KR101277744B1 - Shape measuring apparatus of winding coil and shape measuring method thereof - Google Patents

Abstract

A shape measuring apparatus and a shape measuring method of a winding coil are disclosed. According to one embodiment of the invention, the base is disposed so as to face the side of the winding coil is wound strip; A center sensor disposed on the base to be disposed on an extension line of the rotational center of the winding coil; A plurality of diameter measuring sensors arranged in a plurality of rows along the radial direction of the winding coil in the center sensor of the base; And a controller configured to determine the flatness of the winding coil based on the signal sensed by the center sensor and the diameter measuring sensor.

Description

SHAPE MEASURING APPARATUS OF WINDING COIL AND SHAPE MEASURING METHOD THEREOF}

The present invention relates to a shape measuring apparatus and a shape measuring method of a winding coil capable of measuring the winding shape of the winding coil.

Generally, the steelmaking process may include a steelmaking process, a steelmaking process, and a rolling process. In the rolling process, there is a hot rolling process for rolling a slab to produce a coil. The hot rolling process sandwiches the slab between two rotating rollers and applies a continuous force while gradually narrowing the roller spacing to create a thin strip. Winding coils are produced as the strips are wound into coil shapes in the winder.

Korean Patent Registration No. 10-0862778 (October 02, 2008) discloses a hot rolling device control device. The hot rolling device control device sets the initial tension between the first pinch roll and the second pinch roll, measures the left and right elastic deformation of each of the first pinch roll and the second pinch roll, and generates a telescope while the strip is wound. Can be suppressed. In addition, the loosening of the strip wound on the pinch roll can be reduced.

Embodiments of the present invention provide a shape measuring apparatus and a shape measuring method of a winding coil which can measure whether the strip is normally wound on the winding coil.

According to one aspect of the invention, the base is disposed so as to face the side of the winding coil is wound strip; A center sensor disposed on the base to be disposed on an extension line of the rotational center of the winding coil; A plurality of diameter measuring sensors arranged in a plurality of rows along the radial direction of the winding coil in the center sensor of the base; And a controller configured to determine the flatness of the winding coil based on the signal sensed by the center sensor and the diameter measuring sensor.

The diameter measuring sensor rows may be arranged to have the same arc angle around the center sensor.

 The base may be formed crosswise or radially with a plurality of rods crossed.

It may further include a rotary device coupled to correspond to the center sensor of the base to rotate the base.

The base can be rotated forward and backward in the arc angle range of the diameter sensor array.

The diameter measuring sensor may be arranged at equal intervals.

The center sensor and the diameter measuring sensor may be laser sensors.

According to another aspect of the invention, measuring the side shape of the winding coil by the central sensor and the plurality of diameter measuring sensor; And determining a side flatness of the winding coil based on the signals received from the center sensor and the diameter measuring sensor.

In the side shape measurement step of the winding coil, the base can be rotated.

The base has diameter measuring sensors arranged in a row at regular arc angles about the center sensor, and the base can be rotated forward and backward within the arc angle range of the diameter measuring sensor row.

According to the embodiments of the present invention, since the shape measuring device measures the side shape of the winding coil, there is an effect that can measure whether the strip is normally wound on the winding coil.

1 is a view showing a rolling line according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a winding coil and a shape measuring device installed in the rolling line of FIG. 1.
3 is a view showing a first embodiment of the shape measuring apparatus according to the present invention.
4 is a view showing a second embodiment of the shape measuring apparatus according to the present invention.
5 is a diagram illustrating a shape measuring apparatus.
6 is a diagram illustrating a method of measuring the shape of a winding coil.
7 is a flowchart illustrating a shape measuring method of a winding coil according to an exemplary embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. In the following description of the present invention, if it is determined that the detailed description of the related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, an embodiment of the desulfurization slag separation apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a rolling line according to an embodiment of the present invention.

Referring to FIG. 1, in the hot rolling process, the slab 1 may be manufactured into a thin strip 2 while passing through a rough mill (not shown) and a finishing mill 11. Roughing mill (not shown) may be rolled to a thickness of approximately 20 ~ 50mm by rolling a slab (slab) heated in a heating furnace about 1100 ~ 1300 ℃. The finishing mill 11 may be made of a plurality of rolling rollers to produce a strip 2 by rolling the slab rolled in the rough mill to approximately 1.0 to 20.0 mm. In the finishing mill 11, the slab may have a temperature of about 850 ~ 1100 ℃.

The strip 2 is cooled to the target temperature in the continuous cooler 13, and the cooled strip 2 can be transferred to the pinch roller 15 and then wound up in the winder 17. The pinch roller 15 can adjust the speed at which the strip 2 is wound in the winder 17. The strip 2 may be wound on the winder 17 at a temperature of about 400-800 ° C.

2 is a view showing a winding coil and a shape measuring device installed in a rolling line, Figure 3 is a view showing a first embodiment of a shape measuring device according to the present invention.

2 to 3, the shape measuring device 100 may be disposed on the side of the winding coil 20 on which the strip 2 is wound so as to be spaced apart from the winding coil 20. The shape measuring apparatus 100 may include a base 110, a center sensor 121, a diameter measuring sensor 131, and a controller 160.

The base 110 may be disposed to face the side of the winding coil 20. The base 110 may be formed in a cross shape in which a plurality of rods 111 intersect. Of course, the base 110 may be formed in a disc shape or a straight shape.

The center sensor 121 may be disposed in the center of the base 110. For example, when the base 110 is cross-shaped, the center sensor 121 may be disposed at a portion where the rod 111 intersects. In addition, when the base 110 is in the form of a disc, the center sensor 121 may be disposed in the center of the base 110. The center sensor 121 may be disposed to correspond to the extension line C of the rotation center of the winding coil 20.

The diameter measuring sensor 131 may be arranged in a plurality of rows along the radial direction of the winding coil 20 about the center sensor 121 in the base 110. For example, when the base 110 is cross-shaped, the diameter measuring sensors 131 may be arranged along the length direction of the rod 111 of the base 110. In addition, when the base 110 is disc-shaped, the diameter measuring sensors 131 may be arranged along the radial direction with respect to the center sensor 121 of the base 110. These diameter measuring sensors 131 may be arranged at equal intervals.

The column of the diameter measuring sensor 131 may be disposed to have the same arc angle with respect to the center sensor 121. For example, when the base 110 is formed in a cross shape, the diameter measuring sensor 131 rows may be arranged for each arc angle of 90 degrees. In this case, four rows of diameter measuring sensors 131 are arranged in the base 110.

In the present embodiment, a description will be made based on the case where the base 110 has a cross shape.

The diameter measuring sensors 131 may be measured in detail by dividing the step of increasing the radius of the winding coil 20 as the radial interval is narrower. For example, when the diameter measuring sensor 131 is disposed every 5 cm in the radial direction, it is possible to measure whether the winding coil 20 is normally wound in a circular shape every time the radius of the winding coil 20 increases by 5 cm.

On the other hand, the diameter measuring sensor 131 can be measured by dividing the step of increasing the radius of the winding coil 20 is relatively denser as the radial interval is wider. For example, when the diameter measuring sensor 131 is disposed every 20 cm in the radial direction, it is possible to measure whether the winding coil 20 is normally wound in a circular shape every time the radius of the winding coil 20 increases by 20 cm.

The spacing of the diameter measuring sensors 131 may be appropriately set according to the thickness of the strip 2, the target diameter of the winding coil 20, and the like.

The center sensor 121 and the diameter measuring sensor 131 may be laser sensors. The laser sensor detects the laser reflected from the side of the winding coil 20 after irradiating the laser. When the signal sensed by the laser sensor is received by the controller 160, it may be determined whether the winding coil 20 is wound in a circular shape.

The center sensor 121 may be a reference when the center sensor 121 measures the diameter from the center of the winding coil 20 by the diameter measuring sensors 131. The diameter measuring sensors 131 may measure the diameter of the winding coil 20 from the center sensor 121.

The rotating device 140 may be connected to the center of the base 110. The rotating device 140 may include a rotating shaft 141 fixed to the crossing portion of the rod 111 and a motor 145 coupled to rotate the rotating shaft 141. The motor 145 rotates the base 110 by rotating the rotation shaft 141.

The base 110 may be rotated by the rotating device 140 within the arc angle range of the row of the diameter measuring sensor 131. For example, when the rows of diameter measuring sensors 131 are arranged in a line every 90 °, the base 110 may be rotated in the forward and backward directions (clockwise and counterclockwise) within a 90 ° range. Since the base 110 is rotated forward and backward within the range of 90 °, the circumferential shape of the winding coil 20 can be measured as a whole.

4 shows a second embodiment of a base according to the invention.

Referring to FIG. 4, the base 110 may have a structure in which a plurality of rods 111 are disposed radially. In FIG. 4, eight rods 110 are provided with respect to the center portion, but the number of the rods 111 may be changed in various ways. Hereinafter, a description will be given based on the structure in which eight rods 111 are installed.

The center sensor 121 is installed at the centers of the plurality of rods 111, and the diameter measuring sensors 131 may be arranged in a line along the length direction of each rod 111. The diameter measuring sensors 131 may be arranged at equal intervals.

The column of the diameter measuring sensor 131 may be arranged to have the same arc angle with respect to the center sensor 121. For example, when there are eight rows of diameter measuring sensors 131, the rows of diameter measuring sensors 131 may be arranged for each arc angle of 45 °.

The base 110 may be rotated by the rotating device 140 within the arc angle range of the row of the diameter measuring sensor 131. For example, when the column of diameter measuring sensors 131 is arranged in a line for each circular arc of 45 °, the base 110 may be rotated forward and backward within the 45 ° range. Since the base 110 is rotated forward and backward within the 45 ° range, the circumferential shape of the winding coil 20 can be measured as a whole.

5 is a diagram illustrating a shape measuring apparatus.

Referring to FIG. 5, the controller 160 may be connected to the center sensor 121, the plurality of diameter measuring sensors 131, the rotating device 140, or the like by wire or wirelessly. The center sensor 121 and the plurality of diameter measuring sensors 131 transmit a measurement signal about the diameter of the winding coil 20 to the control unit 160, and the control unit 160 receives the winding coil 20 by the received signal. Determine the flatness of. The rotating device 140 may be rotated continuously or periodically by the controller 160.

The reference flatness and the error range are preset in the controller 160. The flatness is a value obtained by dividing a plurality of diameters of the winding coil 20. Through this flatness, it can be determined whether the winding coil 20 is wound in a circular or elliptical shape.

The shape measurement method of the winding coil according to the present invention configured as described above and its operation will be described. The following description will be made based on a cross-shaped base.

6 is a view showing a method of measuring the shape of the winding coil, Figure 7 is a flow chart showing a shape measuring method of the winding coil according to an embodiment of the present invention.

6 and 7, the winder 17 winds up the strip 2 to form a winding coil 20 (S11).

The rotating device 140 rotates the base 110 about the rotation axis 141 in the forward and backward directions within the arc angle range of the diameter measuring sensor 131 row. Four radial diameter measuring sensor 131 rows are arranged every 90 degrees. In the following, two parallel diameter measuring sensor 131 rows are referred to as a first radial row, and the other two parallel diameter measuring sensor 131 rows are referred to as a second radial row.

The side shape of the coiling coil is measured (S12). That is, when the base 110 is rotated forward and backward within the 90 ° range, the four diameter measuring sensor 131 rows measure the radius of the winding coil 20. That is, the center sensor 121 and the diameter measuring sensors 131 irradiate the laser to the side of the winding coil 20 and measure the reflected laser.

The controller 160 determines whether the winding coil 20 is wound in a circular shape according to the signal received from the diameter measuring sensor 131 column. That is, the controller 160 may detect two average diameters of the winding coil 20 by signals detected in the first radial row and the second radial row.

The average diameter a detected in the first radial row is divided by the average diameter b detected in the second radial row. The value divided in this way is called flatness, and it can be judged that the winding coil is wound round or elliptical by the flatness. Flatness can be obtained by the formula (a-b) / a.

The controller determines whether the winding coil is wound in a circular shape by the flatness (S13).

If it is determined that the flatness is out of the error range, the control unit 160 stops the winding of the winding coil 20 (S16). At this time, the winding coil 20 is determined to be wound in an ellipse form because the two average diameters are different. The controller 160 performs a winding failure determination. The winding coil 20 that is determined to be defective is separated from the winding machine 17 and then sent to the previous process.

In addition, when it is determined that the flatness falls within the error range, the controller 160 determines that the winding coil 20 is wound in a circular shape. In this case, the strip 2 is continuously wound up to the winding coil 20 (S14).

The diameter measuring sensors 131 continuously measure the diameter of the winding coil 20. The controller 160 determines whether winding of the winding coil 20 is completed (S15). That is, the controller 160 determines whether the winding coil 20 has reached the target diameter.

If it is determined that the winding coil 20 has not reached the target diameter, the winding of the winding coil 20 is continuously performed, and the side shape of the winding coil 20 is continuously measured.

On the other hand, if it is determined that the winding coil 20 has reached the target diameter, the winding of the winding coil 20 is stopped (S16). After the winding is completed, the winding coil 20 is separated from the winding machine 17 and then sent to the next process.

As described above, since the shape measuring device measures the side shape of the winding coil 20 as a whole as it rotates, the shape of the winding coil 20 may be accurately sensed as a whole.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

100: shape measuring device 110: base
111: load 121: center sensor
131: diameter measuring sensor 140: rotating device
141: shaft 145: motor

Claims (10)

A base disposed to face the side of the winding coil in which the strip is wound;
A center sensor disposed on the base to be disposed on an extension line of the rotational center of the winding coil;
A plurality of diameter measuring sensors arranged in a plurality of rows along the radial direction of the winding coil in the center sensor of the base; And
And a controller configured to determine the flatness of the winding coil based on the signals sensed by the center sensor and the diameter measuring sensor.
The method of claim 1,
The diameter measuring sensor array is a shape measuring device of the winding coil, characterized in that arranged to have the same arc angle around the center sensor.
The method of claim 1,
The base is a shape measuring device of the winding coil, characterized in that formed in the cross or radial cross-section of a plurality of rods.
3. The method of claim 2,
Shaped apparatus of the winding coil further comprises a rotary device coupled to correspond to the center sensor of the base to rotate the base.
The method of claim 4, wherein
And said base is rotated forward and backward in the arc angle range of the diameter measuring sensor row.
6. The method according to any one of claims 1 to 5,
The diameter measuring device is a shape measuring device of the winding coil, characterized in that arranged at equal intervals.
The method according to claim 6,
The center sensor and the diameter measuring sensor is a shape measurement device of the winding coil, characterized in that the laser sensor.
Measuring a side shape of the winding coil by a central sensor and a plurality of diameter measuring sensors; And
Determining the side flatness of the winding coil based on the signals received from the center sensor and the diameter measuring sensor;
In the side shape measurement step of the winding coil,
Rotate the base,
The base diameter measuring sensors are arranged in a line at regular arc angles with respect to the center sensor.
And said base is rotated forward and backward within the arc angle range of the diameter measuring sensor row. delete delete

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