JP2016002582A - Chatter mark prevention method of steel plate - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a chatter mark prevention method of a steel plate capable of efficiently preventing a chatter mark generated in a low strength steel plate on the outlet side of a cold rolling mill.SOLUTION: Rolling mill outlet side tension T/A is adjusted so that a frequency (f) of string vibration of a steel plate slips out of a natural frequency F of a rolling mill on the basis of the relationship between the rolling mill outlet side tension T/A per unit cross-sectional area and the frequency (f) of the string vibration of the steel plate, and vibration of the rolling mill outlet side steel plate is restrained thereby, and a roll diameter R of a small diameter roll is properly set so that a steel plate surface is not plastically deformed by the small diameter roll of becoming one fulcrum of the string vibration of the steel plate, and flexural strain ε of the steel plate surface is managed thereby so as to become an elastic limit or less.

Description

  The present invention relates to a method for preventing marks (chatter marks) generated on a steel sheet by chattering.

  In steel plate processing equipment such as cold rolling mills and tension levelers, it is known that marks in the width direction (chatter marks) are generated on the steel sheet surface due to abnormal vibrations (chattering). Various proposals have been made as countermeasures for deterrence.

  For example, in patent document 1, the damper which reduces the vibration of a horizontal direction is installed in the work roll chock or backup roll chock of a cold rolling mill, and the vibration of a cold rolling mill is reduced.

  Further, in Patent Document 2, immediately after the tension leveler, a support roll and a guide for guiding the support roll in parallel with the pass line of the steel plate are provided, and the position of the support roll is changed along the guide by the air cylinder device. Thus, the method of suppressing the resonance of the steel sheet by changing the frequency of the string vibration of the steel sheet is employed.

JP 2001-137915 A JP-A-8-66724

  On the other hand, when the present inventor investigated the chatter marks generated in a cold rolling mill (hereinafter, also simply referred to as “rolling mill”), the yield strength after hot rolling and pickling was determined. It has been noticed that a low-strength steel sheet having a thickness of 450 MPa or less often has a striped pattern (chatter mark) on the steel sheet surface.

  Therefore, as a result of studying the cause of the occurrence, as shown in FIG. 1, (1) the rolling mill (final stand) 1 vibrates at the natural frequency (natural vibration), and (2) rolling When the string frequency of the steel plate 3 between the machine (final stand) 1 and the small diameter roll (for example, deflector roll) 2 coincides, the string vibration of the steel plate 3 is generated by resonance, and (3) the steel plate 3 has a string vibration frequency. It was determined that a low-strength steel plate having a yield strength of 450 MPa or less that was subjected to repeated bending according to the present invention caused plastic deformation on the surface of the steel plate, resulting in a striped pattern (chatter mark).

  In order to prevent the occurrence of such chatter marks, even if the natural vibration of the rolling mill can be reduced when the method of Patent Document 1 is applied, the natural frequency of the rolling mill and the steel sheet on the delivery side of the rolling mill can be reduced. If the frequency of the string vibration becomes equal, vibration propagates and chatter marks are generated.

  Further, even if the method of Patent Document 2 is applied to a cold rolling mill, a large number of small diameter rolls such as deflector rolls and pass line rolls are arranged between the rolling mill exit side and the tension reel or carousel reel. It is difficult to install a new device (support roll, guide, air cylinder device).

  The present invention has been made in view of the circumstances as described above, and provides a method for preventing chatter marks on a steel sheet that can efficiently prevent chatter marks generated on a low-strength steel sheet on the exit side of a cold rolling mill. It is intended to provide.

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

[1] When cold rolling a steel sheet having a yield strength of 450 MPa or less after hot rolling and pickling, the natural frequency of the cold rolling mill and the cold rolling shown in the following formula (1) The chord length between the final stand of the machine and the small diameter roll that first contacts the steel plate at the cold rolling mill exit side is made not to coincide with the frequency f of the string vibration of the steel plate. A method for preventing chatter marks on a steel sheet, wherein the bending strain ε produced on the steel sheet surface is less than or equal to the elastic limit.
f = (n / 2L) ((T / A) / ρ) ^1/2 Formula (1)
Where n is the order of the vibration mode
L: Steel string length
T: Cold roll exit tension applied to the steel sheet
A: Cross-sectional area of steel sheet (plate thickness x plate width)
ρ: Steel sheet density ε = t / 2R (2)
Where t: plate thickness of the steel plate
R: radius of the small diameter roll that first contacts the steel sheet at the cold rolling mill exit side [2] By adjusting the cold rolling mill exit tension applied to the steel sheet, the natural frequency of the cold rolling mill and the steel sheet The method for preventing chatter marks on a steel sheet according to the above [1], wherein the frequency f of the string vibration is not matched.

  According to the present invention, chatter marks generated on a low-strength steel plate on the exit side of the cold rolling mill can be efficiently prevented.

It is a figure which shows the generation | occurrence | production mechanism of a striped pattern (chatter mark). It is the schematic of the cold rolling line in the Example of this invention. It is a figure which shows the natural vibration mode of the last stand (# 4std) in the Example of this invention. It is a figure which shows the vibration mode of the steel plate string vibration in the Example of this invention. It is a figure which shows the relationship between the tension | tensile_strength change and the string vibration frequency in the Example of this invention.

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

  In normal cold rolling operations, the tension on the exit side of the rolling mill is within the range where the winding shape after winding on the coil is appropriate, and the operator sets the tension per unit cross-sectional area arbitrarily. As described above, when the string vibration frequency of the steel plate under the set tension becomes equal to the natural frequency of the rolling mill (final stand), resonance between the rolling mill and the steel plate on the delivery side of the rolling mill occurs, By repeated bending, in a low-strength steel plate (yield strength 450 MPa or less), plastic deformation occurs on the steel plate surface, and a striped pattern (chatter mark) is generated.

  Therefore, in one embodiment of the present invention, based on the relationship between the rolling mill exit side tension T / A per unit cross-sectional area and the frequency f of the string vibration of the steel sheet, shown in the following formula (1), The rolling mill exit side tension T / A is intentionally set from the resonance point (point where f = F) so that the frequency f of the string vibration deviates from the natural frequency F of the rolling mill (final stand) (f ≠ F). Ascending or descending suppresses the vibration of the steel sheet on the exit side of the rolling mill and uses a small diameter roll (small diameter roll that first contacts the steel sheet on the cold rolling mill exit side) as one fulcrum of the string vibration of the steel sheet. By appropriately setting the roll diameter R of the small-diameter roll so that the surface is not plastically deformed, the bending strain ε of the steel sheet surface obtained by the following formula (2) is managed to be below the elastic limit.

f = (n / 2L) ((T / A) / ρ) ^1/2 Formula (1)
Where n is the order of the vibration mode
L: Steel string length
T: Cold roll exit tension applied to the steel sheet
A: Cross-sectional area of steel sheet (plate thickness x plate width)
ρ: Steel sheet density ε = t / 2R (2)
Where t: plate thickness of the steel plate
R: radius of a small diameter roll that first contacts the steel plate at the cold rolling mill exit

  Note that the natural frequency F of the rolling mill (final stand) may be obtained in advance by actual measurement or numerical calculation.

Further, as described above, the bending strain ε generated on the steel sheet surface needs to be less than the elastic limit. For example, in the case of a mild steel sheet having a tensile strength of 270 MPa or more, the yield strength is 230 MPa. The bending strain ε needs to be 1.5 × 10 ⁻³ or less.

  In this way, in one embodiment of the present invention, a new apparatus as in Patent Document 2 is provided for the striped pattern (chatter mark) generated on the low-strength steel plate on the exit side of the cold rolling mill. And can be efficiently prevented.

  In this embodiment, the frequency f of the string vibration of the steel sheet is changed by adjusting the rolling mill exit side tension T / A. In some cases, the position of the small diameter roll is adjusted to adjust the string of the steel sheet. By adjusting the length L, it is possible to change the frequency f of the string vibration of the steel plate or to combine both.

  As an example of the present invention, a case where cold rolling of a low-strength steel sheet is specifically performed based on the above-described embodiment of the present invention will be described.

  FIG. 2 shows the cold rolling line used in this example, and is a schematic diagram of the line from the cold rolling mill to the tension reel.

  As shown in FIG. 2, here, # 4std (# 4 stand) corresponds to the rolling mill (final stand) 1 in FIG. 1, and the exit deflector roll corresponds to the small diameter roll 2 in FIG.

  Table 1 shows the natural frequency F of each vibration mode of # 4std, and FIG. 3 schematically shows the vibration behavior of the rolls (backup roll BUR, intermediate roll IMR, work roll WR) in each vibration mode of # 4std. Indicate.

  Table 2 shows conditions on the steel plate side, and FIG. 4 shows each vibration mode of string vibration of the steel plate.

Under the conditions as described above, the frequency f of the string vibration in each vibration mode (n = 1 to 6) of the steel sheet was calculated using the equation (1). The rolling mill exit side tension T / A per unit cross-sectional area was changed in the range of 4.0 to 9.0 kgf / mm ² .

  FIG. 5 plots the frequency f of the string vibration of the steel plate calculated as described above, and there is a primary natural frequency (128 Hz) and a secondary natural frequency as the natural frequency F of # 4std. (179 Hz).

As a result, as shown in FIG. 5, at the resonance point where the frequency f of the string vibration matches the natural frequency F of # 4std, the rolling mill exit side tension T / A per unit cross-sectional area is 4.9 kgf / mm ^2. , 7.0 kgf ^/ mm 2, is when the 7.7kgf / mm ^2, by removing these resonance points, it is possible to prevent the resonance of the # 4Std exit side of the steel plate.

  However, the following restrictions occur in actual operation.

(Constraint 1) Lower limit value of tension If the tension at the rolling mill exit side is excessively lowered, the coil inner periphery called “bamboo shoot” may occur due to insufficient coil winding tension. From past results, there is a concern that "bamboo shoots" may occur when the rolling mill exit side tension T / A per unit cross-sectional area is less than 4.5 kgf / mm ² .

(Constraint 2) Upper limit of tension When the tension at the rolling mill exit side is excessively increased, when the coil is pulled out of the reel, the inner diameter of the coil may be crushed due to buckling of the steel plate at the innermost periphery of the coil. is there. From past results, there is a concern that the “kink phenomenon” may occur when the rolling mill exit side tension T / A per unit cross-sectional area exceeds 8.0 kgf / mm ² .

(Constraint 3) Tension fluctuation In actual operation, even if the tension is set to a certain value, a tension fluctuation of about ± 10% of the set tension occurs due to various factors such as material fluctuation, plate thickness fluctuation, roll eccentricity and the like.

Therefore, in consideration of the above constraints 1 to 3, here, as shown in FIG. 5, the rolling mill exit side tension T / A per unit cross-sectional area is 5.4 to 6.3 kgf / s as a stable operation possible region. The range is set to mm ² .

  Thereby, the vibration of the steel plate on the exit side of the rolling mill can be stably suppressed.

On the other hand, as shown in Table 2, the bending strain ε of the steel sheet surface is 0.9 mm, and the radius R of the exit deflector roll is 300 mm. Therefore, from the above equation (2), ε = 1.5 × 10 ⁻³ .

As shown in Table 2, since the yield strength of the steel sheet is 230 MPa, the bending strain ε = 1.5 × 10 ⁻³ is below the elastic limit, and there is no possibility of plastic deformation on the steel sheet surface.

  Thus, in this embodiment, the striped pattern (chatter mark) generated on the low-strength steel plate on the rolling mill exit side (# 4std exit side) can be accurately prevented.

1 Cold rolling mill (final stand)
2 Small diameter roll 3 Steel plate

Claims (2)

When cold rolling a steel sheet having a yield strength of 450 MPa or less after hot rolling and pickling, the natural frequency of the cold rolling mill and the final rolling mill shown in the following formula (1) are shown. The chord length between the stand and the small diameter roll that first contacts the steel plate at the cold rolling mill exit side is made to not coincide with the string vibration frequency f of the steel plate, and is shown in the following formula (2). A method for preventing chatter marks on a steel sheet, wherein the bending strain ε generated on the surface of the steel sheet is less than the elastic limit.
f = (n / 2L) ((T / A) / ρ) ^1/2 Formula (1)
Where n is the order of the vibration mode
L: Steel string length
T: Cold roll exit tension applied to the steel sheet
A: Cross-sectional area of steel sheet (plate thickness x plate width)
ρ: Steel sheet density ε = t / 2R (2)
Where t: plate thickness of the steel plate
R: radius of a small diameter roll that first contacts the steel plate at the cold rolling mill exit   The natural frequency of the cold rolling mill and the frequency f of the string vibration of the steel plate do not coincide with each other by adjusting the cold rolling mill exit tension applied to the steel plate. To prevent chatter marks on steel sheets.

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