KR100417518B1 - Method of intermesh setting of tension leveller for strip using transverse bow measurement system - Google Patents

Abstract

The present invention is a method for removing the C bending, which is one of several defects that occur in the steel sheet, a constant tension according to the conditions of the steel sheet to prevent the work environment is changed by the error between individuals caused by the alternation of several workers The purpose of the present invention is to provide a method for fine-tuning the tension leveler by selecting the value of the fine tuning coefficient of the leveler.

The fine adjustment method of the tension leveler according to the present invention receives the conditions of the steel sheet 3 and finely adjusts each roll (12, 14, 16, 18) accommodated in the tension leveler 10 according to the bending degree of the steel sheet (3) In the method, the step of measuring the degree of bending of the steel sheet 3 with the semi-curve measuring device 20, the tension of the fine adjustment coefficient arbitrarily depending on the degree of bending of the steel sheet 3 and the conditions of the input steel sheet (3) After applying to the leveler 10, the steel sheet is passed through the tension leveler 10 and leveled, and then the shape of the steel sheet is observed, and the conditions of the steel sheet 3 having a good shape among the observed steel sheets 3 and a semi-curve measuring device ( The degree of bending measured in 20) and the fine adjustment coefficient of the tension leveler 10 applied to the steel sheet 3 are informed, and the steel sheet having the same bending degree as the condition of the informed steel sheet 3 enters the tension leveler 10. When the fine adjustment coefficient of the information tension leveler 10 is retrieved and applied to the tension leveler 10 The.

Description

Method of intermesh setting of tension leveller for strip using transverse bow measurement system}

The present invention relates to a method for selecting fine adjustment coefficient values of a tension leveler by using a device for measuring C bending, which is one of defects occurring in steel sheets, and in particular, the conditions and fine adjustment coefficient values of various kinds of steel sheets are qualified. After selecting the optimum fine tuning coefficient value by testing, it is a method to fine tune the tension leveler with this fine tuning coefficient to remove the bending of the steel sheet.

In general, if the shape of the steel sheet is not properly corrected, the product quality of the steel sheet is lowered, thereby lowering the selling price.

Among various factors that lower the quality of the steel sheet, there are C bends in the width direction and L bends in the longitudinal direction. These C and L bends are generated through various processes of steel sheet processing, and these C and L bends are removed through a tension leveler.

1 is a schematic view showing a number of rolls constituting the tension leveler, Figure 2 is a schematic diagram showing the process of the steel sheet in a state where the fine adjustment coefficient is given to the various rolls of the tension leveler shown in FIG.

As shown in FIGS. 1 and 2, the first extension roll 12 is positioned at the inlet side of the tension leveler 10, and the second extension roll 14 is located behind the tension leveler 10. The first anti-cambering roll 16 is located at the rear of the second extension roll 14, and the second anti-cambering roll 18 is located at the rear of the first anti-cambering roll 16. This is located.

Of each of these rolls 12, 14, 16, 18, the first and second extension rolls 12, 14 draw the steel sheet 3, and the first anti-camber roll 16 carries the steel sheet 3. The C bend formed in the straightening, and the second anti-camber roll 18 straightens the L bending formed in the steel sheet (3). However, moving the first anti-camburing roll 16 to correct the C-bending may cause the C-bending to transition to L-bending.

In order to calibrate the shape of the steel sheet 3 with the tension leveler 10, the operator generally recognizes the shape of the bending of the steel sheet 3 that is currently in progress, and each of the rolls 12 and 14 of the tension leveler 10. , 16 and 18 are changed to correct the shape of the steel sheet 3.

The fine adjustment coefficients of the rolls 12, 14, 16, and 18 accommodated in the tension leveler 10 are represented by I ₁ , I ₂ , I ₃ , and I ₄ , respectively, as shown in FIG. 2. Ranges from 0 to 30. In general, among the four rolls 12, 14, 16, and 18 of the tension leveler 10, the fine adjustment coefficients I ₃ and I ₄ which are mainly included in the first and second anti-camber rolls 16 and 18 are determined. The leveling operation is performed while varying, where I ₃ is the fine adjustment coefficient of the first anti-cambering roll 16 and I ₄ is the fine adjustment coefficient of the second anti-cambering roll 18.

On the other hand, in order to apply these fine tuning coefficients, the conditions of the steel sheet 3 must be known in advance. to be. The information regarding the condition of the steel sheet 3 and the shape of the steel sheet 3 currently in progress are added to the first and second extension rolls 12 and 14 and the first and second anti-camber rolls 16 and 18. The fine tuning coefficients of I ₁ , I ₂ , I ₃ and I ₄ are determined.

When the fine adjustment coefficient of each of these rolls 12, 14, 16, and 18 is determined, the fine adjustment coefficient determined in the operation computer is input, and each of the rolls 12, 14, and 12 of the tension leveler 10 according to the input fine adjustment coefficient. 16, 18) are adjusted.

However, the shape of the steel sheet 3 that determines these fine adjustment coefficients is measured by the operator's neck. Therefore, even if the shape of the same steel sheet 3, the fine adjustment coefficient is variously set according to the operator's neck measurement result, so that each roll 12, 14, of the tension leveler 10 controlling the shape of the steel sheet 3, There is a problem that the fine tuning coefficients of 16 and 18 also vary.

The present invention is provided to solve the problems of the prior art as described above, by selecting the characteristics of the various types of steel sheet and the fine tuning coefficient value test the optimal fine tuning coefficient, and set without the arbitrary judgment of several operators It is an object of the present invention to provide a fine adjustment method of a tension leveler that allows the shape correction of the steel sheet to be performed at an optimum fine adjustment coefficient value according to the condition and shape of the steel sheet.

1 is a schematic view showing the various rolls constituting the tension leveler,

FIG. 2 is a schematic diagram illustrating a process of the steel sheet in a state in which fine adjustment coefficients are given to various rolls of the tension leveler illustrated in FIG. 1;

3 is a schematic diagram showing a semi-curve measuring device, a control unit, and an operation computer for selecting a fine adjustment coefficient of a tension leveler according to an embodiment of the present invention;

Figure 4 is a schematic diagram showing the halftone measuring device shown in Figure 3,

FIG. 5 is a schematic view showing an operation relationship of the halftone measuring apparatus shown in FIG. 4.

♠ Explanation of symbols on the main parts of the drawing ♠

3: steel sheet 10: tension leveler

12: 1st extension roll 14: 2nd extension roll

16: 1st anti-cambering roll 18: 2nd anti-cambering roll

20: width measuring apparatus 23a, 23b: rail

27a, 27b: 1st, 2nd rotation motor 30a, 30b: laser rangefinder

50: control unit 60: signal processing device

According to the present invention for achieving the object as described above, fine adjustment of each roll accommodated in the tension leveler according to the degree of bending formed in the steel sheet by inputting the conditions such as the width and thickness of the steel sheet and the steel type, elongation and quality In the fine adjustment method of the tension leveler to apply the coefficient, the step of measuring the degree of bending formed in the steel sheet with a semi-curve measuring device, and the arbitrary fine adjustment coefficient according to the degree of bending of the steel sheet and the conditions of the input steel sheet Observing the shape of the steel sheet after leveling by passing the steel sheet through the tension leveler after applying it to the tension leveler, conditions of the steel sheet having a good shape among the observed steel sheets, the degree of curvature measured by the semi-curve measuring device, and And informing the fine adjustment coefficient of the tension leveler applied to the steel sheet, and the condition of the information steel sheet. When the steel sheet having the same degree of curvature enters the tension leveler, there is provided a method of finely adjusting the tension leveler, including searching for the fine adjustment coefficient of the informed tension leveler and applying the same to the tension leveler.

The half-measurement device is installed in the lower portion of the steel sheet so that the plurality of laser rangefinder is movable up and down on the same line to measure the distance from the bottom surface of the steel sheet, the plurality of laser rangefinders installed on both ends of the plurality of laser rangefinders It is provided so as to be movable to the fine adjustment method of the tension leveler to measure the measurement of the bend formed in the width direction of the steel sheet by moving the plurality of laser rangefinders on the left and right sides according to the width of the steel sheet.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a fine adjustment method of the tension leveler using a semi-curve measuring device for measuring the semi-curve of the steel sheet according to the present invention.

3 is a schematic diagram showing a half-curve measuring device, a control unit and an operation computer for selecting a fine adjustment coefficient of a tension leveler according to an embodiment of the present invention, and FIG. 4 is a half-curve measuring device shown in FIG. 5 is a schematic view showing an operation relationship of the halftone measuring apparatus shown in FIG.

3 to 5, a device for screening the fine adjustment coefficient of the tension leveler is a semi-curve measuring device 20 for measuring the shape of the steel sheet (3) to advance the front of the tension leveler (10) And a signal processing device 60 that receives and stores the measured information in the half-curve measuring device 20, and the half-curve measuring device 20 corresponds to a change in the width of the steel sheet 3 in a continuous process. The control unit 50 is installed, the control unit 50 is connected to the signal processing device 60 to send and receive information, the operation computer 70 from the signal processing device 60 to the signal processing device 60 of the Information about the condition is entered.

On the other hand, the semi-curve measuring device 20 is installed in front of the tension leveler 10, and passes through the upper portion of the semi-curve measuring device 20 before the steel sheet 3 enters the tension leveler 10. At this time, the halftone measuring apparatus 20 measures the halftone of the steel plate 3 from the bottom surface of the steel plate 3.

In this half-curve measuring device 20, a plurality of laser rangefinders 30a and 30b capable of measuring up to 0.01 mm are installed in a straight line on the upper surface of the first upper plate 21a, each of which is located at both ends of the first upper plate 21a. Laser rangefinders 30b measure edge portions of the steel sheet 3, and three laser rangefinders 30a in the middle portion of the first top plate 21a measure the intermediate portions of the steel sheet 3 to produce a steel sheet 3. Measure the bending degree in the width direction of the This first top plate 21a is provided in the vertical direction of the traveling direction of the steel plate 3, and thus, a plurality of laser rangefinders 30a and 30b are provided to face the bottom surface of the steel plate 3.

In addition, four rails 23a are installed on the bottom surface of the first upper plate 21a, that is, on the opposite surface on which the plurality of laser rangefinders 30a and 30b are installed, and the transfer screw 25a is fastened. The rotary motor 27a is fixed to the end of the feed screw 25a. The first top plate 21a slides up and down along four rails 23a provided to face the bottom surface of the steel plate 3. Then, the transfer screw 25a is rotated by the rotation of the rotary motor 27a, and the first top plate 21a screwed with the transfer screw 25a is along the rail 23a by the rotation of the rotary motor 27a. It moves up and down toward the bottom surface of the steel plate 3.

And, among the plurality of laser rangefinders 30a and 30b, each of the two laser rangefinders 30b at both ends is provided on the upper surface of the second upper plate 21b. In addition, two rails 23b and a second conveying screw 25b provided in the longitudinal direction of the first upper plate 21a and the second conveying screw 25b are installed on the bottom surface of the second upper plate 21b. The second rotary motor 27b is fixed thereto. Therefore, the second top plate 21b slides along the rail 23b in the longitudinal direction of the first top plate 21a, that is, in the width direction of the steel plate 3, by the rotation of the second rotary motor 27b.

Therefore, as shown in FIG. 4, the plurality of laser rangefinders 30a and 30b move up and down toward the bottom of the steel plate 3 by the rotation of the first rotary motor 27a, and the plurality of laser rangefinders 30a. , Respectively, the two laser rangefinders 30b at both ends are moved in the width direction of the steel plate 3 by the rotation of the second rotary motor 27b. Therefore, the three laser rangefinders 30a in the middle of the plurality of laser rangefinders 30a and 30b measure the distance from the center of the steel sheet 3, and each of the two laser rangefinders 30b at both ends is the steel plate 3. The distance from the edge part is measured by the laser beam 31 to determine whether the steel sheet 3 is bent in the width direction.

On the other hand, the signal processing device 60 has received the information of the steel sheet 3 that is already measuring the semicircle from the operation computer 70, and the output signals output from the plurality of laser rangefinders 30a and 30b are controlled. 50 is input to the signal processing device 60 and stored again. The signal processing device 60 has an A / D exchanger to convert these multiple analog signals into digital signals.

When the steel sheet passing through the semi-curve measuring device 20 (hereinafter referred to as a 'preceding steel sheet') proceeds, and a steel sheet welded to the rear end of the preceding steel sheet (hereinafter referred to as a 'lagging steel sheet') is about to enter The information regarding the condition of the following steel sheet already input from the operation computer 70 is input to the controller 50 via the signal processing device 60, and the controller 50 controls the first, The second rotary motors 27a and 27b are rotated forward or reverse to adjust the positions of the two laser rangefinders 30b at both ends of the plurality of laser rangefinders 30a and 30b according to the width of the trailing steel sheet. The half curve in the width direction is measured.

Thus, the fine adjustment coefficient of the tension leveler 10 is set according to the conditions of the steel plate 3 input from the operating computer 70, and the shape of the measured steel plate 3. As shown in FIG.

In the same manner as described above, while leveling hundreds of thousands of steel sheets, the condition of each steel sheet 3, the shape of the steel sheets, and the corresponding fine adjustment coefficient values are stored in the signal processing apparatus 60. Then, according to the conditions of the hundreds and thousands of kinds of steel sheet (3) and the shape of the steel sheet (3) by applying an arbitrary fine adjustment coefficient to the tension leveler 10, as a result of the leveling operation, the shape of the leveled steel sheet is constant Only the good case above the level is selected to inform the condition of the steel sheet 3 and the shape of the steel sheet and the fine adjustment coefficient set accordingly before being leveled. One such example is shown in Table 1.

In Table 1, fine adjustment coefficients applied to the rolls 12, 14, 16, and 18 of the tension leveler 10 according to the steel type, thickness, elongation, and shape of the steel sheet 3 were derived. The numbers in braces ({}) in Table 1 relate to the fine tuning coefficients I ₂ , I ₃ and I ₄ , where I ₁ is not shown because it is constant as 6.

On the other hand, when the conditions and fine adjustment coefficients of the several hundreds of thousands of steel sheets 3 are informed by the signal processing apparatus 60, when the steel sheets 3 having the same conditions and half-curved shape enter the tension leveler 10, Search the data of the steel sheet 3 having the same conditions and the semi-curved shape among the informed data to find a fine adjustment coefficient suitable for the information, and according to the fine adjustment coefficients, each of the rolls 12, 14, 16, 18).

Here, H is the degree of curvature of the steel sheet, and if the curvature is 1.0 mm or less, it is represented by (+), and if it is 2.0 mm or more, it is represented by (-), and the elongation (Δl / l × 100) is represented by%.

As an example of the test below, when the thickness of the steel sheet is 0.25 mm, the steel type of the steel sheet is T4, and the elongation is 0.12%, the fine adjustment coefficient of the second extension roll 14 of the tension leveler is 6, The fine adjustment coefficient of the 1st anti-camber roll 16 is 11.1, and the fine adjustment coefficient of the 2nd anti-camber roll 18 is 6. At this time, the fine adjustment coefficient of the first extension roll 12 is fixed to six.

As described in detail above, the fine level adjustment method of the tension leveler using a half-measurement measuring device for measuring the bending of the steel sheet of the present invention by using the information already stored without the need to operate the tension leveler to observe the shape of the steel sheet By selecting the adjustment coefficient, there is an advantage that a constant fine adjustment coefficient can be applied according to the steel plate conditions and the shape of the bending.

In addition, there is an advantage that the operator can measure the correct bending up to about 0.01mm with a semi-curve measuring device to observe the steel sheet in order to observe the shape of the steel sheet.

Although the technical concept of the fine adjustment method of the tension leveler using the semi-curve measuring device for measuring the semi-curve of the steel sheet of the present invention has been described with the accompanying drawings, this is illustrative of the best embodiment of the present invention by way of example It is not intended to limit. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (2)

In the fine adjustment method of the tension leveler by inputting the conditions such as the width and thickness of the steel sheet, the steel grade, elongation and quality, and applying the fine adjustment coefficient of each roll accommodated in the tension leveler according to the degree of bending formed in the steel sheet, Measuring the degree of half-curvature formed on the steel sheet by a half-curvature measuring device; Observing the shape of the steel sheet after leveling the steel sheet through the tension leveler after applying an optional fine adjustment coefficient to the tension leveler according to the bending degree of the steel sheet and the condition of the input steel sheet; Information on the condition of the steel sheet having a good shape among the observed steel sheets, the degree of bending measured by the semi-curve measuring device, and the fine adjustment coefficient of the tension leveler applied to the steel sheet; When the steel sheet having the same bending degree as the condition of the information steel sheet enters the tension leveler, retrieving a fine adjustment coefficient of the information tensioned leveler and applying the tension leveler to the tension leveler; Way. The method of claim 1, The semi-curve measuring device is installed so that a plurality of laser rangefinders are moved up and down on the same line under the steel plate to measure a distance from the bottom surface of the steel plate, and a plurality of laser rangefinders installed at both ends of the plurality of laser rangefinders are located at the left and right sides. It is installed to be movable to the fine adjustment method of the tension leveler, characterized in that for measuring the half-curve formed in the width direction of the steel sheet by moving the plurality of laser rangefinders on the left and right sides according to the width of the steel sheet.