KR20120032870A - Method for measuring size of slab - Google Patents

Abstract

PURPOSE: A slab size measuring method is provided to measure and compensate slab size from the actual moving speed and edge coordinates of slab, thereby obtaining accurate slab size. CONSTITUTION: A slab size measuring method comprises the steps of: measuring a distance to slab being moved in real time(S1), calculating the actual moving speed of the slab by comparing the rotating speed of a roller table with a moving speed of the slab which is calculated based on a slab detection signal(S2), calculating edge coordinates of the slab using the measured distance and the actual moving speed of the slab(S3), calculating the width and length of the slab using the edge coordinates of the slab(S4), compensating the length of the slab using the slab detection signal(S5), and calculating the thickness of the slab using the measured distance to the slab(S6).

Description

How to measure slab size {METHOD FOR MEASURING SIZE OF SLAB}

The present invention relates to a slab size measuring method, and more particularly, to a slab size measuring method for accurately measuring the length, width, and thickness of the slab even in the case of slabs moving at a nonlinear speed.

In general, the size information of the slab is used as important information in the furnace and rolling process.

When the slab is inserted into the heating furnace, which is a preheating process in the hot-rolled steel part, if the actual width of the slab is large and the error of the predicted width is large, the slab may be considered as a bad slab after rolling.

Therefore, it is necessary to accurately measure the size of the slab at the entrance side of the heating furnace.

On the other hand, the slab is designed to move at a linear speed, but there is a case in which the slab does not come into close contact with the roller due to a problem on the lower surface of the slab or a friction problem of the roller table.

The above technical configuration is a background art for helping understanding of the present invention, and does not mean a conventional technology well known in the art.

The present invention calculates the actual moving speed by tracking the position of the slab and accurately measures the size of the slab even when the slab moves at a nonlinear speed by measuring and compensating the size of the slab using the slab's actual moving speed and the edge coordinates of the slab. It is an object of the present invention to provide a method for measuring a slab size so that it can be measured.

The slab size measuring method according to the present invention comprises the steps of real-time measuring the distance to the moving slab; Calculating the actual moving speed of the slab by comparing the rotational speed of the roller table with the moving speed of the slab calculated through the slab detection signal; Calculating edge coordinates of the slab by using the distance measurement with the slab and the actual moving speed of the slab; Calculating a width and a length of the slab by using edge coordinates of the slab and compensating for the length of the slab by using the slab detection signal; And calculating a thickness of the slab by using the distance measurement value with the slab.

In the present invention, the step of compensating the length of the slab may include receiving the slab detection signal from a plurality of slab detection sensors provided at predetermined intervals; Calculating a first moving distance of the slab by using the number of slab detection signals and an interval between the slab detection sensors; Calculating a second moving distance of the slab by using the slab transit time of the slab detection sensor that first detects the moving slab and the actual moving speed of the slab; And compensating for the length of the slab calculated through the corner coordinates of the slab by summing the first and second travel distances.

In the present invention, the step of measuring the distance to the slab is characterized in that for measuring at both sides and the upper portion of the slab to move using a laser displacement sensor.

In the present invention, the step of calculating the corner coordinates of the slab is characterized in that it is calculated through the distance measurement value and the actual moving speed of the slab measured at both sides of the slab.

In the present invention, the step of calculating the thickness of the slab is characterized in that the calculation of the average value of the distance measurement with the slab measured at the top of the slab.

As described above, the present invention tracks the position of the slab to calculate the actual moving speed and shorten the processing time by measuring and compensating the size of the slab using the slab's actual moving speed and the edge coordinates of the slab and the slab is meandering. In the case of slabs moving at high speeds or at non-linear speeds, the slab size is accurately measured, thereby improving reliability.

1 to 3 are views for explaining the configuration of the slab size measuring apparatus according to an embodiment of the present invention.
4 is a flowchart illustrating a slab size measuring method according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to Examples. These embodiments are only for illustrating the present invention, and the scope of rights of the present invention is not limited by these embodiments.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 to 3 are views for explaining the configuration of the slab size measuring apparatus according to an embodiment of the present invention.

1 and 3, a slab size measuring apparatus according to an embodiment of the present invention includes a first laser displacement sensor 1, a second laser displacement sensor 2, a third laser displacement sensor 3, and a controller. (4) and the slab detection sensor (5).

The first laser displacement sensor 1, the second laser displacement sensor 2, and the third laser displacement sensor 3 measure a distance from the slab 7 moving the roller table 6.

As shown in FIG. 2, the first laser displacement sensor 1 and the second laser displacement sensor 2 respectively measure a distance from the reference plates 11 and 21 when the slab 7 does not enter. When the slab 7 enters, the distance with the slab 7 which changes in real time on both sides of the slab 7 which moves is measured.

In addition, the third laser displacement sensor 3 measures the distance to the roller table 6 in the state that the slab 7 does not enter, but when the slab 7 enters the slab at the top of the slab 7. Measure the distance to (7).

The slab detection sensor 5 is configured to determine whether or not the slab is detected and is configured in plural. The slab detection sensor 5 is provided on the side of the roller table 6 at regular intervals to detect the position of the slab 7.

The controller 4 derives a compensation coefficient by comparing the slab movement speed detected from the slab detection sensor 5 with the rotational speed of the roller table 6, and calculates the actual movement speed of the slab 7 using the compensation coefficient. .

The edge of the slab 7 is analyzed by analyzing the actual moving speed of the slab 7 and the distance measurement value between the two slabs 7 measured from the first laser displacement sensor 1 and the second laser displacement sensor 2. Calculate the coordinates (x1, y1 to x4, y4).

Next, the width and length of the slab 7 are calculated using the edge coordinates x1, y1 to x4, y4 of the slab 7.

Here, the width and length of the slab 7 are calculated through an average calculation method on four straight lines connecting the corner coordinates x1, y1 to x4, y4 of the slab 7.

As shown in FIG. 3, when the slab 7 is detected from the plurality of slab detection sensors 5, the controller 4 determines, "the spacing of the slab detection sensor x (number of detected slab detection sensors -1)". The first moving distance of the slab 7 is calculated through the equation.

Subsequently, the second travel distance of the slab 7 is calculated using the slab 7 passing time of the slab detection sensor 5 which first detected the moving slab 7 and the actual moving speed of the slab 7. do.

The length of the slab calculated through the corner coordinates x1, y1 to x4, y4 of the slab 7 is calculated by summing the first moving distance and the second moving distance.

In other words, the distance measurement value between the two reference plates 11 and 21 measured when the slab 7 does not enter, and the variable slab 7 measured when the slab 7 enters. The corner coordinates x1, y1 to x4, y4 of the slab 7 are calculated using the two distance measurements with and the actual moving speed of the slab 7 calculated by the slab detection sensor 5.

The length and width of the slab 7 are calculated using the edge coordinates x1, y1 to x4, y4 of the slab 7, and the length of the slab 7 is the slab detected from the slab detection sensor 5. Compensate using the movement distance in (7).

That is, while measuring the length of the slab (7) using the edge coordinates (x1, y1 ~ x4, y4) of the slab (7), in the case of slabs that move a non-linear velocity, the slab (7) through the movement distance of the slab (7) 7) Compensation for the length of 7) increases the reliability of the measured value even when the slab moves at nonlinear speed.

In addition, the controller 4 calculates the thickness of the slab 7 by using the distance measurement value with the slab 7 measured by the third laser displacement sensor 3. That is, the distance measurement value with the roller table 6 measured in the state that the slab 7 does not enter and the distance measurement with the slab 7 measured from the upper part of the slab 7 in the state in which the slab 7 entered. The thickness of the slab 7 is calculated by comparing the values.

Here, the control unit 4 has an application for calculating the corner coordinates (x1, y1 to x4, y4) of the slab 7 by using the distance measurement value with the slab 7 and the actual moving speed of the slab 7, The length and width of the slab 7 are calculated using the coordinates (x1, y1 to x4, y4), and the distance of the slab 7 measured from the upper part of the slab 7 is used to measure the slab 7. Built-in application to calculate thickness.

In addition, in calculating the width, length, and thickness of the slab 7, it is possible to reduce the actual value and the error through filtering of the reference and averaging.

Referring to the slab size measurement method according to an embodiment of the present invention configured as described above are as follows. 4 is a flowchart illustrating a slab size measuring method according to an embodiment of the present invention.

1 to 4, first, each of the first laser displacement sensor 1, the second laser displacement sensor 2, and the third laser displacement sensor 3 is a slab 7 for moving the roller table 6. Measure the distance to the (S1).

Here, the first laser displacement sensor 1 and the second laser displacement sensor 2 respectively measure the distance from the slab 7 at both sides of the slab 7, and the third laser displacement sensor 3 is the slab ( Measure the distance to the slab 7 from the top of 7).

Subsequently, by comparing the moving speed of the slab 7 detected from the slab detection sensor 5 with the moving speed of the slab 7 driven by the roller table 6, a compensation coefficient is derived and the slab is obtained through the derived compensation coefficient. The actual moving speed of (7) is calculated (S2).

Next, the actual movement of the slab 7 calculated through the slab detection sensor 5 and the two distance measurement values between the slab 7 measured from the first laser displacement sensor 1 and the second laser displacement sensor 2. By analyzing the velocity, the edge coordinates (x1, y1 to x4, y4) of the slab 7 are calculated (S3).

Here, the calculation of the corner coordinates (x1, y1 to x4, y4) is a distance measurement value between the two reference plates 11 and 21 measured while the slab 7 does not enter, and the slab 7 enters. Two distance measurement values with the variable slab 7 measured in one state and the actual moving speed of the slab 7 are input to calculate corner coordinates x1, y1 to x4, y4 of the slab 7.

Then, the length and width of the slab 7 are calculated through an average calculation method on four straight lines connecting the edge coordinates x1, y1 to x4, y4 of the slab 7 (S4).

Subsequently, in order to compensate for the length error of the slab 7 which may occur due to the slip phenomenon of the slab 7, the control unit 4 according to the actual position of the slab 7 detected from the slab detection sensor 5. Compensating the length of 7) (S5).

When the slab 7 is detected from the plurality of slab detection sensors 5, the length compensation of the slab 7 is performed through a calculation formula of "interval of slab detection sensor x (number of detected slab detection sensors -1)". The first moving distance of the slab 7 is calculated and the slab 7 passing time of the slab detection sensor 5 which first detects the moving slab 7 and the actual moving speed of the slab 7 are used. The second travel distance of the slab 7 is calculated. The length of the slab calculated through the corner coordinates x1, y1 to x4, y4 of the slab 7 is calculated by summing the first moving distance and the second moving distance.

In addition, the thickness of the slab 7 is calculated through the distance measurement value with the slab measured from the third laser displacement sensor 1 (S6).

Here, the thickness calculation of the slab 7 is measured at the top of the slab 7 with the distance measurement value with the roller table 6 measured in the state that the slab 7 does not enter and the slab 7 enters. The thickness of the slab 7 is calculated by comparing the distance measurement value with one slab 7.

As described above, the present invention measures the distance between the slab 7 and the size of the slab 7 while the slab 7 moves, thereby reducing the processing time.

In addition, since the present invention measures the length and width of the slab 7 by using the edge coordinates of the slab 7, it is possible to increase the accuracy of the measured value while the slab 7 meanders on the roller table 6.

In addition, the present invention measures and compensates for the length and width of the slab 7 using the slab's actual moving speed through the slab detection sensor 5 even when the slab 6 moves at a nonlinear speed. Improve reliability.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is understandable. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1: first laser displacement sensor 2: second laser displacement sensor
3: third laser displacement sensor 4: control unit
5: slab detection sensor 6: roller table
7: slab 11, 21: reference plate

Claims (5)

Measuring the distance to the moving slab in real time;
Calculating the actual moving speed of the slab by comparing the rotational speed of the roller table with the moving speed of the slab calculated through the slab detection signal;
Calculating edge coordinates of the slab by using the distance measurement with the slab and the actual moving speed of the slab;
Calculating a width and a length of the slab by using edge coordinates of the slab and compensating for the length of the slab by using the slab detection signal; And
And calculating the thickness of the slab by using the distance measurement with the slab.
The method of claim 1, wherein compensating for the length of the slab
Receiving the slab detection signals from a plurality of slab detection sensors provided at predetermined intervals;
Calculating a first moving distance of the slab by using the number of slab detection signals and an interval between the slab detection sensors;
Calculating a second moving distance of the slab by using the slab transit time of the slab detection sensor that first detects the moving slab and the actual moving speed of the slab;
Compensating the length of the slab calculated through the corner coordinates of the slab by summing the first travel distance and the second travel distance.
The method of claim 1, wherein measuring the distance to the slab
Slab size measuring method, characterized in that for measuring on both sides and the upper portion of the slab moving using a laser displacement sensor.
The method of claim 1, wherein the calculating of the edge coordinates of the slab
Slab size measuring method characterized in that it is calculated through the distance measurement value and the actual moving speed of the slab measured at both sides of the slab.
The method of claim 1, wherein calculating the thickness of the slab is
Slab size measuring method characterized in that it is calculated as the average value of the distance measurement with the slab measured from the top of the slab.

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