 3 mm at the surface of the hot-rolled annealed oxide plate after the hot coils, the pickled coils obtained by removing the scales, the shot blasters and the brushes.

In the conventional surface defect inspection, for example, roll fatigue scratch detection is performed by detecting and determining only three-millimeter or more concave defects on the line, so that detection and determination of micro defects of 3 mm or less are confused with other defects such as line defects, This is difficult.

Patent Document 1 discloses a technique for improving the defect detection rate by using a photoelectric sensor in which a light source is improved.

In Patent Document 2, the camera angle adjustment is performed when the gray level difference between the defective portion and the top portion is small, and the threshold adjustment is performed when the gray level difference is large, And a technique to be performed in a short time is disclosed.

Patent Document 3 discloses a technique in which the object to be detected is limited and the periodic scratch signal processing technique of the inspection apparatus is improved.

Patent document 4 is a technique for identifying a roll causing defects by detecting a periodic defect caused by roll scratches. The surface inspection apparatus calculates defects and calculates the pitch of defects to reverse the defective hot-rolled roll .

However, it is difficult to clearly specify the hot-rolled roll that caused surface defects if the pitch between the defect group and the defect group is unclear in the existing technologies, and a method of specifying the defect roll for the rolled roll defect that is hard to find the periodicity is provided I never do that.

One. Japanese Patent Application Laid-Open No. 2005-134363 2. Japanese Patent Application No. 2010-112846 3. Japanese Patent Application Laid-Open No. 2001-281154 4. Japanese Patent Specification No. 2012-30260

An embodiment of the present invention is intended to provide a hot-rolling roll fault detection method capable of more effectively detecting a hot rolled roll defect.

Further, an embodiment of the present invention is intended to provide a hot-rolling roll fault detection method capable of more effectively detecting a hot-rolled roll having hot-rolled roll-off defects.

According to an aspect of the present invention, there is provided a method for detecting a defect on a surface of a plate material by photographing a surface of a plate material, analyzing the taken image to detect a defect on the surface of the plate material, and if the detected defect type is a linear defect or a hook- A hot rolling rolled defect detection method in which a defect is judged as a hot rolling rolled defect can be provided.

In the determination of the hot rolling roll defects, the detected defects may be clustered on one side or both sides of the edges of the plate material, and may have a shape of a linear or hooked shape with respect to the plate advancing direction, Are present symmetrically with respect to the central portion of the plate, the detected defects can be judged as the hot rolling rolled defect.

Further, in the hot rolling rolled defect judgment, if the defect groups having the above-mentioned shape have a pitch of a predetermined length, the detected defect can be judged as the hot rolling rolled defect.

It is preferable that in the determination of the hot rolling rolled defect, the detected defects are clustered at the plate central portion of the plate and have a linear or hooked shape with respect to the plate advancing direction, or there exist defect groups having the above- If the defect groups have a predetermined pitch, the detected defect can be judged as the hot rolling rolled defect.

When the detected defects are judged to be the hot rolling rolled defects, the angle of inclination of the linear defects or the hook type defects with respect to the plate advancing direction is calculated, and the calculated inclination angles are stored in advance on the stand inclination angles And determining a rolling roll of the found rolling mill stand as a rolling roll with a defect.

In addition, the photographing of defects on the surface of the plate can be performed after at least one of a hot rolling step, a hot rolling annealing pickling step and a cold rolling step.

The embodiments of the present invention accurately detect the hot rolling roll defects before the final product stage or the final product stage by investigating the occurrence pattern and development and progress of the hot rolling rolled surface defects for each process, It is possible to precisely estimate the rolled roll of the stand that is caused, and it is possible to reduce the occurrence of a large amount of surface quality defects and damage caused by undetectable defects, and to accurately detect defective hot rolled rolls.

1 is a configuration diagram of a hot rolling system to which a hot rolling rolled defect detection apparatus according to an embodiment of the present invention is applied.
2 is a view for explaining a defect of a rolling roll in an embodiment of the present invention.
3 is an example of a defect shape and a defect shape of a hot-rolled steel sheet due to a defect in a rolling roll in an embodiment of the present invention.
4 is another example of a defect shape and a defect shape of the hot-rolled steel sheet due to defects of the rolling roll in one embodiment of the present invention.
5 is a control block diagram of a hot rolling rolled defect detection apparatus according to an embodiment of the present invention.
6 is a control flowchart for a hot rolling rolled defect detection method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments to be described below are provided by way of example so that those skilled in the art can fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below, but may be embodied in other forms. In the drawings, the width, length, thickness, etc. of components are exaggerated for the sake of convenience. Like reference numerals designate like elements throughout the specification.

According to one embodiment of the present invention, the shape of the surface defects of the plate material due to the surface defects of the hot-rolling rolls is investigated for each of the hot-rolled sheet, hot-rolled annealed sheet and cold-rolled sheet by the respective processes. As a result, And that these defects appear as defects having a constant inclination different from the existing linear defects. Based on this point, it is possible to detect the defects of the plate caused by the surface defect of the hot rolling roll at an early stage, It provides a way to find out the role of a particular stand where a fault has occurred and take action.

1 is a configuration diagram of a hot rolling system to which a hot rolling rolled defect detection apparatus according to an embodiment of the present invention is applied.

Referring to FIG. 1, a hot rolling system includes a reheating furnace 10, a roughing mill 20, a finishing mill 30, a run-out table 40 And a down coiler 50, as shown in FIG.

The heating furnace 10 is a device for heating the slab, which is the material of the hot-rolled coil, to an appropriate temperature.

The rough rolling mill 20 has a function of rolling the slabs heated by the primary rolling mill in two directions with an appropriate thickness and width. The roughing mill 20 is a first thickness reduction process for making a product of a desired thickness. The slab whose thickness has been thinned in the roughing mill 20 is again fed through a finishing mill 30.

The finishing mill 30 is a device for finally rolling the plate material with a higher precision to a desired length and thickness. The hot-rolled steel sheet S having undergone this process is cooled by the cooling system 40 and then wound into a coil shape in the winder 50. The finishing mill (30), for example, arranges 6 to 7 stands continuously to secure dimensions and flatness through continuous rolling.

The hot-rolled steel sheet subjected to hot rolling is subjected to a hot-rolled annealing and pickling process for removing the scale of the surface, followed by cold rolling to a predetermined thickness by a rolling mill, followed by cold rolling, annealing, or light annealing.

Hot rolled annealing is a step of heat treatment after hot rolling, in which the internal structure of the hot rolled steel sheet is restored and the surface is washed with acid.

Cold rolling annealing is a process of recovering the internal structure change of stainless steel of cold-rolled coil caused by cold rolling and recovering it, and at the same time removing the high-temperature oxidized rust from the surface caused by heat treatment to show the original stainless steel surface.

Brass annealing is a process for obtaining a high surface gloss by annealing in an inert atmosphere for the heat treatment of stainless steel after cold rolling.

As described above, in the hot rolling of the stainless steel sheet, the surface of the hot rolled plate is defective due to the surface damage occurring in the hot rolling roll caused by the high rolling load and the repeated thermal stress in the rolling of the very rough rolling mill , A surface defects detection device (SDD) installed on the downstream side of the hot-rolled annealing and pickling process for scale removal and material control of the hot-rolled coils, can not detect defects in the hot rolling process even though the surface damage of the roll is transferred to the surface of the rolled- ) Can not detect the surface defects of the material. As a result, after the cold rolling annealing, which is a cold rolling finishing process using this material, or the surface inspection of the plate surface after the light annealing, .

In order to thoroughly identify such defects in each process inspection, it has been impossible to effectively detect fine rolling roll defects even though a surface defect inspection apparatus (SDD) is installed and operated in the initial stage or intermediate stage of each process.

The reason for this is that, first, information on the shape and characteristics of the hot-rolled rollable micro-defect is insufficient, and since the size of the defect is very small, about 1 to 3 mm, the threshold setting for defect detection is inappropriate. In the case of raising, the time required for the determination and the confusion with other defects may be caused, thereby causing problems in device operation.

Therefore, in order to quickly detect and determine fine defects, it is necessary to be able to directly detect the characteristics of defects.

In one embodiment of the present invention, such hot rolling rolled surface defects are investigated for each process, generation, development and progress of the process, so that the hot rolling roll defects can be accurately detected even before the final product stage or the final product stage, And provides a method for accurately estimating the roll of the stand that caused the defect.

Hot-rolled roll-off micro-defects are exposed to micro-defects at the stage of cold-rolling, cold-rolling, and surface defects at the end of the final product stage after the completion of hot rolling or after completion of hot- Causing a large amount of quality defects.

An embodiment of the present invention provides a roll fatigue defect detection method for minimizing mass quality defects due to the occurrence of such roll fatigue scratches and a method for accurately estimating the hot rolling rolls that cause roll fatigue defects , A method of replacing the roll or changing the grinding standard should be devised so that further roll fatigue defects do not occur.

On the other hand, there is a method of measuring the pitch between the defect groups and the defect groups in the hot-rolled annealed oxide sheet caused by the fatigue damage of the hot-rolled roll and inversely inversely rolling the corresponding roll where the roll fatigue occurs. However, when the pitch between the defect groups and the defect groups is unclear, it is difficult to estimate the hot-rolled roll causing the roll fatigue defect.

Therefore, it is possible to detect the hot rolling rolled linear fine defect from the characteristic shape investigation of the hot rolled roll fine defects found in the hot rolling process, the hot rolled annealing pickling process and the cold rolling process surface defect inspection, And measuring the angle with the axis to estimate the hot-rolled roll caused by the hot-rolled micro-defect.

In particular, the final cold-rolled stainless steel product, which is made of brass, has a beautiful surface and excellent gloss, so even small defects are very visible and if defects are found, they are difficult to become normal products. The hot-rolled sheet is a defect of a small line on the order of 2 to 3 mm which is detected in the inspection step after the defects recorded on the hot-rolled sheet by the hot-rolled roll are subjected to hot-rolled annealing, cold-annealing, pickling and bright annealing. It is a very fatal flaw because it can appear across the battlefield.

Since the defect size is very small, it is very difficult to find defects even after the hot rolling, the hot rolling annealing, the hot rolling annealing, and after the final brass annealing process.

According to an embodiment of the present invention, there is provided a method for detecting fine defects caused by such hot rolled sheet damage after hot rolling or after annealing and pickling, as well as a method for drastically reducing fatigue of a hot rolling roll.

In the event of material defects due to damage to the hot-rolled roll, coil defects that occur in the surface layer can be removed by coil grinding in the case of plate materials that are generally scratched. However, the intervention of the intermediate process for the removal of defects has a problem of causing an increase in cost.

Further, in the case of a roll causing such roll damage, sufficient grinding is required to restrict the use or to completely remove the roll fatigue layer. This also increases the roll consumption and increases the grinding time, have.

In one embodiment of the present invention, as a result of investigation of the rolling roll fine defects in the hot rolling, the scale of the material is caught in the defective portion of the formed product on the surface of the hot rolling roll, Or by pressing the surface of the concave depressed roller convexly pressed by the concave depressed roll again on the next rolling roll, the fine defects of the hot-rolled steel are subjected to a shot ball, brushing it can not be removed by brushing and cold-rolled while maintaining fine defects on the surface of hot-rolled oxide which is the base material of cold-rolled steel. The surface defects imprinted by the rolling roll fine defects are oblique due to the spread of the width in the hot rolled steel, which is distinguished from other surface defects in the hot rolled annealed steel plate which is the base material of cold rolling.

In fact, it is difficult to detect fine surface defects caused by such hot rolled roll fine defects on the surface of hot rolled coils or hot rolled annealed pickled coils due to surface defects of about 2 to 3 mm in size, to be.

FIG. 2 is a view for explaining a defect of a rolling roll in an embodiment of the present invention, FIG. 3 is an example of a defect shape and a defect shape of a hot rolled steel sheet caused by defects of a rolling roll in an embodiment of the present invention, 4 is another example of a defect shape and a defect shape of the hot-rolled steel sheet due to defects of the rolling roll in one embodiment of the present invention.

2 to 4, when a defect 61 is generated in the hot rolling roll 60 which is one of the working rolls of the roughing mill 20 or the finishing mill 30, A defect (D) due to the defect (61) generated in the hot rolling roll (60) is generated in the hot rolled sheet (S)

Defects (D) generated in the sheet material (S) due to the hot-rolling roll (60) are transferred to the hot-rolled sheet after the hot-rolling step, to the hot-rolled annealed sheet when hot annealed and pickled, Plate, and after the cold-annealing annealing process, it appears on the cold-rolled annealed sheet.

Defects (D) generated in the plate material (S) due to the hot rolling roll (60) appear in a specific shape and form, and have a constant shape and size even though they pass through each process.

Unlike the conventional line defect, such a defect (D) appears as a defect having a constant slope with respect to the plate advancing direction which is the rolling direction as shown by the arrow direction. For example, a quadruple linear defect (see FIG. 3) or a hooked quadruple linear defect (see FIG. 4).

5 is a control block diagram of a hot rolling rolled defect detection apparatus according to an embodiment of the present invention.

Referring to FIG. 5, the apparatus for detecting a hot rolling rolled defect may include a surface defect inspection unit 100, a control unit 110, a display unit 120, and a storage unit 130.

The controller 110 electrically connects the surface defect inspection unit 100 (SDD), the display unit 120, and the storage unit 130.

The surface defect inspection unit 100 includes a first surface defect inspection unit 101 (SDD1) for inspecting surface defects of the hot-rolled sheet after the hot rolling process, a second surface defect inspection unit 101 for inspecting surface defects of the hot- A third surface defect inspection section 103 (SDD3) for inspecting surface defects of the cold-rolled annealed and pickled sheet after the cold-rolled annealing and pickling process, an inspection section 102 (SDD2) 4 surface defect inspection unit 104 (SDD4).

The surface defect inspection unit 100 may include at least one surface defect inspection unit among the four surface defect inspection units.

The first to fourth surface defect inspection units 101 to 104 may include a camera for photographing the surface of the sheet material. The first to fourth surface defect inspection units 101 to 104 may include a camera for photographing the surface of the plate material after other processes in addition to the above-described processes. The first to fourth surface defect inspection units 101 to 104 may include various sensors capable of detecting defects on the surface such as a photoelectric sensor in addition to a camera.

The control unit 110 determines the defects of the hot rolling roll using the surface defect inspection result inspected by the surface defect inspection unit 100 and determines whether the defective hot rolling roll is a defective hot rolling roll in the roughing or finishing mill Determine which stands are among the various stands.

For example, the control unit 110 receives a surface image captured by the surface defect inspection unit 100, analyzes defects of the plate material by analyzing the received image, analyzes the defects of the plate material, It is judged whether or not the defect is caused by a defect in the rolling roll. If it is judged that the defect is a defect caused by a defect in the hot rolling roll, it is judged whether the defective hot rolling roll is a work roll of a rough rolling mill or a finishing mill. Then, the control unit 110 displays a result of the determination on the display unit 120 to alert the operator.

The storage unit 130 stores work roll information for each stand of the roughing mill and the finishing mill. The storage unit 130 stores angle information corresponding to the work rolls of the respective stands with respect to the line center axis of the plate material with respect to the traveling direction of the plate material due to the line defect occurring in the plate material due to the defect of the hot rolling roll.

One embodiment of the present invention is a hot rolling mill for hot rolling a stainless steel sheet at high temperature. In the hot rolling mill stand, fine surface damage of the hot rolling roll, surface damage of the hot rolling plate and fine surface defects And by taking preemptive measures, it is a measure for reducing the occurrence of a large amount of surface quality defects and the damage caused by the detection of defects.

One embodiment of the present invention relates to a surface defect inspection apparatus (hot rolling SDD) for inspecting surface defects of hot rolled coils after hot rolling, a surface defect inspection apparatus (HAPL SDD) for inspecting surface defects of hot rolled annealing pickling coils, In the surface defect inspection system of each process consisting of a surface defect inspection device (cold rolling SDD) for inspecting surface defects of pickling coils and surface defects of a brass annealing coil, Linear defects and claw-shaped linear defects are detected, the angle of defects inclined with respect to the rolling direction is calculated from the defects, the roll on which the roll fatigue occurs is firstly detected from the angle to detect the defects in the hot rolling process, In the annealing pickling process, the defect can be detected in the final tertiary inspection of the cold rolling process.

In one embodiment of the present invention, if the shape of the surface defects of the plate material due to the fine surface defects of the hot-rolling roll is oblique or hook-shaped, the defects are caused by the surface scale of the material being imposed on the fine surface defects such as the carbide drop- When the scale and the scale of the material come in contact with each other, it is possible to estimate that the scale is crushed on the roll, and the defect is generated on the surface of the base material.

The shape of the defect is oblique, and the angle of the oblique line is defined as the direction of the sum of the backward slip and the width spread.

The backward slip is calculated by the following equation (1).

- [식 1]

- [Equation 1]

는 접촉각, T는 접촉시간, 접촉장

, Δh는 두께차(h_i-h_i-1), 압연재의 후진량 l_b=F_b/h₁, 롤표면에 대한 판의 상대속도의 평균치 v_b= 2l_b/T 이다.Where R is the radius of the roll,

T is contact time, contact length

, Δh is the thickness difference (h _i -h _i-1 ), the backward displacement of the rolled material l _b = F _b / h ₁ , and the average value of the plate relative speed v _b = 2l _b / T.

The width spread (gouse) is calculated by the following [Equation 2].

Spreading amount = 0.35? H - [Equation 2]

The oblique angle tan &thetas; of the defects is calculated by the following [Equation 3].

Table 1 below shows the stand number, the roll diameter, the thickness before and after rolling, and the inclination angles of the four linear defects generated in the sheet material in one embodiment of the present invention.

Stand number Roll diameter [mm] H ₀ [mm] H ₁ [mm] Angle [°] F1 700 27 18 5 to 6 F2 700 18 12.5 4 to 5 F3 700 12.5 9 3.5 ~ 4 F4 700 9 6.7 3 ~ 3.5 F5 660 6.7 5 3 ~ 3.5 F6 660 5 3.8 2 to 3 F7 660 3.8 3 2 to 3

The surface defects of the hot-rolled steel sheet due to the fine surface defects of the hot-rolled roll leave hook-shaped or line-shaped concave marks on the surface of the material. If the size of the defect is large, it can be detected directly during hot working. However, if the size of the defect is small, the hot rolled steel sheet can be detected after annealing. If it is very small, detection can be performed after cold rolling and annealing pickling.

It is most preferable to be directly detected during hot rolling, and then the detection may be a lane after the hot-rolled annealing and pickling, which is undesirable if it is detected after cold rolling and annealing.

Therefore, it is very important to detect hot-rolled roll fine defects at least in the step of annealing the hot rolled sheet before cold rolling.

It is assumed that the hot rolled roll fine defects are generated from the pitting due to the cyclic loading of the rolling roll and gradually develop into a long concave defect on the line.

The shape of fine defects on the surface of the linear steel sheet caused by the start and development process of the rolling roll fine surface defects are in the form of hooks or hooks in the initial stage and then gradually develop and develop linearly.

Defects that divide into two bifurcations in the form of the first hook gradually increase and deepen on one side, while the other is shallow, shortened and extinguished, leaving only one side.

From these results, it is possible to prevent transfer and diffusion of steel sheet defects due to additional rolling roll micro-defects to steel sheet defects by detecting surface defects on the steel sheet due to rolling roll micro-defects prematurely.

In the hot rolling of stainless steel, surface defects transferred to the plate due to the surface damage of the operating roll appear as a cluster at a position of, for example, 100 to 300 mm at both edge portions of the plate.

6 is a control flowchart for a hot rolling rolled defect detection method according to an embodiment of the present invention.

Referring to FIG. 6, a method of detecting a hot rolling rolled defect is performed by the control unit 110. FIG.

A method for detecting a hot rolling rolled defect includes a step (200) of photographing a surface of a plate material by a process, a step (202) of detecting a defect by analyzing an image of a surface of the plate material, (204) a step 204 of determining whether the hot rolled sheet is a hot rolled roll defect due to a defect in the hot rolled roll if the hot rolled roll is a quadrilateral defect or a claw-like defect symmetrical to the center of the plate, A step 208 of warping that the hot rolled roll defect is a rolled rolled defect if it is judged to be a hot rolling rolled defect and a step 210 of calculating an oblique angle with respect to the rolling direction, A step 212 of comparing the calculated inclination angle with an inclination angle of each stand of each rolling mill stored in the storage unit 130, and a step (212) of comparing the inclination angles of the corresponding rolling mills And a step 214 to find the DE, locate the step of rolling roll determination with defects the work rolls of the stand of the rolling mill 218 may include a step 218 to alert the rolling rolls with defects.

In one embodiment of the present invention, when a four-line or claw-shaped surface defect is detected symmetrically with respect to the center of the plate in the hot-rolled sheet inspection process, the hot-rolled annealing pickling plate inspection process and the cold- rolled sheet inspection process, It is judged to be defective and the inclination angle of the defect is measured to estimate the working roll of the stand having the hot rolling roll defect among the stands of each rolling mill.

The surface defects of the steel sheet due to the surface damage of the hot-rolled roll have a periodicity depending on the diameter of the roll and the thickness of the rolled steel sheet. For example, if the roll diameter of F7 of a hot finishing mill made up of seven stands is 660 mm, defects are repeatedly repeated at a period of? D7 = 3.1415 * 660 mm = 207,3 mm.

However, in the case of F1, if the roll diameter is 700 mm, the defects are repeated in the period of πD1 = 3.1415 * 700 mm * 18/3 = 13,194 mm.

However, in the case of micro defects that are difficult to detect the period characteristic of such rolling roll defects, it has been found that the type of defects detected in the final cold rolled product as a result of the tests is a whitish linear shape and is a cluster type defect having a hook- It has been found to be defects having features that are symmetrical with respect to the center.

However, the defects observed in the final products of the cold rolled steel sheet were found to be in conformity with the defects detected in the base material of the cold rolled sheet, and the size thereof was reduced.

It was also found that the inclination angle of defects correlated with the surface defects of the rolling rolls of the hot rolling mill stand, and the defects due to scratching and breakage of the scales.

The rolling roll defects of the hot rolling start to develop from the flawed flaws due to the detachment of carbide on the surface of the rolling roll and spread in a crack shape on the line in the direction of the body of the rolling roll. The scales of the base material are caught in the damaged cracks of the roll, and when the scale attached to the surface of the base material on which the scales sandwiched by the gaps are pressed is pressed, the scales pressed or broken are pushed behind the rolls, And the broken scale is divided into two because it is less restrained toward the edge than the center side of the plate.

Defects transferred to the hot-rolled plate are changed into a form in which the defect type is almost maintained and the length is reduced in the cold rolling.

Therefore, if defects are not detected in the surface defect inspection apparatus SDD in the hot rolling step, the surface defect inspection apparatus SDD of the hot-rolling pickling step is not detected in the surface defect inspection apparatus SDD of the hot- The hot rolling roll defects are detected from the defect feature and shape in the surface defect inspection apparatus (SDD) of the final cold rolling product inspection stage, and the operating roll of the rolling stand can be estimated from the angle of defects.

The angle at which the scale is bisected is related to the down-load distribution of the finish rolling stand, so that the operating roll of the stand that caused the defect from the form transferred to the plate can be found.

Table 2 below shows the angle of slant on the SDD for each stand by the occurrence of roll fatigue flaws in the pass schedule rolling the STS304 27t bar to 3.0t.

Stand number Roll diameter [mm] H ₀ [mm] H ₁ [mm] Angle [°] F1 700 27 18.0 5.0 F2 700 18.0 12.5 5.0 F3 700 12.5 9 4.0 F4 700 9 6.7 3.5 F5 660 6.7 5.0 3.5 F6 660 5.0 3.8 3.0 F7 660 3.8 3.0 3.0

Table 3 below shows the angle of slant on the SDD for each stand by the occurrence of roll fatigue flaws in the pass schedule rolling the STS304 27 t bar to 2.7 t.

Stand number H ₀ [mm] H ₁ [mm] Angle [[°] F1 27 17.0 6.0 F2 17.0 11.5 5.5 F3 11.5 8.0 4.5 F4 8.0 5.8 4.0 F5 5.8 4.3 4.0 F6 4.3 3.3 3.5 F7 3.3 2.7 3.5

In one embodiment of the present invention, surface defects of a hot-rolled steel sheet due to micro-surface defects of a hot-rolled work roll in a hot rolling process of a stainless steel sheet and the linear fine surface defects of the cold rolled steel sheet caused thereby are detected early, By precisely locating the rolling rolls, further hot rolled roll-off defects are prevented from occurring.

[Application Example 1]

Table 4 below shows the inclination angles of fine line defects in hot-rolled SDD, HAPL SDD, and cold-rolled SDD when a hot rolled defect occurred in an F1 stand in a pass schedule of STS304 27tx 1253mm width bars rolled to a thickness of 3.0t.

Stand number F1 F2 F3 F4 F5 F6 F7 Hot rolling
SDD HAPL
SDD Cold rolling
SDD Thickness [mm] 18 12.5 9 6.7 5 3.8 3.0 Roll fatigue stand ○ × × × × × × Oblique defect inclination angle
[°] - - 5.5

○: occurrence, ×: not occurring

[Application example 2]

Table 5 below shows the inclination angles of fine line defects in hot-rolled SDD, HAPL SDD, and cold-rolled SDD when hot rolled defects occurred in the F4 stand in a pass schedule rolling STS304 27tx 1253mm wide bar to 3.0t thickness.

Stand number F1 F2 F3 F4 F5 F6 F7 Hot rolling
SDD HAPL
SDD Cold rolling
SDD Thickness [mm] 18 12.5 9 6.7 5 3.8 3.0 Roll fatigue stand × × × ○ × × × Oblique defect inclination angle
[°] - 3.5 3.5

○: occurrence, ×: not occurring

100: Surface defect inspection apparatus 110:
120: display unit 130:

Claims (6)

The surface of the sheet material is photographed,
Detecting a defect on the surface of the plate material by analyzing the photographed image,
And determining that the detected defect is a hot rolling rolled defect if the type of the detected defect is a linear defect or a hook type defect. The method according to claim 1,
In the determination of the hot rolled roll defects, the detected defects are clustered on one side or both sides of both edge portions of the plate material, and have a shape of a linear or hook-like shape with respect to the plate advancing direction, And the detected defect is determined as the hot rolling rolled defect when the hot rolled defect is present symmetrically with respect to the center portion with a width. 3. The method of claim 2,
Wherein in the hot rolling rolled defect judgment, the detected defect is judged to be the hot rolling rolled defect when the defect groups having the form have a pitch of a predetermined length. The method according to claim 1,
The detected defects are clustered at the center of the plate of the plate material and have a linear or hooked shape with respect to the plate advancing direction, or there exist defect groups having the above-mentioned shape, Wherein the detected defects are determined as the hot rolling rolled defect when the groups have a predetermined pitch. The method according to claim 1,
Wherein when the detected defects are determined as the hot rolling rolled defects, the angle of inclination of the oblique linear defect or the hook type defect with respect to the plate advancing direction is calculated, and the calculated inclination angle is compared with the stand inclination angle of each of the previously stored rolling mills And finds a mill stand on which the inclination angles coincide with each other according to the comparison result, and judges the work roll of the found rolling mill stand as a rolling roll with defects. The method according to claim 1,
Wherein the defect of the surface of the plate is photographed after at least one of a hot rolling step, a hot rolling annealing step, and a cold rolling step.

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